Cambium Networks 89FT0004 Dual Channel 2.4GHz MIMO Access Point Transceiver User Manual PMP 450 Planning Guide

Cambium Networks Inc. Dual Channel 2.4GHz MIMO Access Point Transceiver PMP 450 Planning Guide

Exhibit D Users Manual per 2 1033 b3

      Cambium PMP 450 Planning Guide System Release 12.1.1 For Regulatory Review Only
  pmp-0047 (June 2013)  PMP 450 module essential information Default IP Address for Management GUI Access 169.254.1.1 Default Administrator Username admin Default Administrator Password (no password) Software Upgrade Procedure See “Updating the software version and using CNUT” in the PMP 450 Configuration and User Guide Resetting to Factory Defaults (2 options) 1. On the radio GUI, navigate to Configuration, Unit Settings and select Set to Factory Defaults  OR  2. On the radio GUI, navigate to Configuration, Unit Settings and enable and save option Set to Factory Defaults Upon Default Plug Detection.  When the unit is powered on with a default/override plug (see section “Acquiring the Override Plug” in the PMP 450 Configuration and User Guide) the radio will be returned to its factory default settings.
pmp-0047 (June 2013)      Accuracy While reasonable efforts have been made to assure the accuracy of this document, Cambium Networks assumes no liability resulting from any inaccuracies or omissions in this document, or from use of the information obtained herein. Cambium reserves the right to make changes to any products described herein to improve reliability, function, or design, and reserves the right to revise this document and to make changes from time to time in content hereof with no obligation to notify any person of revisions or changes. Cambium does not assume any liability arising out of the application or use of any product, software, or circuit described herein; neither does it convey license under its patent rights or the rights of others. It is possible that this publication may contain references to, or information about Cambium products (machines and programs), programming, or services that are not announced in your country. Such references or information must not be construed to mean that Cambium intends to announce such Cambium products, programming, or services in your country.  Copyrights This document, Cambium products, and 3rd Party Software products described in this document may include or describe copyrighted Cambium and other 3rd Party supplied computer programs stored in semiconductor memories or other media. Laws in the United States and other countries preserve for Cambium, its licensors, and other 3rd Party supplied software certain exclusive rights for copyrighted material, including the exclusive right to copy, reproduce in any form, distribute and make derivative works of the copyrighted material. Accordingly, any copyrighted material of Cambium, its licensors, or the 3rd Party software supplied material contained in the Cambium products described in this document may not be copied, reproduced, reverse engineered, distributed, merged or modified in any manner without the express written permission of Cambium. Furthermore, the purchase of Cambium products shall not be deemed to grant either directly or by implication, estoppel, or otherwise, any license under the copyrights, patents or patent applications of Cambium or other 3rd Party supplied software, except for the normal non-exclusive, royalty free license to use that arises by operation of law in the sale of a product.  Restrictions Software and documentation are copyrighted materials. Making unauthorized copies is prohibited by law. No part of the software or documentation may be reproduced, transmitted, transcribed, stored in a retrieval system, or translated into any language or computer language, in any form or by any means, without prior written permission of Cambium. License Agreements  The software described in this document is the property of Cambium and its licensors. It is furnished by express license agreement only and may be used only in accordance with the terms of such an agreement.  High Risk Materials  Components, units, or 3rd Party products used in the product described herein are NOT fault-tolerant and are NOT designed, manufactured, or intended for use as on-line control equipment in the following hazardous environments requiring fail-safe controls: the operation of Nuclear Facilities, Aircraft Navigation or Aircraft Communication Systems, Air Traffic Control, Life Support, or Weapons Systems (High Risk Activities). Cambium and its supplier(s) specifically disclaim any expressed or implied warranty of fitness for such High Risk Activities. © 2013 Cambium Networks, Inc. All Rights Reserved.
PMP 450 Planning Guide Safety and regulatory information  pmp-0047 (June 2013)  i  Safety and regulatory information This section describes important safety and regulatory guidelines that must be observed by personnel installing or operating PMP 450 equipment. Important safety information  To prevent loss of life or physical injury, observe the safety guidelines in this section. Power lines Exercise extreme care when working near power lines. Working at heights Exercise extreme care when working at heights. Grounding and protective earth PMP 450 units must be properly grounded to protect against lightning. It is the user’s responsibility to install the equipment in accordance with national regulations. In the USA, follow Section 810 of the National Electric Code, ANSI/NFPA No.70-1984 (USA). In Canada, follow Section 54 of the Canadian Electrical Code. These codes describe correct installation procedures for grounding the outdoor unit, mast, lead-in wire and discharge unit, size of grounding conductors and connection requirements for grounding electrodes. Other regulations may apply in different countries and therefore it is recommended that installation of the outdoor unit be contracted to a professional installer.  Powering down before servicing Always power down and unplug the equipment before servicing. Primary disconnect device  The AP or SM unit’s power supply is the primary disconnect device. External cables Safety may be compromised if outdoor rated cables are not used for connections that will be exposed to the outdoor environment.
Safety and regulatory information PMP 450 Planning Guide  ii  pmp-0047 (June 2013)  RF exposure near the antenna Radio frequency (RF) fields will be present close to the antenna when the transmitter is on. Always turn off the power to the PMP 450 unit before undertaking maintenance activities in front of the antenna. Minimum separation distances Install the AP/SM so as to provide and maintain the minimum separation distances from all persons. The minimum separation distances for each frequency variant are specified in Calculated distances and power compliance margins on page 4-12. Important regulatory information The PMP 450 product is certified as an unlicensed device in frequency bands where it is not allowed to cause interference to licensed services (called primary users of the bands). Radar avoidance In countries where radar systems are the primary band users, the regulators have mandated special requirements to protect these systems from interference caused by unlicensed devices.  Unlicensed devices must detect and avoid co-channel operation with radar systems.  Installers and users must meet all local regulatory requirements for radar detection. To meet these requirements, users must set the correct Country Code during commissioning of the PMP 450. If this is not done, installers and users may be liable to civil and criminal penalties. Contact the Cambium helpdesk if more guidance is required. USA and Canada specific information The USA Federal Communications Commission (FCC) has asked manufacturers to implement special features to prevent interference to radar systems that operate in the 5250-5350 and 5470-5725 MHz bands. These features must be implemented in all products able to operate outdoors in the UNII band.  The use of the 5600 – 5650 MHz band is prohibited, even with detect-and-avoid functionality implemented. Manufacturers must ensure that such radio products cannot be configured to operate outside of FCC rules; specifically it must not be possible to disable or modify the radar protection functions that have been demonstrated to the FCC. In order to comply with these FCC requirements, Cambium supplies variants of the PMP 450 for operation in the USA or Canada.  These variants are only allowed to operate with Country Codes that comply with FCC/IC rule.
PMP 450 Planning Guide Contents  pmp-0047 (June 2013)  iii  Contents PMP 450 module essential information ............................................................................................................................... 2 Safety and regulatory information .................................................................................... i Important safety information ......................................................................................................................................... i Important regulatory information ................................................................................................................................. ii About This Planning Guide ................................................................................................ x General information ............................................................................................................................................................ xi Version information .................................................................................................................................................... xi Contacting Cambium Networks .................................................................................................................................. xi Chapter 1: Product description .................................................................................. 1-1 Overview of PMP 450 ......................................................................................................................................................1-2 Purpose ......................................................................................................................................................................1-2 Key features ...............................................................................................................................................................1-2 Typical deployment ...................................................................................................................................................1-3 System components ...................................................................................................................................................1-4 Access Point (AP) .............................................................................................................................................................1-5 Network connection ..................................................................................................................................................1-8 AP power supply .......................................................................................................................................................1-8 Further reading on the AP .........................................................................................................................................1-8 Subscriber Module (SM) ...................................................................................................................................................1-9 Mounting brackets ...................................................................................................................................................1-12 Network connection ................................................................................................................................................1-12 SM power supply.....................................................................................................................................................1-12 Further reading on the SM .......................................................................................................................................1-13 Cabling and lightning protection .....................................................................................................................................1-14 PMP and lightning protection ..................................................................................................................................1-14 Outdoor connections ................................................................................................................................................1-14 Wireless operation ..........................................................................................................................................................1-15 Time division duplexing ..........................................................................................................................................1-15 OFDM and channel bandwidth ...............................................................................................................................1-15 Link operation – Dynamic Rate Adapt ....................................................................................................................1-16 Adaptive modulation ...............................................................................................................................................1-20 MIMO......................................................................................................................................................................1-20 Cyclic Prefix ............................................................................................................................................................1-20 Encryption ...............................................................................................................................................................1-21 Further reading on wireless operation .....................................................................................................................1-21 System management .......................................................................................................................................................1-22 Management agent ..................................................................................................................................................1-22 Web server ...............................................................................................................................................................1-22
Contents PMP 450 Planning Guide  iv  pmp-0047 (June 2013)  Remote Authentication Dial In User Service (RADIUS) ....................................................................................... 1-25 SNMP ..................................................................................................................................................................... 1-25 Network Time Protocol (NTP) ............................................................................................................................... 1-26 Wireless Manager (WM) ........................................................................................................................................ 1-26 Capacity upgrades .................................................................................................................................................. 1-28 Software upgrade .................................................................................................................................................... 1-28 Further reading on system management ................................................................................................................. 1-28 Chapter 2: Planning considerations ........................................................................... 2-1 Regulatory planning ......................................................................................................................................................... 2-2 Obeying Regulatory limits........................................................................................................................................ 2-2 Conforming to the limits........................................................................................................................................... 2-2 Network migration planning ............................................................................................................................................ 2-3 Example PMP 450 deployment scenario .................................................................................................................. 2-3 Sector capacity.......................................................................................................................................................... 2-5 Site planning .................................................................................................................................................................. 2-11 AP or SM site selection .......................................................................................................................................... 2-11 Power supply site selection..................................................................................................................................... 2-11 Maximum cable lengths.......................................................................................................................................... 2-11 Wind loading .......................................................................................................................................................... 2-12 Link planning ................................................................................................................................................................. 2-14 Range and obstacles ............................................................................................................................................... 2-14 Path loss considerations .......................................................................................................................................... 2-18 Calculating maximum power level for connectorized AP units ............................................................................. 2-18 Understanding Attenuation ..................................................................................................................................... 2-19 Calculating Link Loss ............................................................................................................................................. 2-19 Calculating Rx Signal Level ................................................................................................................................... 2-19 Calculating Fade Margin ........................................................................................................................................ 2-20 Analyzing the RF Environment ..................................................................................................................................... 2-20 Mapping RF Neighbor Frequencies........................................................................................................................ 2-20 Analyzing the spectrum .......................................................................................................................................... 2-21 Anticipating Reflection of Radio Waves ................................................................................................................ 2-22 Noting Possible Obstructions in the Fresnel Zone .................................................................................................. 2-22 Multiple OFDM Access Point Clusters .................................................................................................................. 2-23 Planning for co-location and using the OFDM Frame Calculator Tool.................................................................. 2-25 Selecting Sites for Network Elements ............................................................................................................................ 2-28 Surveying Sites ....................................................................................................................................................... 2-29 Clearing the Radio Horizon .................................................................................................................................... 2-29 Calculating the Aim Angles ................................................................................................................................... 2-30 Diagramming Network Layouts ..................................................................................................................................... 2-31 Avoiding Self Interference ..................................................................................................................................... 2-31 Avoiding Other Interference ................................................................................................................................... 2-32 Grounding and lightning protection ............................................................................................................................... 2-33 The need for power surge protection ...................................................................................................................... 2-33 Standards ................................................................................................................................................................ 2-33
PMP 450 Planning Guide Contents  pmp-0047 (June 2013)  v  Lightning protection zones ......................................................................................................................................2-34 General protection requirements .............................................................................................................................2-35 Protection requirements for a mast or tower installation .........................................................................................2-37 Protection requirements for a wall installation ........................................................................................................2-38 Protection requirements on a high rise building ......................................................................................................2-39 Configuration options for TDD synchronization ............................................................................................................2-41 GPS synchronization ...............................................................................................................................................2-41 Mounting the GPS receiver (CMM or UGPS) module on the equipment building .................................................2-43 Mounting the GPS receiver (CMM or UGPS) module on a metal tower or mast ...................................................2-43 Data network planning ....................................................................................................................................................2-44 Understanding addresses .........................................................................................................................................2-44 Dynamic or static addressing ...................................................................................................................................2-44 DNS Client ..............................................................................................................................................................2-45 Network Address Translation (NAT) ......................................................................................................................2-45 Developing an IP addressing scheme ......................................................................................................................2-46 Address Resolution Protocol ...................................................................................................................................2-46 Allocating subnets ...................................................................................................................................................2-47 Selecting non-routable IP addresses ........................................................................................................................2-47 Translation bridging ................................................................................................................................................2-48 Engineering VLANs ................................................................................................................................................2-48 Security planning ............................................................................................................................................................2-52 Isolating APs from the Internet ...............................................................................................................................2-52 Managing module access by passwords ..................................................................................................................2-52 Filtering protocols and ports ....................................................................................................................................2-56 Port Lockdown ........................................................................................................................................................2-60 Isolating SMs ...........................................................................................................................................................2-60 Filtering management through Ethernet ..................................................................................................................2-61 Allowing management from only specified IP addresses ........................................................................................2-61 Configuring management IP by DHCP ...................................................................................................................2-61 Planning for airlink security ....................................................................................................................................2-61 Planning for RF Telnet Access Control ...................................................................................................................2-62 Forwarding Downlink PPPoE PADI packets ..........................................................................................................2-62 Planning for RADIUS integration ...........................................................................................................................2-62 Planning for SNMP security ....................................................................................................................................2-63 Ordering components ......................................................................................................................................................2-64 PMP 450 component part numbers .........................................................................................................................2-64 Chapter 3: Legal information ..................................................................................... 3-1 Cambium Networks end user license agreement ..............................................................................................................3-2 Acceptance of this agreement ....................................................................................................................................3-2 Definitions .................................................................................................................................................................3-2 Grant of license .........................................................................................................................................................3-2 Conditions of use .......................................................................................................................................................3-2 Title and restrictions ..................................................................................................................................................3-3 Confidentiality ...........................................................................................................................................................3-4
Contents PMP 450 Planning Guide  vi  pmp-0047 (June 2013)  Right to use Cambium’s name .................................................................................................................................. 3-4 Transfer .................................................................................................................................................................... 3-4 Updates ..................................................................................................................................................................... 3-4 Maintenance ............................................................................................................................................................. 3-5 Disclaimer ................................................................................................................................................................ 3-5 Limitation of liability ............................................................................................................................................... 3-5 U.S. government ....................................................................................................................................................... 3-6 Term of license ......................................................................................................................................................... 3-6 Governing law .......................................................................................................................................................... 3-6 Assignment ............................................................................................................................................................... 3-6 Survival of provisions ............................................................................................................................................... 3-6 Entire agreement ....................................................................................................................................................... 3-7 Third party software ................................................................................................................................................. 3-7 Hardware warranty ........................................................................................................................................................... 3-9 Limit of liability ............................................................................................................................................................. 3-10 Chapter 4: Reference information .............................................................................. 4-1 Equipment specifications ................................................................................................................................................. 4-2 AP specifications ...................................................................................................................................................... 4-2 SM specifications ..................................................................................................................................................... 4-5 Wireless specifications ..................................................................................................................................................... 4-8 General wireless specifications................................................................................................................................. 4-8 Data network specifications ............................................................................................................................................. 4-9 Ethernet interface...................................................................................................................................................... 4-9 Compliance with safety standards .................................................................................................................................. 4-10 Electrical safety compliance ................................................................................................................................... 4-10 Electromagnetic compatibility (EMC) compliance ................................................................................................ 4-10 Human exposure to radio frequency energy ........................................................................................................... 4-11 Compliance with radio regulations ................................................................................................................................ 4-15 Type approvals ....................................................................................................................................................... 4-15 DFS for 5.4 GHz Radios......................................................................................................................................... 4-16 Country Codes and available spectrum .................................................................................................................. 4-19 FCC compliance testing ......................................................................................................................................... 4-29 FCC and ICC IDs and certification numbers .......................................................................................................... 4-29 Notifications ................................................................................................................................................................... 4-33 PMP 450 regulatory compliance ............................................................................................................................ 4-33 Appendix A: Glossary ..................................................................................................... I
PMP 450 Planning Guide List of Figures  pmp-0047 (June 2013)  vii  List of Figures Figure 1  Line Of Sight Diagram .............................................................................................................................................1-3 Figure 2  AP, Radio unit ..........................................................................................................................................................1-5 Figure 3  AP, antenna ..............................................................................................................................................................1-5 Figure 4  AP interfaces ............................................................................................................................................................1-6 Figure 5  AP diagnostic LEDs, viewed from unit front ...........................................................................................................1-7 Figure 6  PMP 450 Series SM .................................................................................................................................................1-9 Figure 7  SM interfaces ..........................................................................................................................................................1-10 Figure 8  SM diagnostic LEDs, viewed from unit front ........................................................................................................1-11 Figure 9  TDD frame division................................................................................................................................................1-15 Figure 10  AP web-based management screenshot ................................................................................................................1-23 Figure 11 Determinants in Rx signal level ............................................................................................................................2-19 Figure 12  Example layout of 16 Access Point sectors (ABCD), 90 degree sectors ..............................................................2-23 Figure 13  Example layout of 16 Access Point sectors (ABC), 60 degree sectors.................................................................2-24 Figure 14  OFDM Frame Calculator tab ................................................................................................................................2-26 Figure 15  Variables for calculating angle of elevation (and depression) ..............................................................................2-30 Figure 16  Rolling sphere method to determine the lightning protection zones ....................................................................2-34 Figure 17  Grounding cable minimum bend radius and angle ...............................................................................................2-36 Figure 18  Grounding and lightning protection on mast or tower ..........................................................................................2-37 Figure 19  Grounding and lightning protection on wall .........................................................................................................2-38 Figure 20  Grounding and lightning protection on building ..................................................................................................2-39 Figure 21  Grounding and lightning protection inside high building .....................................................................................2-40 Figure 22  One unsynchronized AP in cluster resulting in self-interference .........................................................................2-42 Figure 23  GPS timing throughout the network .....................................................................................................................2-43 Figure 24  Cambium network management domain ..............................................................................................................2-45 Figure 25 Example of IP address in Class B subnet ..............................................................................................................2-47 Figure 26  Categorical protocol filtering ...............................................................................................................................2-58 Figure 27  AP DFS Status ......................................................................................................................................................4-16
List of Tables PMP 450 Planning Guide  viii  pmp-0047 (June 2013)  List of Tables Table 1  PMP 450 frequency variants ..................................................................................................................................... 1-4 Table 2  AP interface descriptions and cabling ....................................................................................................................... 1-7 Table 3  AP LED descriptions ................................................................................................................................................ 1-8 Table 4  SM Interfaces .......................................................................................................................................................... 1-10 Table 5  SM diagnostic LED descriptions ............................................................................................................................ 1-12 Table 6  Link Budget Details – Dynamic Rate Adapt, 2.4 GHz Variant .............................................................................. 1-16 Table 7  Link Budget Details – Dynamic Rate Adapt, 5.4 GHz / 5.8 GHz Variant .............................................................. 1-18 Table 8  Deployment scenario terminology descriptions ........................................................................................................ 2-3 Table 9  Examples of aggregate sector throughput – various air interfaces ............................................................................ 2-5 Table 10  Deployment scenario 1 ........................................................................................................................................... 2-6 Table 11  Scenario 1 spectrum usage ...................................................................................................................................... 2-7 Table 12  Deployment scenario 2 ........................................................................................................................................... 2-9 Table 13  Deployment scenario 2 spectrum usage ................................................................................................................ 2-10 Table 14  Sync cable length specification ............................................................................................................................. 2-12 Table 15  Lateral force - metric ............................................................................................................................................ 2-12 Table 16  Lateral force - US ................................................................................................................................................. 2-13 Table 17 Link budget details – PMP 450 link, 20 MHz Channel Bandwidth ....................................................................... 2-14 Table 18 Link budget details – PMP 450 link, 10 MHz Channel Bandwidth ....................................................................... 2-15 Table 19 Link budget details – PMP 450 link, 5MHz Channel Bandwidth .......................................................................... 2-16 Table 20  Example 5.8-GHz OFDM channel assignment by sector ..................................................................................... 2-23 Table 21  Example 5.8-GHz OFDM channel assignment by sector ..................................................................................... 2-24 Table 22  OFDM Frame Calculator tab attributes ................................................................................................................ 2-26 Table 23  OFDM Calculated Frame Results attributes ......................................................................................................... 2-27 Table 24  Special case VLAN IDs ........................................................................................................................................ 2-49 Table 25  VLAN filters in point-to-multipoint modules ....................................................................................................... 2-49 Table 26  Q-in-Q Ethernet frame .......................................................................................................................................... 2-50 Table 27  Identity-based user account permissions - AP ...................................................................................................... 2-53 Table 28  Identity-based user account permissions - SM...................................................................................................... 2-55 Table 29  Ports filtered per protocol selections ..................................................................................................................... 2-59 Table 30  Device default port numbers ................................................................................................................................. 2-60 Table 31  PMP 450 components ........................................................................................................................................... 2-64 Table 32 Connectorized AP physical specifications ............................................................................................................... 4-2 Table 33 SM physical specifications ...................................................................................................................................... 4-5 Table 34  PMP 450 wireless specifications ............................................................................................................................ 4-8 Table 35  PMP 450 Ethernet bridging specifications .............................................................................................................. 4-9 Table 36  PMP 450 safety compliance specifications ........................................................................................................... 4-10 Table 37  EMC emissions compliance .................................................................................................................................. 4-10 Table 38  Power Compliance Margins .................................................................................................................................. 4-13 Table 39  Radio certifications ............................................................................................................................................... 4-15
PMP 450 Planning Guide List of Tables   pmp-0047 (June 2013)  ix  Table 40  OFDM DFS operation based on Country Code setting .........................................................................................4-18 Table 41  Center channel details based on Country Code, 2.4-GHz ......................................................................................4-20 Table 42  Center channel details based on Country Code, 5.4-GHz ......................................................................................4-21 Table 43  Center channel details based on Country Code, 5.8-GHz ......................................................................................4-21 Table 44  AP Default combined transmit power per Country Code – 2.4-GHz band ............................................................4-23 Table 45  Default combined transmit power per Country Code – 5.4-GHz band ..................................................................4-25 Table 46  Default combined transmit power per Country Code – 5.8-GHz band ..................................................................4-26 Table 47  US FCC IDs and Industry Canada Certification Numbers and Covered Configurations ......................................4-29 Table 48  Industry Canada approved antenna list ..................................................................................................................4-34 Table 49  Glossary ...................................................................................................................................................................... I
PMP 450 Planning Guide About This Planning Guide  x  pmp-0047 (June 2013)  About This Planning Guide This guide describes the planning of the Cambium PMP 450 Series of point-to-multipoint wireless equipment deployment. It is intended for use by the system designer.  The guide consists of the following chapters:  Chapter 1: Product description on page on page 1-1  Chapter 2: Planning considerations on page 2-1  Chapter 3: Legal information on page 3-1  Chapter 4: Reference information on page 4-1
General information PMP 450 Planning Guide  pmp-0047 (June 2013)  xi  General information Version information The following shows the issue status of this document since it was first released: Issue Date of issue Remarks 001v000 September 2012 System Release 12.0 002v000 October 2012 Includes additional co-location information 003v000 November 2012 Updated for System Release 12.0.1 004v000 January 2013 Updated for System Release 12.0.2 005v000  March 2013 Updated for System Release 12.0.3/12.0.3.1 Includes additional performance details (SNR) 006v000 June 2013 Updated for System Release 12.1  Contacting Cambium Networks PMP support website: http://www.cambiumnetworks.com/support Cambium main website: http://www.cambiumnetworks.com/  Sales enquiries: solutions@cambiumnetworks.com Email support: support@cambiumnetworks.com Telephone numbers: For full list of Cambium support telephone numbers, see: http://www.cambiumnetworks.com/support/technical.php Address: Cambium Networks 3800 Golf Road, Suite 360 Rolling Meadows, IL 60008
PMP 450 Planning Guide About This Planning Guide  xii  pmp-0047 (June 2013)  Purpose Cambium Networks Point-To-Multipoint (PMP) documents are intended to instruct and assist personnel in the operation, installation and maintenance of the Cambium PMP equipment and ancillary devices. It is recommended that all personnel engaged in such activities be properly trained. Cambium disclaims all liability whatsoever, implied or express, for any risk of damage, loss or reduction in system performance arising directly or indirectly out of the failure of the customer, or anyone acting on the customer's behalf, to abide by the instructions, system parameters, or recommendations made in this document. Cross references References to external publications are shown in italics. Other cross references, emphasized in blue text in electronic versions, are active links to the references. This document is divided into numbered chapters that are divided into sections. Sections are not numbered, but are individually named at the top of each page, and are listed in the table of contents. Feedback We appreciate feedback from the users of our documents. This includes feedback on the structure, content, accuracy, or completeness of our documents. Send feedback to email support (see ‘Contacting Cambium Networks’).
Problems and warranty PMP 450 Planning Guide  pmp-0047 (June 2013)  xiii  Problems and warranty Reporting problems If any problems are encountered when installing or operating this equipment, follow this procedure to investigate and report: 1 Search this document and the software release notes of supported releases. 2 Visit the support website.  http://www.cambiumnetworks.com/support/pmp/software/index.php  3 Ask for assistance from the Cambium product supplier. 4 Gather information from affected units such as:  The IP addresses and MAC addresses.  The software releases.  The configuration of software features.  Any available diagnostic downloads.  CNUT Support Capture Tool information 5 Escalate the problem by emailing or telephoning support. See ‘Contacting Cambium Networks’ for URLs, email addresses and telephone numbers. Repair and service If unit failure is suspected, obtain details of the Return Material Authorization (RMA) process from the support website. Warranty Cambium’s standard hardware warranty is for one (1) year from date of shipment from Cambium or a Cambium distributor. Cambium warrants that hardware will conform to the relevant published specifications and will be free from material defects in material and workmanship under normal use and service. Cambium shall within this time, at its own option, either repair or replace the defective product within thirty (30) days of receipt of the defective product. Repaired or replaced product will be subject to the original warranty period but not less than thirty (30) days. To register PMP products or activate warranties, visit the support website. Extended warranties are available for PMP products.  For warranty assistance, contact the reseller or distributor.  Using non-Cambium parts for repair could damage the equipment or void warranty. Contact Cambium for service and repair instructions.
PMP 450 Planning Guide About This Planning Guide  xiv  pmp-0047 (June 2013)   Portions of Cambium equipment may be damaged from exposure to electrostatic discharge. Use precautions to prevent damage.
Security advice PMP 450 Planning Guide  pmp-0047 (June 2013)  xv  Security advice Cambium Networks systems and equipment provide security parameters that can be configured by the operator based on their particular operating environment.  Cambium recommends setting and using these parameters following industry recognized security practices. Security aspects to be considered are protecting the confidentiality, integrity, and availability of information and assets. Assets include the ability to communicate, information about the nature of the communications, and information about the parties involved.  In certain instances Cambium makes specific recommendations regarding security practices, however the implementation of these recommendations and final responsibility for the security of the system lies with the operator of the system.
PMP 450 Planning Guide About This Planning Guide  xvi  pmp-0047 (June 2013)  Warnings, cautions, and notes The following describes how warnings and cautions are used in this document and in all documents of the Cambium Networks document set. Warnings Warnings precede instructions that contain potentially hazardous situations. Warnings are used to alert the reader to possible hazards that could cause loss of life or physical injury. A warning has the following format:  Warning text and consequence for not following the instructions in the warning. Cautions Cautions precede instructions and are used when there is a possibility of damage to systems, software, or individual items of equipment within a system. However, this damage presents no danger to personnel. A caution has the following format:  Caution text and consequence for not following the instructions in the caution. Notes A note means that there is a possibility of an undesirable situation or provides additional information to help the reader understand a topic or concept. A note has the following format:  Note text.
PMP 450 Planning Guide Product description  pmp-0047 (June 2013)  1-1  Chapter 1:  Product description This chapter provides a high level description of the PMP 450 product.  It describes in general terms the function of the product, the main product variants and typical deployment.  It also describes the main hardware components. The chapter consists of the following topics:  Overview of PMP 450 on page 1-2: Introduces the key features, typical uses, product variants and components of the PMP 450.  Access Point (AP) on page 1-5: Describes the AP and its interfaces   Subscriber Module (SM) on page 1-9: Describes the SM and its interfaces  Cabling and lightning protection on page 1-14: Describes the cabling and lightning protection components of a PMP 450 installation.  Wireless operation on page 1-15: Describes how the PMP 450 wireless link is operated, including modulation modes, power control and security.  System management on page 1-22: Introduces the PMP 450 management system, including the web interface, installation, configuration, alerts and upgrades.
Overview of PMP 450 Product description  1-2  pmp-0047 (June 2013)  Overview of PMP 450 This section introduces the key features, typical uses, product variants and components of the PMP 450. Purpose Cambium PMP 450 Series networks are designed for wireless point-to-multipoint links in the unlicensed 2.4 GHz, 5.4 GHz, and 5.8 GHz bands.  Users must ensure that the PMP 450 Series complies with local operating regulations. The PMP 450 Series adds dramatically increased network throughput and capacity.  The PMP 450 Series enables network operators to grow their business by offering more capacity for data, voice and video applications. Key features The Cambium PMP 450 Series offers the following benefits:  Cambium’s highest performing point-to-multipoint solution, with up to 90 Mbps usable throughput  State-of-the-art MIMO (Multi-In Multi-Out) technology   Better spectral efficiency than other MIMO alternatives  Efficient GPS synchronized, scheduled TDD operation for easy Access Point site deployment and performance that is consistent regardless of subscriber loading  A range of cost-effective subscriber device solutions to meet the business case of any network application  MIMO Matrix B: This technique provides for the ability to double the throughput of a radio transmission under proper RF conditions.  Different data streams are transmitted simultaneously on two different antennas. nLOS benefits and limitations In addition to providing LOS (Line-Of-Sight) connectivity, use of OFDM technology can provide nLOS (near Line-Of-Sight) connectivity and sometimes NLOS (Non-Line-Of-Sight) connectivity:  LOS: the installer can see the AP from the SM and the first Fresnel zone is clear.  nLOS: the installer can see the AP from the SM, but a portion of the first Fresnel zone is blocked.  NLOS: the installer cannot see the AP from the SM and a portion or even much of the first Fresnel zone is blocked, but subsequent Fresnel zones are open.
PMP 450 Planning Guide Overview of PMP 450  pmp-0047 (June 2013)  1-3  Figure 1  Line Of Sight Diagram   Whereas multi-pathing degrades a link in some technologies (FSK, for example), OFDM can often use multi-pathing to an advantage to overcome nLOS, especially in cases where the Fresnel zone is only partially blocked by buildings, “urban canyons”, or foliage. OFDM tends to help especially when obstacles are near the middle of the link, and less so when the obstacles are very near the SM or AP. However, attenuation through walls and trees is substantial for any use of the 2.4/5.4/5.8 GHz frequency bands. Even with OFDM, these products should not be expected to penetrate walls or extensive trees and foliage. Typical deployment The PMP 450 Series consists of Access Point Modules and Subscriber Modules.  The radio link operates on a single frequency channel in each direction using Time Division Duplex (TDD).   Applications for the PMP 450 Series include:  High throughput enterprise applications  nLOS video surveillance in metro areas  Urban area network extension  Network extension into areas with foliage Greenfield deployment The PMP 450 Series equipment may be deployed as a standalone network deployment offering a high-speed access network.
Overview of PMP 450 Product description  1-4  pmp-0047 (June 2013)  System components PMP 450 Access Point  Access Point Module (AP): A connectorized outdoor transceiver unit containing all the radio, networking, antenna, and surge suppression electronics.  Access Point Power Supply: An indoor power supply module providing Power-over-Ethernet (PoE) supply to the Access Point.  Cabling: Cat 5e cables, grounding cables, and connectors. PMP 450 Subscriber Module  Subscriber Module (SM): An integrated-antenna outdoor transceiver unit containing all the radio, antenna, and networking electronics.  Subscriber Module Power Supply: An indoor power supply module providing Power-over-Ethernet (PoE) supply to the Subscriber Module.  Cabling and lightning protection: Cat 5e cables, grounding cables, connectors and lightning protection (surge suppression). Product variants The PMP 450 Series is available in the following product variants: Table 1  PMP 450 frequency variants Variant Region Frequency Coverage (MHz) Channel Bandwidth (MHz) Variant Notes 2.4 GHz PMP 450 FCC ISM Band 2400 – 2483.5 5/10/20  5.4/5.8-GHz PMP 450 FCC UNII Band ETSI Band B ETSI Band C 5470 - 5875 10/20 Combined Transmit power limited based on Country Code setting 5.8-GHz PMP 450 (US ONLY) FCC ISM Band 5725 - 5875 5/10/20 US Only – locked to US Country Code EIRP limit of 36 dBm and 5.8-GHz Only
PMP 450 Planning Guide Access Point (AP)  pmp-0047 (June 2013)  1-5  Access Point (AP) The AP is a self-contained unit that houses both radio and networking electronics.  The AP is supplied in a connectorized configuration for use with an external antenna.  Connectorized units with external antennas can cope with more difficult radio conditions. Figure 2  AP, Radio unit  Figure 3  AP, antenna
Access Point (AP) Product description  1-6  pmp-0047 (June 2013)  AP interfaces The AP interfaces are illustrated in Figure 4.  Figure 4  AP interfaces        RF Port – Vertical RF Port – Horizontal Sync / Default Ethernet RF Port – FSK  Equilibrium Membrane Vent (do not cover) AP Ground Lug
PMP 450 Planning Guide Access Point (AP)  pmp-0047 (June 2013)  1-7  Table 2  AP interface descriptions and cabling Interface Function Cabling RF Port – Vertical  Vertical RF connection to AP antenna 50 ohm RF cable,  N-type RF Port – Horizontal  Horizontal RF connection to AP antenna 50 ohm RF cable, N-type Sync/Default GPS synchronization signaling, provides power to uGPS module.  Default plug port. RJ11 cable or default plug Power-over-Ethernet, Ethernet communications (management and data) RJ45 cable Power-over-Ethernet, Ethernet communications (management and data) RF Port – FSK For future use 50 ohm RF cable, N-type Ground Lug (bottom of unit) For grounding the unit 10 AWG copper wire  AP diagnostic LEDs The diagnostic LEDs report the following information about the status of the module.   The LED color helps you distinguish position of the LED. The LED color does not indicate any status. Figure 5  AP diagnostic LEDs, viewed from unit front        PWR SYN/1 SES/2 GPS/3 ACT/4 LNK/5
Access Point (AP) Product description  1-8  pmp-0047 (June 2013)  Table 3  AP LED descriptions LED Color when active Status information provided Notes PWR red DC power Always lit when power is correctly supplied. SYN/1 yellow Presence of sync Always lit on the AP. SES/2 green Unused on the AP  GPS/3 red Pulse of sync Continuously lit as pulse as AP receives pulse. ACT/4 yellow Presence of data activity  on the Ethernet link Flashes during data transfer. Frequency of flash is not a diagnostic indication. LNK/5 green Ethernet link Continuously lit when link is present.  Network connection The network connection to a PMP 450 Series AP is made via a 10 BaseT, 100 BaseT, or 1000 BaseT Ethernet connection.  Power is provided to the AP over the Ethernet connection using a patented non-standard powering technique. AP power supply The AP power supply generates the AP supply voltage (29 VDC) from the external DC source and injects the supply voltage into the AP. The power supply is connected to the AP and network equipment using Cat5e cable with RJ45 connectors.  Refer to Cabling and lightning protection on page 1-14. Further reading on the AP For more information on the AP, refer to the following:  AP or SM site selection on page 2-11 describes how to select a site for the AP or SM.
PMP 450 Planning Guide Subscriber Module (SM)  pmp-0047 (June 2013)  1-9  Subscriber Module (SM) The SM is a self-contained unit that houses both radio and networking electronics.  The SM is supplied in an integrated antenna configuration, but may also be used with a passive reflector dish or CLIP (Cassegrain Lens for Improved Performance). Figure 6  PMP 450 Series SM
Subscriber Module (SM) Product description  1-10  pmp-0047 (June 2013)  SM interfaces Figure 7  SM interfaces      Table 4  SM Interfaces Interface Function Cabling Ethernet Power-over-Ethernet, Ethernet communications (management and data) RJ45 Cable Sync / Default Default plug port. RJ11 cable, default plug Ground Lug (bottom of unit) For grounding the unit 10 AWG copper wire  Ethernet Ground Lug Sync / Default
PMP 450 Planning Guide Subscriber Module (SM)  pmp-0047 (June 2013)  1-11  SM diagnostic LEDs The diagnostic LEDs report the following information about the status of the module.  The SM LEDs provide different status based on the mode of the SM.  An SM in “operating” mode will register and pass traffic normally.  An SM in “aiming” mode will not register or pass traffic, but will display (via LED panel) the strength of received radio signals (based on radio channel selected via Tools, Alignment).   The LED color helps you distinguish position of the LED. The LED color does not indicate any status.  Figure 8  SM diagnostic LEDs, viewed from unit front SM LED Display LED Labels        LNK/5 ACT/4 GPS/3 SES/2 SYN/1 PWR
Subscriber Module (SM) Product description  1-12  pmp-0047 (June 2013)  Table 5  SM diagnostic LED descriptions   Status information provided  LED Color when active SM in “Operating” Mode SM in “Aiming” Mode Notes LNK/5 green Ethernet link These five LEDs act as a bar graph to indicate the relative quality of alignment. As power level improves during alignment, more of these LEDs are lit.   Continuously lit when link is present.  ACT/4 yellow Presence of data activity  on the Ethernet link Flashes during data transfer. Frequency of flash is not a diagnostic indication. GPS/3 red Interference On - high interference. Blinking - medium interference. Off - low interference. SES/2 green Strong Receive Signal Power  Blinking from slow to full-on to indicate strong power, getting stronger. SYN/1 yellow Medium Receive Signal Power  Blinking from slow to full-on to indicate medium power, getting stronger. PWR red Registration Indicator  Off when registered to AP. On when not registered to AP.  Mounting brackets For mounting PMP 450 SMs, Cambium Networks offers the SMMB1A mounting bracket. Network connection The network connection to a PMP 450 Series SM is made via a 10 BaseT or 100 BaseT Ethernet connection.  Power is provided to the SM over the Ethernet connection using a patented non-standard powering technique. SM power supply The SM power supply generates the SM supply voltage (29 VDC) from the external DC source and injects the supply voltage into the SM. The power supply is connected to the SM and network equipment using Cat5e cable with RJ45 connectors.  Refer to Cabling and lightning protection on page 1-14.
PMP 450 Planning Guide Subscriber Module (SM)  pmp-0047 (June 2013)  1-13  Further reading on the SM For more information on the SM, refer to the following:  AP or SM site selection on page 2-11 describes how to select a site for the SM.
Cabling and lightning protection Product description  1-14  pmp-0047 (June 2013)  Cabling and lightning protection This section describes the cabling and lightning protection components of a PMP 450 installation. PMP and lightning protection Due to the full metallic connection to the tower or support structure through the AP antenna, grounding the AP and installing a 600SS surge suppressor at the Ethernet cable building ingress is strongly recommended.  This suppresses overvoltages and overcurrents such as those caused by near-miss lightning.  APs provide a grounding lug for grounding to the tower or support structure.  The PMP 450 Series is not designed to survive direct lightning strikes. For this reason the unit should not be installed as the highest point in a localized area. Outdoor connections The term ‘drop cable’ refers to the cable that is used for all connections that terminate outside the building, for example, connections between the AP/SM, surge supressors (if installed), GPS receivers (if installed) and the power supply injector. The following practices are essential to the reliability and longevity of cabled connections:  Use only shielded cables and connectors to resist interference and corrosion  For vertical runs, provide cable support and strain relief  Include a 2 ft (0.6 m) service loop on each end of the cable to allow for thermal expansion and contraction and to facilitate terminating the cable again when needed  Include a drip loop to shed water so that most of the water does not reach the connector at the device  Properly crimp all connectors  Use dielectric grease on all connectors to resist corrosion
PMP 450 Planning Guide Wireless operation  pmp-0047 (June 2013)  1-15  Wireless operation This section describes how the PMP 450 wireless link is operated, including modulation modes, power control and security. Time division duplexing The system uses Time Division Duplexing (TDD) – one channel alternately transmits and receives rather than using one channel for transmitting and a second channel for receiving.  To accomplish TDD, the AP must provide sync to its SMs.  Furthermore, collocated APs must be synced together – an unsynchronized AP that transmits during the receive cycle of a collocated AP can prevent a second AP from being able to decode the signals from its SMs.  In addition, across a geographical area, APs that can “hear” each other benefit from using a common sync to further reduce self-interference within the network. Modules use TDD on a common frequency to divide frames for uplink (orange) and downlink (green) usage, as shown in Figure 9. For more information on synchronization configuration options, see section Planning for co-location and using the OFDM Frame Calculator Tool on page 2-25. Figure 9  TDD frame division   OFDM and channel bandwidth The PMP 450 Series transmits using Orthogonal Frequency Division Multiplexing (OFDM).  The channel bandwidth of the OFDM signal may be configured to 5 MHz, 10 MHz or 20 MHz.    Time
Wireless operation Product description  1-16  pmp-0047 (June 2013)  Link operation – Dynamic Rate Adapt PMP 450 Series products offer four levels or speeds of operation – 1x (QPSK), 2x (QPSK-MIMO-B), 4x (16QAM-MIMO-B), and 6X (64QAM-MIMO-B). If received power is less due to distance between the AP and the SM or due to obstructions, or if interference affects the RF environment, the system will automatically and dynamically adjust links to the best operation level.  The system chooses its operation rate dynamically, based on an internal ARQ (Automatic Repeat reQuest) error control method. With ARQ, every data slot of every frame sent over the air (except downlink broadcast) is expected to be acknowledged by the receiver, and if acknowledgement is not received, the data is resent. The sending unit monitors these resends, and adjusts the operation rate accordingly. A normal system may have links that change levels of operation as the RF environment changes. Furthermore, the links operate independently; normal operation can have a downlink running at 6X while the uplink RF environment only supports 2x. Optimal sector utilization involves having as many links as possible running at 6x. This provides as much capacity as possible for the sector.  Table 6  Link Budget Details – Dynamic Rate Adapt, 2.4 GHz Variant  Product Parameter Performance Details 2x 4x 6x PMP 450 Modulation QPSK-MIMO 16-QAM-MIMO 64-QAM-MIMO 2.4-GHz Max. LOS Link Budget (no fade margin) – 20 MHz channel bandwidth with Integrated SM antenna 10.0 4.6 2.0 with connectorized antenna that adds 14 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range 63.4 28.9 12.9 2.4-GHz Max. LOS Link Budget (no fade margin) – 10 MHz channel bandwidth with Integrated SM antenna 14.2 6.5 2.9 with connectorized antenna that adds 14 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range 89.6 40.8 18.2 2.4-GHz Max. LOS Link with Integrated SM antenna 20.1 9.1 4.1
PMP 450 Planning Guide Wireless operation  pmp-0047 (June 2013)  1-17  Budget (no fade margin) –5 MHz channel bandwidth with connectorized antenna that adds 14 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range 126.8 57.7 25.8 2.4-GHz Max. Aggregate Throughput with 1/16 Cyclic Prefix to 1 SM (75%/25% DL/UL Ratio) – RF Link Test 20 MHz Channel: (up+down)    10 MHz Channel: (up+down)    5 MHz Channel: (up+down)    2.4-GHz Nominal Combined Receive Sensitivity (including FEC)* 20 MHz Channel -84 dBm -77 dBm -70 dBm 10 MHz Channel -87 dBm -80 dBm -73 dBm 5 MHz Channel -90 dBm -83 dBm -76 dBm Link Budget (dB) 20 MHz Channel 124.4 117.6 110.6 10 MHz Channel 127.4 120.6 113.6 5 MHz Channel 130.4 123.6 116.6 Margin to Registration Sensitivity (dB) 20 MHz Channel    10 MHz Channel    5 MHz Channel                                                               * PMP 450 devices include two antennas, vertical and horizontal.  Listed receive sensitivity corresponds to the combined horizontal and vertical receive powers.  The PMP 450 management interface displays receive power level readings as a combination of the vertical and horizontal power levels.
Wireless operation Product description  1-18  pmp-0047 (June 2013)  Minimum Signal-to-Noise Ratio (SNR) Required (dB) 5/10/20 MHz Channel 10 17 24   Table 7  Link Budget Details – Dynamic Rate Adapt, 5.4 GHz / 5.8 GHz Variant  Product Parameter Performance Details 2x 4x 6x PMP 450 Modulation QPSK-MIMO 16-QAM-MIMO 64-QAM-MIMO 5.4/5.8-GHz Max. LOS Link Budget (no fade margin) – 20 MHz channel bandwidth with Integrated SM antenna 6.7 mi / 10.9 km 2.7 mi / 4.3 km 1 mi / 1.7 km with CLIP that adds 8 dB to SM Range 17 mi / 27.4 km 6.8 mi / 10.9 km 2.7 mi / 4.3 km with LENS that adds 5.5 dB to SM Range  12.7 mi / 20.5 km  5 mi / 8.1 km  2 mi / 3.2 km  with Reflector Dish that adds 14 dB to SM Range 34 mi / 54.7 km 13.5 mi / 21.7 km 5.3 mi / 8.6 km 5.4/5.8-GHz Max. LOS Link Budget (no fade margin) – 10 MHz channel bandwidth with Integrated SM antenna 9.5 mi / 15.4 km 3.8 mi / 6.1 km 1.5 mi / 2.4 km with CLIP that adds 8 dB to SM Range 24.1 mi / 38.8 km 9.6 mi / 15.4 km 3.8 mi / 6.1 km with LENS that adds 5.5 dB to SM Range  18 mi / 29 km  7.1 mi / 11.5 km  2.8 mi / 4.6 km  with Reflector Dish that adds 14 dB to SM Range 40 mi / 64.3 km 19.1 mi / 30.7 km 7.6 mi / 12.2 km 5.4/5.8-GHz Max. LOS Link Budget (no fade margin) –5 MHz channel with Integrated SM antenna    with CLIP that adds 8 dB to SM Range    with LENS that adds 5.5 dB to SM Range
PMP 450 Planning Guide Wireless operation  pmp-0047 (June 2013)  1-19  bandwidth with Reflector Dish that adds 14 dB to SM Range    5.4/5.8-GHz Max. Aggregate Throughput with 1/16 Cyclic Prefix to 1 SM (75%/25% DL/UL Ratio) – RF Link Test 20 MHz Channel: (up+down) 30 Mbps 60 Mbps 98 Mbps 10 MHz Channel: (up+down) 13 Mbps 26 Mbps 39 Mbps 5 MHz Channel: (up+down)    5.4/5.8-GHz Nominal Combined Receive Sensitivity (including FEC)† 20 MHz Channel -80 dBm -73 dBm -66 dBm 10 MHz Channel -83 dBm -76 dBm -69 dBm 5 MHz Channel    Link Budget (dB) 20 MHz Channel 128.5 120.5 112.5 10 MHz Channel 131.5 123.5 115.5 5 MHz Channel    Margin to Registration Sensitivity (dB) 20 MHz Channel 2 10 18 10 MHz Channel 2 10 18 5 MHz Channel                                                               † PMP 450 devices include two antennas, vertical and horizontal.  Listed receive sensitivity corresponds to the combined horizontal and vertical receive powers.  The PMP 450 management interface displays receive power level readings as a combination of the vertical and horizontal power levels.
Wireless operation Product description  1-20  pmp-0047 (June 2013)  Minimum Signal-to-Noise Ratio (SNR) Required (dB) 5/10/20 MHz Channel 10 18 25  Adaptive modulation PMP 450 units can transport data over the wireless link using a number of different modulation modes.  The radio automatically selects QPSK (Quadrature Phase Shift Keying), 16-QAM (Quadrature Amplitude Modulation), or 64-QAM based on the RF environment to provide 2x, 4x, and 6x operation. MIMO Multiple-Input Multiple-Output (MIMO) techniques provide protection against fading and increase the probability that the receiver will decode a usable signal.  When the effects of MIMO are combined with those of OFDM techniques and a high link budget, there is a high probability of a robust connection over a non-line-of-sight path. The sub-feature that comprises the MIMO technique utilized in the PMP 450 product is:  Matrix B: This technique provides for the ability to double the throughput of a radio transmission under proper RF conditions.  Different data streams are transmitted simultaneously on two different antennas. Cyclic Prefix OFDM technology uses a cyclic prefix, where a portion of the end of a symbol (slot) is repeated at the beginning of the symbol (slot) to allow multi-pathing to settle before receiving the desired data. A 1/16 cyclic prefix means that for every 16 bits of throughput data transmitted, an additional bit is used.
PMP 450 Planning Guide Wireless operation  pmp-0047 (June 2013)  1-21  Encryption The Cambium PMP 450 Series supports optional encryption for data transmitted over the wireless link.  The PMP 450 Series supports the following forms of encryption for security of the wireless link:  DES (Data Encryption Standard):  An over-the-air link encryption option that uses secret 56-bit keys and 8 parity bits.  DES performs a series of bit permutations, substitutions, and recombination operations on blocks of data.  DES encryption does not affect the performance or throughput of the system.  AES (Advanced Encryption Standard):  An over-the-air link encryption option that uses the Rijndael algorithm and 128-bit keys to establish a higher level of security than DES.  AES products are certified as compliant with the Federal Information Processing Standards (FIPS 197) in the U.S.A. Further reading on wireless operation For information on planning wireless operation, refer to the following:  Regulatory planning on page 2-2 describes the regulatory restrictions that affect radio spectrum usage, such as frequency range.
System management Product description  1-22  pmp-0047 (June 2013)  System management This section introduces the PMP 450 management system, including the web interface, installation, configuration, alerts and upgrades, and management software. Management agent PMP 450 equipment is managed through an embedded management agent.  Management workstations, network management systems or PCs can be connected to this agent using the module’s Ethernet port or over-the air (SM). The management agent supports the following interfaces:  Hypertext transfer protocol (HTTP)  RADIUS authentication  Simple network management protocol (SNMP)  Network time protocol (NTP)  System logging (Syslog)  Wireless Manager (WM) software  Canopy Network Updater Tool (CNUT) software Web server The PMP 450 management agent contains a web server. The web server supports access via the HTTP interface.. Web-based management offers a convenient way to manage the PMP 450 equipment from a locally connected computer or from a network management workstation connected through a management network, without requiring any special management software. The web-based interfaces are the only interfaces supported for installation of PMP 450, and for the majority of PMP 450 configuration management tasks.
PMP 450 Planning Guide System management  pmp-0047 (June 2013)  1-23  Figure 10  AP web-based management screenshot
System management Product description  1-24  pmp-0047 (June 2013)  Web pages The web-based management interfaces provide comprehensive web-based fault, configuration, performance and security management functions organized into the following web-pages and groups: Access Point web-pages:  Home:  The Home web-page reports the general device status, session status, remote subscriber status, event log information, network interface status, and layer 2 neighbor information.  Configuration: The Configuration web-page may be utilized for configuring general device parameters, as well as IP, radio, SNMP, Quality of Service (QoS), security, time, VLAN, DiffServ, protocol filtering, and unit settings.  Statistics: The Statistics web-page reports detailed operating statistics for the scheduler, SM registration failures, bridge control block, bridging table, Ethernet, radio, VLAN, data VC, throughput, filter, ARP, overload, DHCP relay, pass through, and DNS.  Tools: The Tools web-page offers useful tools for device installation, configuration, and operation including link capacity test, frame calculator, subscriber configuration, link status, remote spectrum analyzer, sessions, and DNS test.  Logs: The Logs web-page displays logs related to device operation including AP sessions, AP authentication state machine, AP authorization state machine, and EAP Radius.  Accounts: These web-pages are used to configure device user accounts.  Quick Start: The Quick Start web-page provides a walkthrough of configuring radio parameters for initial operation.  Copyright: The Copyright web-page displays pertinent device copyright information.  Subscriber Module web-pages:  Home:  The Home web-page reports the general device status, event log information, network interface status, and layer 2 neighbor information.  Configuration: The Configuration web-page may be utilized for configuring general device parameters, as well as IP, radio, SNMP, Quality of Service (QoS), security, VLAN, DiffServ, protocol filtering, NAT, PPPoE, NAT port mapping, and unit settings.  Statistics: The Statistics web-page reports detailed operating statistics for the scheduler, bridge control block, bridging table, translation table, Ethernet, radio, VLAN, data VC, filter, NAT, NAT DHCP, ARP, overload, PPPoE, peer information, and DNS.  Tools: The Tools web-page offers useful tools for device installation, configuration, and operation including a spectrum analyzer, alignment configuration and tool, link capacity test, AP evaluation, frame calculator, BER results, link status, and DNS test.  Logs: The Logs web-page displays logs related to device operation including the NAT table, SM session, SM authentication, SM authorization, PPPoE session, and EAP Radius.  Accounts: These web-pages are used to configure device user accounts.  PDA: The PDA web-page includes 320 x 240 pixel formatted displays of information important to installation and alignment for installers using legacy PDA devices.  All device web pages are compatible with touch devices such as smart phones and tablets.  Copyright: The Copyright web-page displays pertinent device copyright information.
PMP 450 Planning Guide System management  pmp-0047 (June 2013)  1-25  Identity-based user accounts When identity-based user accounts are configured, a security officer can define from one to four user accounts, each of which may have one of the four possible roles:  ADMINISTRATOR, who has full read and write permissions. This is the level of the root and admin users, as well as any other administrator accounts that one of them creates.  INSTALLER, who has permissions identical to those of ADMINISTRATOR except that the installer cannot add or delete users or change the password of any other user.  TECHNICIAN, who has permissions to modify basic radio parameters and view informational web pages  GUEST, who has no write permissions and only a limited view of General Status tab  See Table 27  Identity-based user account permissions - AP on page 2-53 and Table 28  Identity-based user account permissions - SM on page 2-55 for detailed information on account permissions.  Remote Authentication Dial In User Service (RADIUS) The PMP 450 system includes support for RADIUS (Remote Authentication Dial In User Service) protocol functionality including:  Authentication: Allows only known SMs onto the network (blocking “rogue” SMs), and can be configured to ensure SMs are connecting to a known network (preventing SMs from connecting to “rogue” APs). RADIUS authentication is used for SMs, but not used for APs.  SM Configuration: Configures authenticated SMs with MIR (Maximum Information Rate), High Priority, and VLAN (Virtual LAN) parameters from the RADIUS server when an SM registers to an AP.  SM Accounting provides support for RADIUS accounting messages for usage-based billing.  This accounting includes indications for subscriber session establishment, subscriber session disconnection, and bandwidth usage per session for each SM that connects to the AP.    Centralized AP and SM user name and password management: Allows AP and SM usernames and access levels (Administrator, Installer, Technician) to be centrally administered in the RADIUS server instead of on each radio and tracks access events (logon/logoff) for each username on the RADIUS server. This accounting does not track and report specific configuration actions performed on radios or pull statistics such as bit counts from the radios. Such functions require an Element Management System (EMS) such as Cambium Wireless Manager. This accounting is not the ability to perform accounting functions on the subscriber/end user/customer account.  Framed-IP-Address: Operators may use a RADIUS server to assign management IP addressing to SM modules.   SNMP The management agent supports fault and performance management by means of an SNMP interface. The management agent is compatible with SNMP v1 and SNMP v2c using 5 Management Information Base (MIB) files which are available for download from the Cambium Networks Support website (http://www.cambiumnetworks.com/support/pmp/software/).
System management Product description  1-26  pmp-0047 (June 2013)  Network Time Protocol (NTP) The clock supplies accurate date and time information to the system. It can be set to run with or without a connection to a network time server (NTP). It can be configured to display local time by setting the time zone and daylight saving in the Time web page. If an NTP server connection is available, the clock can be set to synchronize with the server time at regular intervals.  PMP 450 devices may receive NTP data from a CMM3 or CMM4 module, an NTP server configured in the system’s management network or  a UGPS module. The Time Zone option is configurable on the AP’s Time Configuration page, and may be used to offset the received NTP time to match the operator’s local time zone.  When set on the AP, the offset will be set for the entire sector (SMs will be notified of the current Time Zone upon initial registration).  If a Time Zone change is applied, the SMs will be notified of the change in a best effort fashion, meaning some SMs may not pick up the change until the next re-registration.  Time Zone changes are noted in the Event Log of the AP and SM. An AP which is receiving NTP date and time information from an NTP server or from a GPS synchronization source may be used as an NTP server.  Any client which has IP connectivity to the AP may request NTP date and time information from the AP.  No additional configuration (other than the AP receiving valid NTP data) is required to use the AP as an NTP server.  Wireless Manager (WM) Cambium Networks Wireless Manager 4.0 is recommended for managing PMP 450 networks.  You can achieve better uptime through better visibility of your network with the Cambium Wireless Manager. This network management software tool offers breakthrough map-based visualization capabilities using embedded Google maps, and combined with advanced configuration, provisioning, alerting and reporting features you can control your entire outdoor wireless network including Mesh Wide Area Network, and Point-to-Multipoint and Point-to-Point solutions as well as other SNMP enabled devices. With its powerful user interface you will not only be able to control your network's access, distribution and backhaul layers, but you will also have visibility to WLAN sites and be able to quickly launch indoor network management systems.
PMP 450 Planning Guide System management  pmp-0047 (June 2013)  1-27   Some key features of Wireless Manager are:  Template-Based Configuration: With Wireless Manager's user-defined templates you can accelerate the process for the configuration of the devices you add to your network resulting in quicker and easier deployments. The template-based functionality provides an automated way to configure large numbers of network devices with just a few mouse clicks, and can be scheduled to occur at any time via Wireless Manager's Task Scheduler.  Ultralight Thin Client: With the growing mobile workforce it is important to have access to the status of your network at any time. With Wireless Manager you can view the status and performance of your entire wireless network via a compact web interface accessible by your smart phone.  Map-Based Visualization: Wireless Manager overlays sophisticated real-time information about your network elements onto building layouts and dynamic Google maps. Visuals can be scaled to view an entire city or building or a specific area, floor or link.  High Availability Architecture Support: Wireless Manager offers a high availability option, providing a highly reliable and redundant network management solution that ensures you always have management access to your network.  High Scalability: The enhanced Wireless Manager offers you server scalability with support for up to 10,000 nodes as well as support for distributed server architecture.  Cambium’s Wireless Manager 4.0 available for download at: http://www.cambiumnetworks.com/support under “Management Tools”.
System management Product description  1-28  pmp-0047 (June 2013)  Canopy Network Updater Tool (CNUT) CNUT (Canopy Network Updater Tool) is the stand-alone software update tool for PMP 450 Series products.   The Canopy Network Updater Tool:  automatically discovers all network elements  executes a UDP command that initiates and terminates the Autoupdate mode within APs. This command is both secure and convenient: o For security, the AP accepts this command from only the IP address that you specify in the Configuration page of the AP.  o For convenience, Network Updater automatically sets this Configuration parameter in the APs to the IP address of the Network Updater server when the server performs any of the update commands.  allows you to choose among updating o your entire network. o only elements that you select. o only network branches that you select.  provides a Script Engine that you can use with any script that o you define. o Cambium supplies. CNUT is available at http://www.cambiumnetworks.com/support/planning/index.php?cat=3&type=1 Capacity upgrades Capacity upgrades are supplied as an access key purchased from your Cambium Point-to-Multipoint distributor or solutions provider. The upgrade is applied by entering the supplied URL in a PMP 450 module-connected web browser address bar. Software upgrade CNUT (Canopy Network Updater Tool) is the stand-alone software update tool for PMP 450 Series products.  CNUT is available at http://www.cambiumnetworks.com/support/planning/index.php?cat=3&type=1  Further reading on system management For more information on system management, refer to the following:  Security planning on page 2-52 describes how to plan for PMP 450 links to operate in secure modes.
PMP 450 Planning Guide Planning considerations    Chapter 2:  Planning considerations This chapter provides information to help the user to plan a PMP 450 network. The following topics are described in this chapter:  Regulatory planning on page 2-2 describes how to plan PMP 450 links to conform to the regulatory restrictions that apply in the country of operation.  Network migration planning on page 2-3 presents migration scenarios to aid in planning a network deployment  Site planning on page 2-11 describes factors to be considered when choosing sites for the equipment  Link planning on page 2-12 describes factors to be taken into account when planning links, such as range, path loss and throughput.   Analyzing the RF Environment on page 2-20 describes how to map RF neighbor frequencies, anticipate reflection, assess RF obstructions in the Fresnel Zone, and plan channel usage.  Selecting Sites for Network Elements on page 2-28 describes how to survey sites, find expected coverage areas, clear the radio horizon, and calculate aim angles.  Diagramming Network Layouts on page 2-31 includes tips on how to avoid self interference as well as interference from external sources.  Grounding and lightning protection on page 2-33 discusses wiring standards, the need for surge protection, lightning protection zones, and general protection requirements.  Configuration options for TDD synchronization on page 2-41 covers the importance of GPS synchronization as well as planning for installation  Data network planning on page 2-44 discusses IP networking and other networking features provided with the PMP 450 product  Security planning on page 2-52 can be referenced for information regarding security features of the product.
 Planning considerations  2-2  pmp-0047 (June 2013)  Regulatory planning This section describes how to plan PMP 450 links to conform to the regulatory restrictions that apply in the country of operation.  It is the responsibility of the user to ensure that the PMP product is operated in accordance with local regulatory limits.   Contact the applicable radio regulator to find out whether or not registration of the PMP network is required. Obeying Regulatory limits The local regulator may restrict frequency usage and channel width, and may limit the amount of conducted or radiated transmitter power. Some countries impose conducted power limits on products operating in the 2.4 GHz, 5.4 GHz and 5.8 GHz bands.  For detailed information, see Compliance with radio regulations on page 4-15.  Conforming to the limits Ensure the system is configured to conform to local regulatory requirements by setting the appropriate Country Code setting on the APs and SMs in the network. When using connectorized APs with external antennas, the regulations may require the maximum transmit power to be reduced. To ensure that regulatory requirements are met for connectorized installations, refer to Calculating maximum power level for connectorized AP units on page 2-18.
PMP 450 Planning Guide Network migration planning  pmp-0047 (June 2013)  2-3  Network migration planning The PMP 450 Series offers current network operators the ability to migrate to PMP 450 for expanded network capacity and capability.  The following sections are provided to aid in establishing a planning framework for deploying a PMP 450 system.   Example PMP 450 deployment scenario The following sections detail example network deployment scenarios for the PMP 450 product.  This table may be referenced to begin planning the PMP 450 deployment based on the current network configuration (if applicable).   Definitions of deployment scenario terminology Table 8  Deployment scenario terminology descriptions Term Definition Existing System Release The current running system software release Existing Number of Sectors The total number of AP sectors co-located in the current system Existing Modulation The type of modulation used in the current network.  “FSK” indicates an existing PMP 1x0 series network, and “OFDM” indicates an existing PMP 430 network. Existing Frequency Re-use Pattern The current deployment’s usage of frequency across tower sectors.  For example, in a six AP sector deployment, the following represents an ABC frequency re-use pattern.  Sector 1 (A):  5740  Sector 2 (B):   5760  Sector 3 (C):  5780  Sector 4 (A):  5740  Sector 5 (B):   5760  Sector 6 (C):  5780 The deployment scenarios define their own customized examples of frequency re-use patterns. For multiple AP cluster deployments, see Multiple OFDM Access Point Clusters on page 2-23
Network migration planning Planning considerations  2-4  pmp-0047 (June 2013)  Term Definition Existing Ch BW (MHz) The channel size, or channel bandwidth used in the current system.  For FSK (PMP 1x0 series) deployments, the channel bandwidth is always 20 MHz.  For OFDM (PMP 430) deployments, the channel size may be 5, 10, or 20 MHz. Existing Total Bandwidth Used (MHz) The total amount of spectrum, in MHz, which is used by the existing system. Existing Aggregate Tower Throughput  (Mbps) The total amount of throughput, in Mbps, available in the current network deployment.  Existing Additional Frequencies Available  (MHz) The number of additional frequencies unused by the current deployment that are available for usage by PMP 450 equipment. FINAL:  Aggregate Throughput (Mbps) The aggregate throughput available after upgrading to a PMP 450 network. Resulting Number of Sectors The number of sectors configured in the new PMP 450 network installation. Resulting Modulation The modulation scheme utilized in the new PMP 450 network installation. Resulting Frequency Re-use Pattern The new frequency re-use pattern utilized in the new PMP 450 network installation.  Each deployment scenario in this section includes a custom example of a frequency re-use plan. Resulting Ch BW (MHz) The resulting channel bandwidth configured in the PMP 450 system. Resulting Total Bandwidth Used (MHz) The total amount of spectrum which is used by the existing system. Resulting Aggregate Tower Throughput  (Mbps) The aggregate throughput available after upgrading to a PMP 450 network. Resulting Percentage Increase in Aggregate Tower Throughput The amount of increase in tower (all sectors) throughput after upgrading to a PMP 450 network. Total Bandwidth Used (During Migration)  (MHz) The total amount of spectrum (in MHz) used when migrating to a PMP 450 deployment.
PMP 450 Planning Guide Network migration planning  pmp-0047 (June 2013)  2-5  Sector capacity The following table exhibits the maximum aggregate sector throughput for several Cambium network deployments.  This table may be used as a reference for planning new networks or for planning network upgrades. Table 9  Examples of aggregate sector throughput – various air interfaces Air Interface Rate Adapt Ch BW   (MHz) Cyclic Prefix Maximum Aggregate Sector Throughput  - RF Link Test (Mbps) FSK (PMP 1x0 Series) 1x 20  N/A 7 FSK (PMP 1x0 Series) 2x 20  N/A 14 OFDM (PMP 430 Series) 1x 5 CP 1/16 4 OFDM (PMP 430 Series) 2x 5 CP 1/16 8 OFDM (PMP 430 Series) 3x 5 CP 1/16 12 OFDM (PMP 430 Series) 1x 10 CP 1/16 7 OFDM (PMP 430 Series) 2x 10 CP 1/16 15 OFDM (PMP 430 Series) 3x 10 CP 1/16 24 OFDM (PMP 430 Series) 1x 20 CP 1/16 15 OFDM (PMP 430 Series) 2x 20 CP 1/16 32 OFDM (PMP 430 Series) 3x 20 CP 1/16 50 OFDM (MIMO) (PMP 450 Series) 2x 10 CP 1/16 13 OFDM (MIMO) (PMP 450 Series) 4x 10 CP 1/16 26 OFDM (MIMO) (PMP 450 Series) 6x 10 CP 1/16 39 OFDM (MIMO) (PMP 450 Series) 2x 20 CP 1/16 30 OFDM (MIMO) (PMP 450 Series) 4x 20 CP 1/16 60 OFDM (MIMO) (PMP 450 Series) 6x 20 CP 1/16 98
Network migration planning Planning considerations  2-6  pmp-0047 (June 2013)  Deployment scenario 1 – Replacing PMP 100 Equipment (20 MHz Channel Bandwidth) Deployment scenario 1 assumes that the existing network is comprised of PMP 1x0 equipment (i.e. PMP 100, PMP 120, etc.) with the configuration listed below in Table 10.  The migration in this scenario results in a complete replacement of PMP 1x0 series equipment with PMP 450 equipment. Scenario 1 assumes that neighbouring frequencies are free and that a guard band is not required at the edges of the spectrum used for transmission. Table 10  Deployment scenario 1 Term Definition Existing System Release 11.2 Existing Number of Sectors 6 Existing Modulation FSK Existing Frequency Re-use Pattern ABC ABC Existing Ch BW (MHz) 20 Existing Aggregate Tower Throughput  (Mbps) 84 Existing Total Bandwidth Used (MHz) 60 Existing Additional Frequencies Available  (MHz) 10 Replace Legacy Subscribers with 450 SMs Required   Resulting Number of Sectors 6 Resulting Modulation OFDM (MIMO) Resulting Frequency Re-use Pattern ABC ABC Resulting Ch BW (MHz) 20 Resulting Total Bandwidth Used (MHz) 60 Resulting Aggregate Tower Throughput  (Mbps) 570 Resulting Percentage Increase in Aggregate Tower Throughput 679%
PMP 450 Planning Guide Network migration planning  pmp-0047 (June 2013)  2-7  Table 11  Scenario 1 spectrum usage Beginning frequency usage  Resulting frequency usage (assuming no interference at band edges) 5725          5730          5735          5740   FSK (A)     MIMO (A) 5.740 GHz 5745          5750          5755          5760   FSK (B)     MIMO (B) 5.760 GHz 5765          5770          5775          5780   FSK (C)     MIMO (C) 5.780 GHz 5785          5790          5795          5800
Network migration planning Planning considerations  2-8  pmp-0047 (June 2013)  Deployment scenario 1 migration procedure This procedure assumes that there are no temporary frequencies available and that the PMP 450 APs will replace the existing APs. Procedure 1a  Deployment scenario 1 migration procedure 1 Identify proximity to potential system interferers by running a spectrum analysis scan where the PMP 450 equipment will be deployed.  It is recommended to run this scan at several different times of day and night 2 Record relevant AP and SM configuration parameters within the current operating network, if applicable, including:  authentication, and authorization parameters  frequency configuration  data network configuration  RF statistics  security configuration 3 Configure the PMP 450 AP and SMs for deployment 4 Install the PMP 450 AP 5 Install the PMP 450 MIMO(frequency A) SMs – powered on 6 Verify SM registration, link quality, and link performance. 7 Continue installation for frequency B sector and frequency C sector.
PMP 450 Planning Guide Network migration planning  pmp-0047 (June 2013)  2-9  Deployment scenario 2 – Replacing PMP 430 equipment (10 MHz Channel Bandwidth) Deployment scenario 2 assumes that the existing network is comprised of PMP 430 equipment with the configuration listed below in Table 12.  The migration in this scenario results in a complete replacement of PMP 430 series equipment with PMP 450 equipment. Table 12  Deployment scenario 2 Term Definition Existing System Release 11.2 Existing Number of Sectors 6 Existing Modulation OFDM Existing Frequency Re-use Pattern ABC ABC Existing Ch BW (MHz) 10 Existing Aggregate Tower Throughput  (Mbps) 135 Existing Total Bandwidth Used (MHz) 30 Existing Additional Frequencies Available  (MHz) 0 Replace Legacy Subscribers with 450 SMs Required   Resulting Number of Sectors 6 Resulting Modulation OFDM (MIMO) Resulting Frequency Re-use Pattern ABC ABC Resulting Ch BW (MHz) 10 Resulting Total Bandwidth Used (MHz) 30 Resulting Aggregate Tower Throughput  (Mbps) 234 Resulting Percentage Increase in Aggregate Tower Throughput 173%
Network migration planning Planning considerations  2-10  pmp-0047 (June 2013)  Table 13  Deployment scenario 2 spectrum usage Beginning PMP 430 frequency usage   Resulting PMP 450 frequency usage  5725         5730           5735           5740   OFDM (A)      MIMO (A) 5.740 GHz 5745           5750   OFDM (B)       MIMO (B) 5.750 GHz 5755           5760   OFDM (C)      MIMO (C) 5.760 GHz 5765           5770           Deployment scenario 2 migration procedure This procedure assumes that there are no temporary frequencies available and that the PMP 450 APs will replace the existing APs. Procedure 2  Deployment scenario 2 migration procedure 1 Identify proximity to potential system interferers by running a spectrum analysis scan where the PMP 450 equipment will be deployed.  It is recommended to run this scan at several different times of day and night 2 Record relevant AP and SM configuration parameters within the current operating network, if applicable, including:  authentication, and authorization parameters  frequency configuration  data network configuration  RF statistics  security configuration 3 Configure the PMP 450 AP and SMs for deployment 4 Install the PMP 450 AP (frequency A) 5 Install the PMP 450 MIMO (frequency A) SMs – powered on 6 Verify SM registration, link quality, and link performance. 7 Continue installation for frequency B sector and frequency C sector.
PMP 450 Planning Guide Site planning  pmp-0047 (June 2013)  2-11  Site planning This section describes factors to be taken into account when choosing sites for the AP or SM, power supplies, CMM4 (if applicable) and GPS antenna (if applicable). AP or SM site selection  When selecting a site for the AP or SM, consider the following factors:  Height and location to ensure that people are kept away from the antenna; see Calculated distances and power compliance margins on page 4-12.  Height and location to achieve the best radio path.  Ability to meet the requirements specified in Grounding and lightning protection on page 2-33.  Aesthetics and planning permission issues.  Cable lengths; see Maximum cable lengths on page 2-11.  The effect of strong winds on the installation; see Wind loading on page 2-12. Power supply site selection  When selecting a site for the AP or SM power supply, consider the following factors:  Indoor location with no possibility of condensation.  Availability of a mains electricity supply.  Accessibility for viewing status indicator LED and connecting Ethernet cables.  Cable lengths; see Maximum cable lengths on page 2-11. Maximum cable lengths When installing PMP 450 Series APs or SMs, the maximum permitted length of the shielded copper Ethernet interface cable is 330 feet (100m) from AP/SM to their associated power supplies or CMM4.   When receiving synchronization signalling from a UGPS module, see table below for maximum synchronization cable lengths.
Site planning Planning considerations  2-12  pmp-0047 (June 2013)  Table 14  Sync cable length specification Configuration Maximum Cable Length (feet) Maximum Cable Length (meters) UGPS powered via external power source 330 100 UGPS powered via PMP 450 AP (via AP sync port) 130 40  Wind loading Ensure that the site will not be prone to excessive wind loading. Antennas and equipment mounted on towers or buildings will subject the mounting structure to significant lateral forces when there is appreciable wind.  Antennas are normally specified by the amount of force (in pounds) for specific wind strengths. The magnitude of the force depends on both the wind strength and size of the antenna. Calculation of lateral force (metric) The magnitude of the lateral force can be estimated from: Force (in kilogrammes) = 0.1045aV2 Where:  Is:   a  surface area in square meters  V  wind speed in meters per second  The lateral force produced by a single PMP 450 at different wind speeds is shown in Table 15  Lateral force - metric and Table 16  Lateral force - US. Table 15  Lateral force - metric Largest  surface area (square meters) Lateral force (Kg) at wind speed (meters per second) 30 40 50 60 70 .066 (AP) 6 11 17 25 34 .0027 (SM) 0.25 0.45 0.7 1 1.4
PMP 450 Planning Guide Site planning  pmp-0047 (June 2013)  2-13  Calculation of lateral force (US) The magnitude of the lateral force can be estimated from: Force (in pounds) = 0.0042Av2 Where:  Is:   A  surface area in square feet  v  wind speed in miles per hour The lateral force produced by a single PMP 450 unit at different wind speeds is shown in Table 16. Table 16  Lateral force - US Largest surface area (square feet) Lateral force (lb) at wind speed (miles per hour) 80 100 120 140 150 0.71 (AP) 19  30 43 58  67 0.29 (SM) 7.8 12 18 23 27  Capabilities of the PMP 450 Series The structure and mounting brackets of the AP are capable of withstanding wind speeds up to 190 kph (118 mph). Ensure that the structure to which the AP is fixed to is also capable of withstanding the prevalent wind speeds and loads.  The structure and mounting brackets of the SM are capable of withstanding wind speeds up to 190 kph (118 mph). Ensure that the structure to which the SM is fixed to is also capable of withstanding the prevalent wind speeds and loads.  Wind speed statistics Contact the national meteorological office for the country concerned to identify the likely wind speeds prevalent at the proposed location.  Use this data to estimate the total wind loading on the support structures. Sources of information:  US National Weather Service, http://www.nws.noaa.gov/  UK Meteorological Office, www.meto.gov.uk
Link planning Planning considerations  2-14  pmp-0047 (June 2013)  Link planning This section describes factors to be taken into account when planning links, such as range, obstacles, path loss and throughput. Range and obstacles Calculate the range of the link and identify any obstacles that may affect radio performance. Perform a survey to identify all the obstructions (such as trees or buildings) in the path and to assess the risk of interference. This information is necessary in order to achieve an accurate link feasibility assessment. The PMP 450 Series is designed to operate in Near-Line-of-Sight (nLOS), Non-Line-of-Sight (NLOS) and Line-of-Sight (LOS) environments. An NLOS environment is one in which there is no optical line-of-sight, that is, there are obstructions between the antennas.  See Figure 1  Line Of Sight Diagram. OFDM technology can often use multi-pathing to an advantage to overcome nLOS, especially in cases where the Fresnel zone is only partially blocked by buildings, “urban canyons”, or foliage. OFDM tends to help especially when obstacles are near the middle of the link, and less so when the obstacles are very near the SM or AP. However, attenuation through walls and trees is substantial for any use of the 5.8 GHz frequency band. Even with OFDM, these products should not be expected to penetrate walls or extensive trees and foliage. Table 17 Link budget details – PMP 450 link, 20 MHz Channel Bandwidth  Product Parameter Range Details 2x 4x 6x PMP 450   Modulation QPSK-MIMO-B 16QAM-MIMO-B 64QAM-MIMO-B 5.4/5.8-GHz Max. LOS Link Budget (no fade margin) with Integrated SM antenna 6.7 mi / 10.9 km 2.7 mi / 4.3 km 1 mi / 1.7 km with CLIP that adds 8 dB to SM Range 17 mi / 27.4 km 6.8 mi / 10.9 km 2.7 mi / 4.3 km with LENS that adds 5.5 dB to SM Range 12.7 mi / 20.5 km  5 mi / 8.1 km  2 mi / 3.2 km  with Reflector Dish that adds 14 dB to SM Range 34 mi / 54.7 km 13.5 mi / 21.7 km 5.3 mi / 8.6 km 5.4/5.8-GHz Max. nLOS Link Budget (additional 5 dB link loss) with Integrated SM antenna 3.8 mi / 6.1 km 1.5 mi / 2.4 km 0.6 mi / 0.9 km with CLIP that adds 8 dB to SM Range 9.6 mi / 15.4 km 3.8 mi / 6.1 km 1.5 mi / 2.4 km with LENS that adds 5.5 dB to SM Range 7.1 mi / 11.5 km 2.8 mi / 4.6 km 1.1 mi / 1.8 km
PMP 450 Planning Guide Link planning  pmp-0047 (June 2013)  2-15  Product Parameter Range Details 2x 4x 6x with Reflector Dish that adds 14 dB to SM Range 19.1 mi / 30.7 km 7.6 mi / 12.2 km 3 mi / 4.8 km 5.4/5.8-GHz Max. NLOS1 Link Budget (additional 15 dB link loss) with Integrated SM antenna 1.2 mi / 1.9 km 0.4 mi / 0.7 km 0.1 mi / 0.3 km with CLIP that adds 8 dB to SM Range 3 mi / 4.8 km 1.2 mi / 1.9 km 0.5 mi / 0.8 km with LENS that adds 5.5 dB to SM Range 2.2 mi / 3.6 km 0.9 mi / 1.4 km 0.3 mi / 0.5 km with Reflector Dish that adds 14 dB to SM Range 6 mi / 9.7 km 2.4 mi / 3.8 km 0.9 mi / 1.5 km 5.4/5.8-GHz Max. NLOS2 Link Budget (additional 25 dB link loss) with Integrated SM antenna 0.3 mi / 0.6 km 0.1 mi / 0.2 km 0.06 mi / 0.09 km with LENS that adds 8 dB to SM Range 1 mi / 1.6 km 0.4 mi / 0.6 km 0.2 mi / 0.3 km with LENS that adds 5.5 dB to SM Range 0.7 mi / 1.1 km 0.2 mi / 0.4 km 0.1 mi / 0.18 km with Reflector Dish that adds 14 dB to SM Range 1.9 mi / 3 km 0.7 mi / 1.2 km 0.3 mi / 0.4 km   Table 18 Link budget details – PMP 450 link, 10 MHz Channel Bandwidth  Product Parameter Range Details 2x 4x 6x PMP 450   Modulation QPSK-MIMO-B 16QAM-MIMO-B 64QAM-MIMO-B 5.4/5.8-GHz Max. LOS Link Budget (no fade margin) with Integrated SM antenna 9.5 mi / 15.4 km 3.8 mi / 6.1 km 1.5 mi / 2.4 km with CLIP that adds 8 dB to SM Range 24.1 mi / 38.8 km 9.6 mi / 15.4 km 3.8 mi / 6.1 km with LENS that adds 5.5 dB to SM Range 18 mi / 29 km 7.1 mi / 11.5 km 2.8 mi / 4.6 km with Reflector Dish that adds 14 dB to SM Range 40 mi / 64.3 km 19.1 mi / 30.7 km 7.6 mi / 12.2 km 5.4/5.8-GHz with Integrated SM antenna 5.3 mi / 8.6 km 2.1 mi / 3.4 km 0.8 mi / 1.3 km
Link planning Planning considerations  2-16  pmp-0047 (June 2013)  Product Parameter Range Details 2x 4x 6x Max. nLOS Link Budget (additional 5 dB link loss) with CLIP that adds 8 dB to SM Range 13.5 mi / 21.7 km 5.4 mi / 8.7 km 2.2 mi / 3.5 km with LENS that adds 5.5 dB to SM Range 10.1 mi / 16.3 km 4 mi / 6.5 km 1.6 mi / 2.5 km with Reflector Dish that adds 14 dB to SM Range 27 mi / 43.4 km 10.7 mi / 17.3 km 4.2 mi / 6.8 km 5.4/5.8-GHz Max. NLOS1 Link Budget (additional 15 dB link loss) with Integrated SM antenna 1.7 mi / 2.7 km 0.6 mi / 1 km 0.2 mi / 0.4 km with CLIP that adds 8 dB to SM Range 4.3 mi / 6.9 km 1.7 mi / 2.7 km 0.7 mi / 1.1 km with LENS that adds 5.5 dB to SM Range 3.2 mi / 5.1 km 1.2 mi / 2 km 0.5 mi / 0.8 km with Reflector Dish that adds 14 dB to SM Range 8.5 mi / 13.7 km 3.4 mi / 5.4 km 0.4 1.3 mi / 2.1 km 5.4/5.8-GHz Max. NLOS2 Link Budget (additional 25 dB link loss) with Integrated SM antenna 0.5 mi / 0.8 km 0.2 mi / 0.3 km 0.5 0.08 mi / 0.13 km with CLIP that adds 8 dB to SM Range 1.4 mi / 2.3 km 0.5 mi / 0.8 km 0.6 0.2 mi / 0.3 km with LENS that adds 5.5 dB to SM Range 1 mi / 1.6 km 0.4 mi / 0.6 km 0.7 0.1 mi / 0.2 km with Reflector Dish that adds 14 dB to SM Range 2.7 mi / 4.3 km 1 mi / 1.7 km 0.8 mi / 0.6 km   Table 19 Link budget details – PMP 450 link, 5MHz Channel Bandwidth   Product Parameter Range Details 2x 4x 6x PMP 450   Modulation QPSK-MIMO-B 16QAM-MIMO-B 64QAM-MIMO-B 5.8-GHz Max. LOS Link Budget with Integrated SM antenna    with CLIP that adds 8 dB to SM Range
PMP 450 Planning Guide Link planning  pmp-0047 (June 2013)  2-17  Product Parameter Range Details 2x 4x 6x (no fade margin) with LENS that adds 5.5 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range    5.8-GHz Max. nLOS Link Budget (additional 5 dB link loss) with Integrated SM antenna    with CLIP that adds 8 dB to SM Range    with LENS that adds 5.5 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range    5.8-GHz Max. NLOS1 Link Budget (additional 15 dB link loss) with Integrated SM antenna    with CLIP that adds 8 dB to SM Range    with LENS that adds 5.5 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range    5.8-GHz Max. NLOS2 Link Budget (additional 25 dB link loss) with Integrated SM antenna    with CLIP that adds 8 dB to SM Range    with LENS that adds 5.5 dB to SM Range    with Reflector Dish that adds 14 dB to SM Range
Link planning Planning considerations  2-18  pmp-0047 (June 2013)  Path loss considerations  Path loss is the amount of attenuation the radio signal undergoes between the two ends of the link. Calculating path loss The path loss is the sum of the attenuation of the path if there were no obstacles in the way (Free Space Path Loss), the attenuation caused by obstacles (Excess Path Loss) and a margin to allow for possible fading of the radio signal (Fade Margin). The following calculation needs to be performed to judge whether a particular link can be installed: capabilityseasonalfadeexcessspacefree LLLLL _ Where: Is: spacefreeL_ Free Space Path Loss (dB) excessL Excess Path Loss (dB) fadeL Fade Margin Required (dB) seasonalL Seasonal Fading (dB) capabilityL Equipment Capability (dB) Calculating maximum power level for connectorized AP units If a connectorized PMP 450 AP is to be installed in a country that imposes an EIRP limit in the selected band, calculate the highest setting of Maximum Power Level that will be permitted using this formula: Maximum Power Level (dBm) = Allowed EIRP (dBm) – Antenna Gain (dBi) + Cable Loss (dB) Where:  Is:   Maximum Power Level (dBm)  the highest permissible setting of the transmitter output power,  Allowed EIRP (dBm)  the EIRP limit allowed by the regulations,  Antenna Gain (dBi)  the gain of the chosen antenna,  Cable Loss (dB)  the loss of the RF cable connecting the AP to the antenna.  For more information on EIRP limits, see Compliance with radio regulations on page 4-15. .
PMP 450 Planning Guide Link planning  pmp-0047 (June 2013)  2-19  Understanding Attenuation An RF signal in space is attenuated by atmospheric and other effects as a function of the distance from the initial transmission point. The further a reception point is placed from the transmission point, the weaker is the received RF signal. Calculating Link Loss The link loss is the total attenuation of the wireless signal between two point-to-multipoint units. The link loss calculation is presented below: Link Loss (dB)   =  Transmit power of the remote wireless unit (dBm)  −  Tx Cable loss (dB) − Received power at the local unit (dBm) – Rx cable loss (dB) + Antenna gain at the remote unit (dBi) + Antenna gain at the local unit (dBi) Calculating Rx Signal Level The Rx sensitivity of each module is provided at http://www.cambiumnetworks.com. The determinants in Rx signal level are illustrated in Figure 11. Figure 11 Determinants in Rx signal level   Rx signal level is calculated as follows: Rx signal level  dB   =  Tx power  −  Tx cable loss  +  Tx antenna gain                                              −  free space path loss  +  Rx antenna gain  −  Rx cable loss  This Rx signal level calculation presumes that a clear line of sight is established between the transmitter and receiver and that no objects encroach in the Fresnel zone.
Analyzing the RF Environment Planning considerations  2-20  pmp-0047 (June 2013)  Calculating Fade Margin Free space path loss is a major determinant in Rx (received) signal level. Rx signal level, in turn, is a major factor in the system operating margin (fade margin), which is calculated as follows: system operating margin (fade margin) dB =Rx signal level dB  −  Rx sensitivity dB  Thus, fade margin is the difference between strength of the received signal and the strength that the receiver requires for maintaining a reliable link. A higher fade margin is characteristic of a more reliable link. Analyzing the RF Environment An essential element in RF network planning is the analysis of spectrum usage and the strength of the signals that occupy the spectrum you are planning to use. Regardless of how you measure and log or chart the results you find (through the Spectrum Analyzer in SM feature or by using a spectrum analyzer), you should do so:  at various times of day.  on various days of the week.  periodically into the future.  As new RF neighbors move in or consumer devices in your spectrum proliferate, this will keep you aware of the dynamic possibilities for interference with your network. Mapping RF Neighbor Frequencies These modules allow you to  use an SM or an AP that is temporarily transformed into an SM, as a spectrum analyzer.  view a graphical display that shows power level in RSSI and dBm at 5-MHz increments throughout the frequency band range, regardless of limited selections in the Custom Radio Frequency Scan Selection List parameter of the SM.  select an AP channel that minimizes interference from other RF equipment.   The following procedure causes the SM to drop any active RF link. If a link is dropped when the spectrum analysis begins, the link can be re-established when either a 15-minute interval has elapsed or the spectrum analyzer feature is disabled.
PMP 450 Planning Guide Analyzing the RF Environment  pmp-0047 (June 2013)  2-21  Analyzing the spectrum To use the built-in spectrum analyzer functionality of the SM (or AP that is temporarily configured as an SM for spectrum analysis via the AP’s GUI) proceed as follows: Procedure 3  Analyzing the spectrum 1 Predetermine a power source and interface that will work for the SM  in the area you want to analyze. 2 Take the SM, power source, and interface device to the area. 3 Access the Tools web page of the SM. RESULT: The Tools page opens to its Spectrum Analyzer tab. 4 Click Enable. RESULT: The feature is enabled. 5 Click Enable again. RESULT: The system measures RSSI and dBm for each frequency in the spectrum. 6 Travel to another location in the area. 7 Click Enable again. RESULT: The system provides a new measurement of RSSI and dBm for each frequency in the spectrum.  Spectrum analysis mode times out 15 minutes after the mode was invoked. 8 Repeat Steps 6 and 7 until the area has been adequately scanned and logged.  As with any other data that pertains to your business, a decision today to put the data into a retrievable database may grow in value to you over time.   Wherever you find the measured noise level is greater than the sensitivity of the radio that you plan to deploy, use the noise level (rather than the link budget) for your link feasibility calculations.
Analyzing the RF Environment Planning considerations  2-22  pmp-0047 (June 2013)  Anticipating Reflection of Radio Waves In the signal path, any object that is larger than the wavelength of the signal can reflect the signal. Such an object can even be the surface of the earth or of a river, bay, or lake. The wavelength of the signal is approximately  2 inches for 5.4-GHz and 5.8-GHz signals.  5 inches for 2.4-GHz signals. A reflected signal can arrive at the antenna of the receiver later than the non-reflected signal arrives. These two or more signals cause the condition known as multipath. Multipath may increase or decrease the signal level and so overall attenuation may be higher or lower than that caused by the link distance. This is problematic at the margin of the link budget, where the standard operating margin (fade margin) may be compromised. Noting Possible Obstructions in the Fresnel Zone The Fresnel (pronounced fre∙NEL) Zone is a three-dimensional volume around the line of sight of an antenna transmission. Objects that penetrate this area can cause the received strength of the transmitted signal to fade. Out-of-phase reflections and absorption of the signal result in signal cancellation. The foliage of trees and plants in the Fresnel Zone can cause signal loss. Seasonal density, moisture content of the foliage, and other factors such as wind may change the amount of loss. Plan to perform frequent and regular link tests if you must transmit though foliage.
PMP 450 Planning Guide Analyzing the RF Environment  pmp-0047 (June 2013)  2-23  Multiple OFDM Access Point Clusters When deploying multiple AP clusters in a dense area, consider aligning the clusters as shown below. However, this is only a recommendation. An installation may dictate a different pattern of channel assignments. Figure 12  Example layout of 16 Access Point sectors (ABCD), 90 degree sectors  An example for assignment of frequency channels is provided in the following table. See section Network migration planning on page 2-3 for more information on migrating to a PMP 450 network. Table 20  Example 5.8-GHz OFDM channel assignment by sector Symbol  Frequency A 5.740 GHz B 5.760 GHz C 5.780 GHz D 5.800 GHz
Analyzing the RF Environment Planning considerations  2-24  pmp-0047 (June 2013)  Figure 13  Example layout of 16 Access Point sectors (ABC), 60 degree sectors  An example for assignment of frequency channels and sector IDs is provided in the following table. See section Network migration planning on page 2-3 for more information on migrating to a PMP 450 network. Table 21  Example 5.8-GHz OFDM channel assignment by sector Symbol  Frequency A 5.740 GHz B 5.760 GHz C 5.780 GHz
PMP 450 Planning Guide Analyzing the RF Environment  pmp-0047 (June 2013)  2-25  Planning for co-location and using the OFDM Frame Calculator Tool The first step to avoid interference in wireless systems is to set all APs to receive timing from a synchronization source (Cluster Management Module, or Universal Global Positioning System). This ensures that the modules are in sync and start transmitting at the same time each frame. The second step to avoid interference is to configure parameters on all APs of the same frequency band in proximity such that they have compatible transmit/receive ratios (all stop transmitting each frame before any start receiving). This avoids the problem of one AP attempting to receive the signal from a distant SM while a nearby AP transmits, which could overpower that signal. The following parameters on the AP determine the transmit/receive ratio:  Max Range  Downlink Data percentage  (reserved) Control Slots  If OFDM (PMP 430, PMP 450, PTP 230) and FSK (PMP 1x0) APs of the same frequency band are in proximity, or if you want APs set to different parameters (differing in their Max Range values, for example), then you should use the Frame Calculator to identify compatible settings. The frame calculator is available on the Frame Calculator tab of the Tools web page. To use the Frame Calculator, type into the calculator various configurable parameter values for each proximal AP, and then record the resulting AP Receive Start value. Next vary the Downlink Data percentage in each calculation and iterate until the calculated  AP Receive Start for all collocated APs are within 300 bit times; if possible, within 150 bit times.  In Cambium Point-to-Multipoint systems, 10 bit times = 1 µs. The calculator does not use values in the module or populate its parameters. It is merely a convenience application that runs on a module. For this reason, you can use any FSK module (AP, SM, BHM, BHS) to perform FSK frame calculations for setting the parameters on an FSK AP and any OFDM module (AP, SM, BHM, BHS) to perform OFDM frame calculations for setting the parameters on an OFDM AP.  IMPORTANT! APs that have slightly mismatched transmit-to-receive ratios and low levels of data traffic may see little effect on throughput. A system that was not tuned for co-location may work fine at low traffic levels, but encounter problems at higher traffic levels. The conservative practice is to tune for co-location before traffic ultimately increases. This prevents problems that occur as sectors are built.
Analyzing the RF Environment Planning considerations  2-26  pmp-0047 (June 2013)  Figure 14  OFDM Frame Calculator tab  In the Frame Calculator tab, you may set the following parameters. Table 22  OFDM Frame Calculator tab attributes Attribute Meaning Link Mode For AP to SM frame calculations, select Multipoint Link Platform Type AP/BHM Use the drop-down list to select the hardware series (board type) of the AP. Platform Type SM/BHS Use the drop-down list to select the hardware series (board type) of the SM. Channel Bandwidth Set this to the channel bandwidth used in the AP. Cyclic Prefix Set this to the cyclic prefix used in the AP. Max Range Set to the same value as the Max Range parameter is set in the AP(s). Air Delay This field should be left at the default of 0 ns.
PMP 450 Planning Guide Analyzing the RF Environment  pmp-0047 (June 2013)  2-27  Attribute Meaning Downlink Data Initially set this parameter to the same value that the AP has for its Downlink Data parameter (percentage). Then, as you use the Frame Calculator tool in Procedure 4, you will vary the value in this parameter to find the proper value to write into the Downlink Data parameter of all APs in the cluster.  PMP 450 Series APs offer a range of 15% to 85%, and default to 75%. The value that you set in this parameter has the following interaction with the value of the Max Range parameter (above): The default Max Range value is 5 miles and, at that distance, the maximum Downlink Data value (85% in PMP450) is functional. Control Slots Set this parameter to the value of the Control Slot parameter is set in the APs.  The Calculated Frame Results display several items of interest: Table 23  OFDM Calculated Frame Results attributes Attribute Meaning Modulation The type of radio modulation used in the calculation (OFDM for PMP 450) Total Frame Bits The total number of bits used in the calculated frames Data Slots (Down/Up) This field is based on the Downlink Data setting.  For example, a result within the typical range for a Downlink Data setting of 75% is 61/21, meaning 61 data slots down and 21 data slots up. Round Trip Air Delay (MaxRange) This is the roundtrip air delay in bit times for the Max Range value set in the calculator Approximate distance (MaxRange) The Max Range value used for frame calculation AP Transmit End In bit times, this is the frame position at which the AP ceases transmission. AP Receive Start In bit times, this is the frame position at which the AP is ready to receive transmission from the SM. AP Receive End In bit times, this is the frame position at which the AP will cease receiving transmission from the SM. SM Receive End In bit times, this is the frame position at which the SM will cease receiving transmission from the AP. SM Transmit Start In bit times, this is the frame position at which the SM will begin transmission.
Selecting Sites for Network Elements Planning considerations  2-28  pmp-0047 (June 2013)  To use the Frame Calculator to ensure that all APs are configured to transmit and receive at the same time, follow the procedure below: Procedure 4  Using the Frame Calculator 1 Populate the OFDM Frame Calculator parameters with appropriate values as described above. 2 Click the Calculate button. 3 Scroll down the tab to the Calculated Frame Results section 4 Record the value of the AP Receive Start field 5 Enter a parameter set from another AP in the system – for example, an AP in the same cluster that has a higher Max Range value configured. 6 Click the Calculate button. 7 Scroll down the tab to the Calculated Frame Results section 8 If the recorded values of the AP Receive Start fields are within 150 bit times of each other, skip to step 10. 9 If the recorded values of the AP Receive Start fields are not within 150 bit times of each other, modify the Downlink Data parameter until the calculated results for AP Receive Start are within 300 bit time of each other, if possible, 150 bit time. 10 Access the Radio tab in the Configuration web page of each AP in the cluster and change its Downlink Data parameter (percentage) to the last value that was used in the Frame Calculator.  Selecting Sites for Network Elements The APs must be positioned  with hardware that the wind and ambient vibrations cannot flex or move.  where a tower or rooftop is available or can be erected.  where a grounding system is available.  with lightning arrestors to transport lightning strikes away from equipment.  at a proper height: o higher than the tallest points of objects immediately around them (such as trees, buildings, and tower legs).  o at least 2 feet (0.6 meters) below the tallest point on the tower, pole, or roof (for lightning protection).  away from high-RF energy sites (such as AM or FM stations, high-powered antennas, and live AM radio towers).  in line-of-sight paths o to the SMs. o that will not be obstructed by trees as they grow or structures that are later built.
PMP 450 Planning Guide Selecting Sites for Network Elements  pmp-0047 (June 2013)  2-29   Visual line of sight does not guarantee radio line of sight.  Surveying Sites Factors to survey at potential sites include  what pre-existing wireless equipment exists at the site. (Perform spectrum analysis.)  whether available mounting positions exist near the lowest elevation that satisfies line of site, coverage, and other link criteria.  whether you will always have the right to decide who climbs the tower to install and maintain your equipment, and whether that person or company can climb at any hour of any day.  whether you will have collaborative rights and veto power to prevent interference to your equipment from wireless equipment that is installed at the site in the future.  whether a pre-existing grounding system (path to Protective Earth  ) exists, and what is required to establish a path to it.  who is permitted to run any indoor lengths of cable. Clearing the Radio Horizon Because the surface of the earth is curved, higher module elevations are required for greater link distances. This effect can be critical to link connectivity in link spans that are greater than 8 miles (12 km). To use metric units to find the minimum height required to reach the radio horizon use the following equation: Radio horizon distance (km) = 4.12 (SQRT(h1) + SQRT(h2)) Where:  Is:   h1  height of the AP  h2  height of the SM  To use English standard units to find the angle of elevation, use the following formula: Radio horizon distance (km) = 1.42 (SQRT(h1) + SQRT(h2)) Where:  Is:   h1  height of the AP  h2  height of the SM
Selecting Sites for Network Elements Planning considerations  2-30  pmp-0047 (June 2013)  Calculating the Aim Angles The proper angle of tilt can be calculated as a factor of both the difference in elevation and the distance that the link spans. Even in this case, a plumb line and a protractor can be helpful to ensure the proper tilt. This tilt is typically minimal. The number of degrees to offset (from vertical) the mounting hardware leg of the support tube is equal to the angle of elevation from the lower module to the higher module (<B in the example provided in Figure 15). Figure 15  Variables for calculating angle of elevation (and depression)  Where:  Is:   b  angle of elevation  B  vertical difference in elevation  A  horizontal distance between modules  Calculating the Angle of Elevation To use metric units to find the angle of elevation, use the following formula:  Where:  Is:   B  expressed in meters  A  expressed in kilometers  To use English standard units to find the angle of elevation, use the following formula:  Where:  Is:   B  expressed in feet  A  expressed in miles  The angle of depression from the higher module is identical to the angle of elevation from the lower module. tan b  =    B1000Atan b  =    B5280A
PMP 450 Planning Guide Diagramming Network Layouts  pmp-0047 (June 2013)  2-31  Diagramming Network Layouts Avoiding Self Interference The following section includes information maximizing tower performance by minimizing self-interference.   Physical Proximity Two AP clusters co-located on the same tower require a CMM. The CMM properly synchronizes the transmit start times of all modules to prevent interference and desensing of the modules. At closer distances without GPS synchronization, the frame structures cause self-interference.  Non-synchronized deployments are highly discouraged. Furthermore, non-synchronized APs on the same tower require that the effects of their differing receive start times be mitigated by either  100 vertical feet (30 meters) or more and as much spectral separation as possible within the same frequency band range  the use of the frame calculator to tune the Downlink Data parameter in each, so that the receive start time in each is the same  The constraints for collocated modules in the same frequency band range are to avoid self-interference that would occur between them. Specifically, unless the uplink and downlink data percentages match, intervals exist when one is transmitting while the other is receiving, such that the receiving module cannot receive the signal from the far end.  The interference is less a problem during low throughput periods and intolerable during high. Typically, during low throughput periods, sufficient time exists for the far end to retransmit packets lost because of interference from the collocated module. Spectrum Analysis You can use an SM as a spectrum analyzer. See Mapping RF Neighbor Frequencies on Page 2-20. Through a toggle of the Device Type parameter, you can temporarily transform an AP into an SM to use it as a spectrum analyzer.  SM Automatic Transmit Power Control The PMP 450 AP automatically sets the transmitter output power in its SMs through a feature named Auto-TPC (Transmit Power Control). The conceptual reason for this feature is OFDM reception in the AP is sensitive to large differences in power levels received from its SMs, and by limiting power levels of close-in SMs the overall RF noise floor is lowered.
Diagramming Network Layouts Planning considerations  2-32  pmp-0047 (June 2013)  Avoiding Other Interference Where signal strength cannot dominate noise levels, the network experiences  packet errors and retransmissions.  lower throughput (because bandwidth is consumed by retransmissions) and high latency (due to resends).  Regular spectrum analysis is critical to RF planning.  The integrated spectrum analyzer can be very useful as a tool for troubleshooting and RF planning, but is not intended to replicate the accuracy and programmability of a high-end spectrum analyzer, which you may sometime need for other purposes.   When you enable the Spectrum Analyzer on a module, it enters a scan mode and drops any RF connection it may have had. Scanning mode ends when either you click Disable on the Spectrum Analyzer page, or it times out after 15 minutes and returns to operational mode. For this reason: 1. do not enable the spectrum analyzer on a module you are connected to via RF. The connection will drop for 15 minutes, and when the connection is re-established no readings will be displayed. 2. be advised that, if you enable the spectrum analyzer by Ethernet connection, the RF connection to that module drops.  You can use any module to see the frequency and power level of any detectable signal that is within, just above, or just below the frequency band range of the module.   Vary the days and times when you analyze the spectrum in an area.  The RF environment can change throughout the day or throughout the week.
PMP 450 Planning Guide Grounding and lightning protection  pmp-0047 (June 2013)  2-33  Grounding and lightning protection This section describes the grounding and lightning protection requirements of a PMP 450 installation.  Electro-magnetic discharge (lightning) damage is not covered under warranty. The recommendations in this guide, when followed correctly, give the user the best protection from the harmful effects of EMD. However 100% protection is neither implied nor possible. The need for power surge protection Structures, equipment and people must be protected against power surges (typically caused by lightning) by conducting the surge current to ground via a separate preferential solid path. The actual degree of protection required depends on local conditions and applicable local regulations. Cambium recommends that PMP 450 installation is contracted to a professional installer. Standards Full details of lightning protection methods and requirements can be found in the international standards IEC 61024-1 and IEC 61312-1, the U.S. National Electric Code ANSI/NFPA No. 70-1984 or section 54 of the Canadian Electric Code.
Grounding and lightning protection Planning considerations  2-34  pmp-0047 (June 2013)  Lightning protection zones The ‘rolling sphere method’ (Figure 16) is used to determine where it is safe to mount equipment.  An imaginary sphere, typically 50 meters in radius, is rolled over the structure. Where the sphere rests against the ground and a strike termination device (such as a finial or ground bar), all the space under the sphere is considered to be in the zone of protection (Zone B). Similarly, where the sphere rests on two finials, the space under the sphere is considered to be in the zone of protection. Figure 16  Rolling sphere method to determine the lightning protection zones EquipmentZone BZone AZone A50 mZone B  Assess locations on masts, towers and buildings to determine if the location is in Zone A or Zone B:  Zone A: In this zone a direct lightning strike is possible. Do not mount equipment in this zone.  Zone B: In this zone, direct EMD (lightning) effects are still possible, but mounting in this zone significantly reduces the possibility of a direct strike. Mount equipment in this zone.  Never mount equipment in Zone A. Mounting in Zone A may put equipment, structures and life at risk.
PMP 450 Planning Guide Grounding and lightning protection  pmp-0047 (June 2013)  2-35  General protection requirements To adequately protect a PMP 450 installation, both ground bonding and transient voltage surge suppression are required. Basic requirements The following basic protection requirements must be implemented:  The equipment must be in ‘Zone B’ (see Lightning protection zones on page 2-34).  The AP must be grounded to the supporting structure.  A surge suppression unit (600SS) must be installed close to the SM.  The distance between the SM and 600SS should be kept to a minimum.  The drop cable length between the SM and 600SS must be less than 600 mm.  An surge suppression unit (200SS) must be installed within 600 mm (24 in) of the point at which the power cable enters the building or equipment room.  The drop cable must be grounded at the building entry point.  The drop cable must not be laid alongside a lightning air terminal.  All grounding cables must be a minimum size of 10 mm2 csa  (8AWG), preferably 16 mm2 csa (6AWG), or 25 mm2 csa (4AWG). Grounding cable requirements When routing, fastening and connecting grounding cables, the following requirements must be implemented:  Grounding conductors must be run as short, straight, and smoothly as possible, with the fewest possible number of bends and curves.  Grounding cables must not be installed with drip loops.  All bends must have a minimum radius of 203 mm (8 in) and a minimum angle of 90° (Figure 17). A diagonal run is preferable to a bend, even though it does not follow the contour or run parallel to the supporting structure.  All bends, curves and connections must be routed towards the grounding electrode system, ground rod, or ground bar.  Grounding conductors must be securely fastened.  Braided grounding conductors must not be used.  Approved bonding techniques must be used for the connection of dissimilar metals.
Grounding and lightning protection Planning considerations  2-36  pmp-0047 (June 2013)  Figure 17  Grounding cable minimum bend radius and angle Radius not lessthan 203 mm (8 in)Angle not lessthan 90°
PMP 450 Planning Guide Grounding and lightning protection  pmp-0047 (June 2013)  2-37  Protection requirements for a mast or tower installation If the AP or SM is to be mounted on a metal tower or mast, then in addition to the general protection requirements (above), the following requirements must be observed:  The equipment must be lower than the top of the tower or its lightning air terminal.  The metal tower or mast must be correctly grounded.  A grounding kit must be installed at the first point of contact between the drop cable and the tower, near the top.  A grounding kit must be installed at the bottom of the tower, near the vertical to horizontal transition point. This grounding kit must be bonded to the tower or tower ground bus bar (TGB), if installed. Schematic examples of mast or tower installations are shown in Figure 18. Figure 18  Grounding and lightning protection on mast or tower 600SSExternal ground barGround ringOutdoor CAT5e cable: shielded with copper-plated steelPower supplyEquipment buildingNetwork switchAPGround CableTower/building ground systemCat5e cable
Grounding and lightning protection Planning considerations  2-38  pmp-0047 (June 2013)  Protection requirements for a wall installation If the SM is to be mounted on the wall of a building, then in addition to the general protection requirements (above), the following requirements must be observed:  The equipment must be lower than the top of the building or its lightning air terminal.  The building must be correctly grounded. Schematic examples of wall installations are shown in Figure 19.  Figure 19  Grounding and lightning protection on wall External ground barGround cableGround ringOutdoor CAT5e cable: shielded with copper-plated steelPower SupplyEquipment buildingNetwork switchBuilding ground systemSM600SSCat5e cable
PMP 450 Planning Guide Grounding and lightning protection  pmp-0047 (June 2013)  2-39  Protection requirements on a high rise building If the AP is to be mounted on a high rise building, it is likely that cable entry is at roof level (Figure 20) and the equipment room is several floors below (Figure 21). The following additional requirements must be observed:  The AP must be below the lightning terminals and finials.  A grounding conductor must be installed around the roof perimeter, to form the main roof perimeter lightning protection ring.  Air terminals are typically installed along the length of the main roof perimeter lightning protection ring typically every 6.1m (20ft).  The main roof perimeter lightning protection ring must contain at least two down conductors connected to the grounding electrode system. The down conductors should be physically separated from one another, as far as practical.  Figure 20  Grounding and lightning protection on building Air terminal (finial)Tower grounding conductorBuilding ground ring AC serviceAPTo equipment areaCAT5e cable: outdoor, shielded with copper-plated steelGround cableBuilding ground system600SS
Grounding and lightning protection Planning considerations  2-40  pmp-0047 (June 2013)  Protection inside a high rise building The following protection requirements must be observed inside multi-story or high rise buildings (Figure 21):  The drop cable shield must be bonded to the building grounding system at the entry point to the building.  The drop cable shield must be bonded to the building grounding system at the entry point to the equipment area.  Figure 21  Grounding and lightning protection inside high building Equipment area within a larger buildingTo building ground ringCAT5e cable: outdoor shielded with copper-plated steelCAT5e cableAPNetwork switchGround cableBuilding ground system600SSPower Supply
PMP 450 Planning Guide Configuration options for TDD synchronization  pmp-0047 (June 2013)  2-41  Configuration options for TDD synchronization The PMP 450 system uses Time Division Duplexing (TDD) - one channel alternately transmits and receives - rather than using one channel for transmitting and a second channel for receiving. To accomplish TDD, the AP must provide sync to its SMs – it must keep them in sync. Furthermore, collocated APs must be synced together - an unsynchronized AP that transmits during the receive cycle of a collocated AP can prevent that second AP from being able to decode the signals from its SMs. In addition, across a geographical area, APs that can “hear” each other benefit from using a common sync to further reduce self-interference within the network.  The configuration options available for synchronization on the PMP 450 Access Point are:  Generate Sync Signal:  This option may be used when the AP is not receiving GPS synchronization pulses from either a CMM or UGPS module, and there are no other APs active within the link range.  Using this option will not synchronize transmission of APs that can “hear” each other, it will only generate a sync signal for the local AP and its associated SMs.  See Advantage of GPS synchronization on page 2-42.  Sync to Received Signal (Timing Port / UGPS):  This option may be used to set the AP to receive GPS synchronization pulses from a UGPS (Universal Global Positioning System) module or an AP in the cluster via the RJ11 sync port.  Sync to Received Signal (Power Port):  This option may be used to set the AP to receive GPS synchronization pulses from a connected CMM via the RJ45 port. GPS synchronization The Navigation Satellite Timing and Ranging (NAVSTAR) Global Positioning System (GPS) uses 24 satellites to relay information for precise derivation of position and time.  The cluster management module (CMM) contains a Cambium GPS Receiver. The CMM is a critical element in the operation of the system. At one AP cluster site or throughout an entire wireless system, the CMM provides a GPS timing pulse to each module, synchronizing the network transmission cycles. The Oncore GPS Receiver tracks eight or more NAVSTAR satellites. The CMM uses the signal from at least four of these satellites to generate a one-second interval clock that has a rise time of 100 nsec. This clock directly synchronizes APs and which, in turn, synchronize the SMs in the network. The Oncore GPS Receiver also provides  the latitude and longitude of the GPS antenna (collocated with the CMM)  the number of satellites that are being tracked  the number of satellites that are available  the date  the time in Universal Coordinated Time (UCT)  the altitude of the GPS antenna  other information that can be used to diagnose network problems.
Configuration options for TDD synchronization Planning considerations  2-42  pmp-0047 (June 2013)  Alternative to GPS synchronization A link can operate without GPS sync, but cannot operate without sync. The alternative to GPS sync is to configure the AP in the link to generate a sync pulse to pass to the SM. Depending on the RF environment in which the link operates, this latter alternative may or may not be plausible. For example, in Figure 22, AP4  is not synchronized with any of the other APs.  is transmitting nearby the other APs while they are expecting to receive SM transmissions from a maximum distance.  Figure 22  One unsynchronized AP in cluster resulting in self-interference    The result is self-interference. In this scenario, the self-interference can be avoided only by synchronizing the TDD transmit cycles of all APs that operate in the same frequency band. An AP that is isolated by at least 5 miles (8 km) from any other equipment can generate and pass sync pulse without GPS timing and not risk that interference will result from the generated sync. In any other type of link, sync should be derived from GPS timing. Advantage of GPS synchronization Although the embedded timing generation capability of the AP keeps a precise clock (configuration parameter Sync Source set to Generate Sync Signal), no trigger exists to start the clock at the same moment in each AP of a cluster. So, the individual AP can synchronize communications between itself and registered SMs, but cannot synchronize itself with other modules, except by GPS timing (shown in Figure 23). Time
PMP 450 Planning Guide Configuration options for TDD synchronization  pmp-0047 (June 2013)  2-43  Figure 23  GPS timing throughout the network   Mounting the GPS receiver (CMM or UGPS) module on the equipment building If mounting the GPS receiver on the equipment building, select a position on the wall that meets the following requirements:  It must be below the roof height of the equipment building or below the height of any roof-mounted equipment (such as air conditioning plant).  It must be below the lightning air terminals.  It must not project more than 600mm (24 inches) from the wall of the building. If these requirements cannot all be met, then the module must be mounted on a metal tower or mast. Mounting the GPS receiver (CMM or UGPS) module on a metal tower or mast If mounting the GPS receiver module on a metal tower or mast, select a position that meets the following requirements:  It must not be mounted any higher than is necessary to receive an adequate signal from four GPS satellites.  It must be protected by a nearby lightning air terminal that projects farther out from the tower than the GPS receiver module.  It must meet all the requirements stated in Protection requirements for a mast or tower installation on page 2-37.  Time
Data network planning Planning considerations  2-44  pmp-0047 (June 2013)  Data network planning This section describes factors to be considered when planning PMP 450 data networks. Understanding addresses A basic understanding of Internet Protocol (IP) address and subnet mask concepts is required for engineering your IP network. IP address The IP address is a 32-bit binary number that has four parts (octets). This set of four octets has two segments, depending on the class of IP address. The first segment identifies the network. The second identifies the hosts or devices on the network. The subnet mask marks a boundary between these two sub-addresses.  Dynamic or static addressing For any computer to communicate with a module, the computer must be configured to either  use DHCP (Dynamic Host Configuration Protocol). In this case, when not connected to the network, the computer derives an IP address on the 169.254 network within two minutes.  have an assigned static IP address (for example, 169.254.1.5) on the 169.254 network.   If an IP address that is set in the module is not the 169.254.x.x network address, then the network operator must assign the computer a static IP address in the same subnet.  When a DHCP server is not found To operate on a network, a computer requires an IP address, a subnet mask, and possibly a gateway address. Either a DHCP server automatically assigns this configuration information to a computer on a network or an operator must input these items.  When a computer is brought on line and a DHCP server is not accessible (such as when the server is down or the computer is not plugged into the network), Microsoft and Apple operating systems default to an IP address of 169.254.x.x and a subnet mask of 255.255.0.0 (169.254/16, where /16 indicates that the first 16 bits of the address range are identical among all members of the subnet).
PMP 450 Planning Guide Data network planning  pmp-0047 (June 2013)  2-45  DNS Client The DNS Client is used to resolve names of management servers within the operator’s management domain (see Figure 24).  This feature allows hostname configuration for NTP servers, Authorization Servers, DHCP relay servers, and SNMP trap servers. Operators may choose to either enter in the FQDN (Fully Qualified Domain Name) for the host name or to manually enter the IP addresses of the servers.   Figure 24  Cambium network management domain  Network Address Translation (NAT) NAT, DHCP Server, DHCP Client, and DMZ in SM The system provides NAT (network address translation) for SMs in the following combinations of NAT and DHCP (Dynamic Host Configuration Protocol):  NAT Disabled  NAT with DHCP Client (DHCP selected as the Connection Type of the WAN interface) and DHCP Server  NAT with DHCP Client(DHCP selected as the Connection Type of the WAN interface)  NAT with DHCP Server  NAT without DHCP NAT NAT isolates devices connected to the Ethernet/wired side of an SM from being seen directly from the wireless side of the SM. With NAT enabled, the SM has an IP address for transport traffic (separate from its address for management), terminates transport traffic, and allows you to assign a range of IP addresses to devices that are connected to the Ethernet/wired side of the SM.
Data network planning Planning considerations  2-46  pmp-0047 (June 2013)  In the Cambium system, NAT supports many protocols, including HTTP, ICMP (Internet Control Message Protocols), and FTP (File Transfer Protocol). For virtual private network (VPN) implementation, L2TP over IPSec (Level 2 Tunneling Protocol over IP Security) and PPTP (Point to Point Tunneling Protocol) are supported.   When NAT is enabled, a reduction in throughput is introduced at the SM (due to processing overhead).  DHCP DHCP enables a device to be assigned a new IP address and TCP/IP parameters, including a default gateway, whenever the device reboots. Thus DHCP reduces configuration time, conserves IP addresses, and allows modules to be moved to a different network within the Cambium system. In conjunction with the NAT features, each SM provides  a DHCP server that assigns IP addresses to computers connected to the SM by Ethernet protocol.  a DHCP client that receives an IP address for the SM from a network DHCP server. DMZ In conjunction with the NAT features, a DMZ (demilitarized zone) allows the assignment of one IP address behind the SM for a device to logically exist outside the firewall and receive network traffic. The first three octets of this IP address must be identical to the first three octets of the NAT private IP address. Developing an IP addressing scheme Network elements are accessed through IP Version 4 (IPv4) addressing.  A proper IP addressing method is critical to the operation and security of a network. Each module requires an IP address on the network. This IP address is for only management purposes. For security, you should either  assign an unroutable IP address.  assign a routable IP address only if a firewall is present to protect the module.   You will assign IP addresses to computers and network components by either static or dynamic IP addressing. You will also assign the appropriate subnet mask and network gateway to each module.  Address Resolution Protocol As previously stated, the MAC address identifies a module in  communications between modules.  the data that modules store about each other.  The IP address is essential for data delivery through a router interface. Address Resolution Protocol (ARP) correlates MAC addresses to IP addresses.
PMP 450 Planning Guide Data network planning  pmp-0047 (June 2013)  2-47  For communications to outside the network segment, ARP reads the network gateway address of the router and translates it into the MAC address of the router. Then the communication is sent to MAC address (physical network interface card) of the router. For each router between the sending module and the destination, this sequence applies. The ARP correlation is stored until the ARP cache times out. Allocating subnets The subnet mask is a 32-bit binary number that filters the IP address. Where a subnet mask contains a bit set to 1, the corresponding bit in the IP address is part of the network address.    Example IP address and subnet mask In Figure 25 Example of IP address in Class B subnet the first 16 bits of the 32-bit IP address identify the network: Figure 25 Example of IP address in Class B subnet  Octet 1 Octet 2 Octet 3 Octet 4 IP address 169.254.1.1 10101001 11111110 00000001 00000001 Subnet mask 255.255.0.0 11111111 11111111 00000000 00000000  In this example, the network address is 169.254, and 216 (65,536) hosts are addressable.  Selecting non-routable IP addresses The factory default assignments for network elements are  unique MAC address  IP address of 169.254.1.1  subnet mask of 255.255.0.0  network gateway address of 169.254.0.0  For each radio and CMMmicro and CMM4, assign an IP address that is both consistent with the IP addressing plan for your network and cannot be accessed from the Internet. IP addresses within the following ranges are not routable from the Internet, regardless of whether a firewall is configured:  10.0.0.0 – 10.255.255.255  172.16.0.0 – 172.31.255.255  192.168.0.0 – 192.168.255.255  You can also assign a subnet mask and network gateway for each CMMmicro and CMM4.
Data network planning Planning considerations  2-48  pmp-0047 (June 2013)  Translation bridging Optionally, you can configure the AP to change the source MAC address in every packet it receives from its SMs to the MAC address of the SM that bridged the packet, before forwarding the packet toward the public network. If you do, then  not more than 10 IP devices at any time are valid to send data to the AP from behind the SM.  the AP populates the Translation Table tab of its Statistics web page, displaying the MAC address and IP address of all the valid connected devices.  each entry in the Translation Table is associated with the number of minutes that have elapsed since the last packet transfer between the connected device and the SM.  if 10 are connected, and another attempts to connect  o and no Translation Table entry is older than 255 minutes, the attempt is ignored. o and an entry is older than 255 minutes, the oldest entry is removed and the attempt is successful.  the Send Untranslated ARP parameter in the General tab of the Configuration page can be o disabled, so that the AP will overwrite the MAC address in Address Resolution Protocol (ARP) packets before forwarding them. o enabled, so that the AP will forward ARP packets regardless of whether it has overwritten the MAC address.  This is the Translation Bridging feature, which you can enable in the General tab of the Configuration web page in the AP. When this feature is disabled, the setting of the Send Untranslated ARP parameter has no effect, because all packets are forwarded untranslated (with the source MAC address intact).  See Address Resolution Protocol on Page 2-46. Engineering VLANs The radios support VLAN functionality as defined in the 802.1Q (Virtual LANs) specification, except for the following aspects of that specification:  the following protocols: o Generic Attribute Registration Protocol (GARP) GARV o Spanning Tree Protocol (STP) o Multiple Spanning Tree Protocol (MSTP) o GARP Multicast Registration Protocol (GMRP)  embedded source routing (ERIF) in the 802.1Q header  multicast pruning  flooding unknown unicast frames in the downlink    As an additional exception, the AP does not flood downward the unknown unicast frames to the SM. A VLAN configuration in Layer 2 establishes a logical group within the network. Each computer in the VLAN, regardless of initial or eventual physical location, has access to the same data. For the network operator, this provides flexibility in network segmentation, simpler management, and enhanced security.
PMP 450 Planning Guide Data network planning  pmp-0047 (June 2013)  2-49  Special case VLAN numbers This system handles special case VLAN numbers according to IEEE specifications: Table 24  Special case VLAN IDs VLAN Number Purpose Usage Constraint 0  These packets have 802.1p priority, but are otherwise handled as untagged. Should not be used as a management VLAN. 1 Although not noted as special case by IEEE specifications, these packets identify traffic that was untagged upon ingress into the SM and should remain untagged upon egress. This policy is hard-coded in the AP. Should not be used for system VLAN traffic. 4095 This VLAN is reserved for internal use. Should not be used at all.  SM membership in VLANs With the supported VLAN functionality, the radios determine bridge forwarding on the basis of not only the destination MAC address, but also the VLAN ID of the destination. This provides flexibility in how SMs are used:  Each SM can be a member in its own VLAN.  Each SM can be in its own broadcast domain, such that only the radios that are members of the VLAN can see broadcast and multicast traffic to and from the SM.  The network operator can define a work group of SMs, regardless of the AP(s) to which they register.  PMP modules provide the VLAN frame filters that are described in Table 25. Table 25  VLAN filters in point-to-multipoint modules Where VLAN is active, if this parameter value is selected … then a frame is discarded if… because of this VLAN filter in the software: entering the bridge/  NAT switch through… Ethernet… TCP/IP… any combination of VLAN parameter settings with a VID not in the membership table  Ingress any combination of VLAN parameter settings  with a VID not in the membership table Local Ingress Allow Frame Types: Tagged Frames Only with no 802.1Q tag  Only Tagged Allow Frame Types: Untagged Frames Only with an 802.1Q tag, regardless of VID  Only Untagged
Data network planning Planning considerations  2-50  pmp-0047 (June 2013)  Local SM Management: Disable in the SM, or All Local SM Management: Disable in the AP with an 802.1Q tag and a VID in the membership table  Local SM Management  leaving the bridge/ NAT switch through…   Ethernet… TCP/IP…  any combination of VLAN parameter settings with a VID not in the membership table  Egress any combination of VLAN parameter settings  with a VID not in the membership table Local Egress  Priority on VLANs (802.1p) The radios can prioritize traffic based on the eight priorities described in the IEEE 802.1p specification. When the high-priority channel is enabled on an SM, regardless of whether VLAN is enabled on the AP for the sector, packets received with a priority of 4 through 7 in the 802.1p field are forwarded onto the high-priority channel. Operators may configure priority precedence as 802.1p Then Diffserv (Default) or Diffserv Then 802.1p.  Since these priority precedence configurations are independent between the AP and SM, this setting must be configured on both the AP and the SM to ensure that the precedence is adhered to by both sides of the link.   VLAN settings can also cause the module to convert received non-VLAN packets into VLAN packets. In this case, the 802.1p priority in packets leaving the module is set to the priority established by the DiffServ configuration. If you enable VLAN, immediately monitor traffic to ensure that the results are as desired. For example, high-priority traffic may block low-priority. Q-in-Q DVLAN (Double-VLAN) Tagging (802.1ad) PMP modules can be configured with 802.1ad Q-in-Q DVLAN (Double-VLAN) tagging which is a way for an operator to put an 802.1Q VLAN inside of an 802.1ad VLAN.  A nested VLAN, which is the original 802.1Q tag and a new second 802.1ad tag, allows for bridging of VLAN traffic across a network and segregates the broadcast domains of 802.1Q VLANs.  Q-in-Q can be used with PPPoE and/or NAT. The 802.1ad standard defines the S-VLAN as the Service Provider VLAN and the C-VLAN as the customer VLAN.  The radio software does 2 layer Q-in-Q whereby the C-VLAN is the 802.1Q tag and the S-VLAN is the second layer Q tag as shown in Table 26. Table 26  Q-in-Q Ethernet frame Ethernet Header S-VLAN EthType 0x88a8 C-VLAN EthType 0x8100 IP Data EthType 0x0800
PMP 450 Planning Guide Data network planning  pmp-0047 (June 2013)  2-51  The 802.1ad S-VLAN is the outer VLAN that is configurable on the Configuration => VLAN web page of the AP.  The Q-in-Q EtherType parameter is configured with a default EtherType of 0x88a8 in addition to four alternate EtherTypes that can be configured to aid in interoperability with existing networks that use a different EtherType than the default. The C-VLAN is the inner VLAN tag, which is the same as 802.1Q. As a top level concept, this operates on the outermost tag at any given time, either “pushing” a tag on or “popping” a tag off. This means packets will at most transition from an 802.1Q frame to an 801.ad frame (with a tag “pushed” on) or an untagged 802.1 frame (with the tag “popped” off. Similarly, for an 802.1ad frame, this can only transition from an 802.1ad frame to an 802.1Q frame (with the tag “popped” off) since the radio software only supports 2 levels of tags.
Security planning Planning considerations  2-52  pmp-0047 (June 2013)  Security planning This section describes how to plan for PMP 450 networks to operate in secure mode. Isolating APs from the Internet Ensure that the IP addresses of the APs in your network  are not routable over the Internet.  do not share the subnet of the IP address of your user.  RFC 1918, Address Allocation for Private Subnets, reserves for private IP networks three blocks of IP addresses that are not routable over the Internet:  /8 subnets have one reserved network, 10.0.0.0 to 10.255.255.255.  /16 subnets have 16 reserved networks, 172.16.0.0 to 172.31.255.255.  /24 subnets have 256 reserved networks, 192.168.0.0 to 192.168.255.255. Managing module access by passwords Adding a user for access to a module From the factory, each module has a preconfigured administrator-level account in the name root, which initially requires no associated password. This is the same root account that you may have used for access to the module by ftp. When you upgrade a module  an account is created in the name admin.  both admin and root inherit the password that was previously used for access to the module: o the Full Access password, if one was set. o the Display-Only Access password, if one was set and no Full Access password was set.   If you use Wireless Manager, do not delete the root account from any module. If you use an NMS that communicates with modules through SNMP, do not delete the root account from any module unless you first can confirm that the NMS does not rely on the root account for access to the modules.  Each module supports four or fewer user accounts, regardless of account levels. The available levels are   ADMINISTRATOR, who has full read and write permissions. This is the level of the root and admin users, as well as any other administrator accounts that one of them creates.  INSTALLER, who has permissions identical to those of ADMINISTRATOR except that the installer cannot add or delete users or change the password of any other user.  TECHNICIAN, who
PMP 450 Planning Guide Security planning  pmp-0047 (June 2013)  2-53   GUEST, who has no write permissions and only a limited view of General Status tab From the factory default state, configure passwords for both the root and admin account at the ADMINISTRATOR permission level, using the Account => Change Users Password tab. (If you configure only one of these, then the other will still require no password for access into it and thus remain a security risk.) If you are intent on configuring only one of them, delete the admin account. The root account is the only account that CNUT uses to update the module.  After a password has been set for any ADMINISTRATOR-level account, initial access to the module GUI opens the view of GUEST level. Table 27  Identity-based user account permissions - AP Menu Option Menu Tab ADMIN INSTALLER TECH Home General Status         Session Status         Remote Subscribers         Event Log         Network Interface         Layer2 Neighbors       Configuration General         IP         Radio         SNMP         Quality of Service (QoS)         Security         Time         VLAN         VLAN Membership         DiffServ         Protocol Filtering         Port Configuration         Syslog         Unit Settings       Statistics Scheduler         SM Registration Failures         Bridge Control Block         Bridging Table         Ethernet         Radio         VLAN         Data VC         Throughput
Security planning Planning considerations  2-54  pmp-0047 (June 2013)    Filter         ARP         Overload         DHCP Relay         Pass Through Statistics         DNS Statistics       Tools Link Capacity Test         Combo Frame Calculator         OFDM Frame Calculator         Subscriber Configuration         Link Status         Remote Spectrum Analyzer         Sessions         DNS Test         AP Sessions         AP Authentication State Machine Log         AP Authorization State Machine Log         EAP Radius Log       Accounts User Authentication And Access Tracking         Change User Password         Add User         Delete User       Quick Start Quick Start         Region Settings         Radio Carrier Frequency         Synchronization         LAN IP Address         Review and Save Configuration       Copyright Copyright Notices       Logoff
PMP 450 Planning Guide Security planning  pmp-0047 (June 2013)  2-55  Table 28  Identity-based user account permissions - SM Menu Menu Tab ADMIN INSTALLER TECH Home General Status         Event Log         Network Interface         Layer2 Neighbors       Configuration General         IP         Radio         SNMP         Quality of Service (QoS)         Security         VLAN         VLAN Membership         DiffServ         Protocol Filtering         Port Configuration         NAT         PPPoE         NAT Port Mapping         Syslog         Unit Settings       Statistics Scheduler         Bridge Control Block         Bridging Table         Translation Table         Ethernet         Radio         VLAN         Data VC         Filter         NAT Stats         NAT DHCP         ARP         Overload         PPPoE Statistics         Peer Statistics         DNS Statistics         Syslog Statistics
Security planning Planning considerations  2-56  pmp-0047 (June 2013)  Tools Spectrum Analyzer         Alignment         Link Capacity Test         AP Evaluation         Combo Frame Calculator         OFDM Frame Calculator         BER Results         Alignment Tool         Link Status         DNS Test       Logs NAT Table         SM Session         SM Authentication         SM Authorization         PPPoE Session Log         EAP Radius Log       Accounts User Authentication and Access Tracking         Change User Password         Add User         Delete User       PDA Quick Status         Spectrum Results (PDA)         Information         AP Evaluation         AIM       Copyright Copyright Notices       Logoff           Filtering protocols and ports You can filter (block) specified protocols and ports from leaving the AP and SM and entering the network. This protects the network from both intended and inadvertent packet loading or probing by network users. By keeping the specified protocols or ports off the network, this feature also provides a level of protection to users from each other. Protocol and port filtering is set per AP/SM. Except for filtering of SNMP ports, filtering occurs as packets leave the AP/SM. If an SM is configured to filter SNMP, then SNMP packets are blocked from entering the SM and, thereby, from interacting with the SNMP portion of the protocol stack on the SM.
PMP 450 Planning Guide Security planning  pmp-0047 (June 2013)  2-57  Port Filtering with NAT Enabled Where NAT is enabled on the SM, you can filter only the three user-defined ports. The following are example situations in which you can configure port filtering where NAT is enabled.  To block a subscriber from using FTP, you can filter Ports 20 and 21 (the FTP ports) for both the TCP and UDP protocols.   To block a subscriber from access to SNMP, you can filter Ports 161 and 162 (the SNMP ports) for both the TCP and UDP protocols.  NOTE: In only the SNMP case, filtering occurs before the packet interacts with the protocol stack. Protocol and Port Filtering with NAT Disabled Where NAT is disabled on the SM, you can filter both protocols and the three user-defined ports. Using the check boxes on the interface, you can either   allow all protocols except those that you wish to block.  block all protocols except those that you wish to allow.  You can allow or block any of the following protocols:  PPPoE (Point to Point Protocol over Ethernet)  Any or all of the following IPv4 (Internet Protocol version 4) protocols: o SMB (Network Neighborhood) o SNMP o Up to 3 user-defined ports o All other IPv4 traffic (see Figure 26) o Uplink Broadcast o ARP (Address Resolution Protocol) o All others (see Figure 26)
Security planning Planning considerations  2-58  pmp-0047 (June 2013)  Figure 26  Categorical protocol filtering BootP ClientBootP ServerSNMP IPv4 MulticastUser Defined Port 1 SMBUser Defined Port 3User Defined Port 2PPPoE ARPAll OthersAll Other IPv4    The following are example situations in which you can configure protocol filtering where NAT is disabled:  If you block a subscriber from only PPoE and SNMP, then the subscriber retains access to all other protocols and all ports.  If you block PPoE, IPv4, and Uplink Broadcast, and you also check the  All others selection, then only Address Resolution Protocol is not filtered.
PMP 450 Planning Guide Security planning  pmp-0047 (June 2013)  2-59   The ports that are filtered as a result of protocol selections in the Protocol Filtering tab of the SM are listed in Table 29.  Table 29  Ports filtered per protocol selections Protocol  Selected Port Filtered (Blocked) SMB Destination Ports 137 TCP and UDP, 138 UDP, 139 TCP, 445 TCP SNMP Destination Ports 161 TCP and UDP, 162 TCP and UDP Bootp Client Source Port 68 UDP Bootp Server Source Port 67 UDP
Security planning Planning considerations  2-60  pmp-0047 (June 2013)  Port Lockdown Cambium devices support access to various communication protocols and only the ports required for these protocols are available for access by external entities.  Operators may change the port numbers for these protocols via the radio GUI or SNMP. Table 30  Device default port numbers Port Usage Port Usage Device 21 FTP Listen Port AP, SM 80 HTTP Listen Port AP, SM 1812 Standard RADIUS port Destination Port AP 1813 Standard RADIUS accounting port Destination Port AP, SM 161 SNMP port Listen Port AP, SM 162 SNMP trap port Destination Port AP, SM 514 Syslog Destination Port AP, SM  Isolating SMs In an AP, you can prevent SMs in the sector from directly communicating with each other. In CMMmicro Release 2.2 or later and the CMM4, you can prevent connected APs from directly communicating with each other, which prevents SMs that are in different sectors of a cluster from communicating with each other. In the AP, the SM Isolation parameter is available in the General tab of the Configuration web page. In the drop-down menu for that parameter, you can configure the SM Isolation feature by any of the following selections:  Disable SM Isolation (the default selection). This allows full communication between SMs.  Block SM Packets from being forwarded. This prevents both multicast/broadcast and unicast SM-to-SM communication.  Block and Forward SM Packets to Backbone. This not only prevents multicast/broadcast and unicast SM-to-SM communication but also sends the packets, which otherwise would have been handled SM to SM, through the Ethernet port of the AP.  In the CMMmicro and the CMM4, SM isolation treatment is the result of how you choose to manage the port-based VLAN feature of the embedded switch, where you can switch all traffic from any AP to an uplink port that you specify. However, this is not packet level switching. It is not based on VLAN IDs. See the VLAN Port Configuration parameter in the dedicated user guide that supports the CMM product that you are deploying.
PMP 450 Planning Guide Security planning  pmp-0047 (June 2013)  2-61  Filtering management through Ethernet You can configure the SM to disallow any device that is connected to its Ethernet port from accessing the IP address of the SM. If you set the Ethernet Access Control parameter to Enabled, then  no attempt to access the SM management interface (by http, SNMP, ftp, or tftp) through Ethernet can succeed.  any attempt to access the SM management interface over the air (by IP address, presuming that LAN1 Network Interface Configuration, Network Accessibility is set to Public, or by link from the Session Status or Remote Subscribers tab in the AP) is unaffected. Allowing management from only specified IP addresses The Security tab of the Configuration web page in the AP and SM includes the IP Access Control parameter. You can specify one, two, or three IP addresses that should be allowed to access the management interface (by HTTP, SNMP, FTP, or TFTP).  If you select  IP Access Filtering Disabled, then management access is allowed from any IP address, even if the Allowed Source IP 1 to 3 parameters are populated.  IP Access Filtering Enabled, and specify at least one address in the Allowed Source IP 1 to 3 parameter, then management access is limited to the specified address(es).  Configuring management IP by DHCP The IP tab in the Configuration web page of every radio contains a LAN1 Network Interface Configuration, DHCP State parameter that, if enabled, causes the IP configuration (IP address, subnet mask, and gateway IP address) to be obtained through DHCP instead of the values of those individual parameters. The setting of this DHCP state parameter is also viewable, but is not settable, in the Network Interface tab of the Home page.  In the SM, this parameter is settable  in the NAT tab of the Configuration web page, but only if NAT is enabled.  in the IP tab of the Configuration web page, but only if the Network Accessibility parameter in the IP tab is set to Public. Planning for airlink security Cambium fixed wireless broadband IP systems employ the following form of encryption for security of the wireless link:  DES (Data Encryption Standard):  An over-the-air link encryption option that uses secret 56-bit keys and 8 parity bits.  DES performs a series of bit permutations, substitutions, and recombination operations on blocks of data.  DES encryption does not affect the performance or throughput of the system.  AES (Advanced Encryption Standard):  An over-the-air link encryption option that uses the Rijndael algorithm and 128-bit keys to establish a higher level of security than DES.  AES products are certified as compliant with the Federal Information Processing Standards (FIPS 197) in the U.S.A.
Security planning Planning considerations  2-62  pmp-0047 (June 2013)  Planning for RF Telnet Access Control The RF Telnet Access feature restricts Telnet access to the AP from a device situated below a network SM (downstream from the AP).  This is a security enhancement to restrict RF-interface sourced AP access specifically to the LAN1 IP address and LAN2 IP address (Radio Private Address, typically 192.168.101.[LUID]).  This restriction disallows unauthorized users from running Telnet commands on the AP that can change AP configuration or modifying network-critical components such as routing and ARP tables. Forwarding Downlink PPPoE PADI packets The AP supports the control of forwarding of PPPoE PADI (PPPoE Active Discovery Initiation) packets.  This forwarding is configured on the AP GUI Configuration, Radio tab by parameter PPPoE PADI Downlink Forwarding.  When set to “Enabled”, the AP allows downstream and upstream transmission of PPPoE PADI packets.  When set to “Disabled”, the AP will NOT allow PPPoE PADI packets to be sent out of the AP RF interface (downstream) but will allow PPPoE PADI packets to enter the RF interface (upstream) and exit the Ethernet interface. Planning for RADIUS integration PMP 450 modules include support for the RADIUS (Remote Authentication Dial In User Service) protocol supporting Authentication, Authorization, and Accounting (AAA). RADIUS Functions RADIUS protocol support provides the following functions:   SM Authentication allows only known SMs onto the network (blocking “rogue” SMs), and can be configured to ensure SMs are connecting to a known network (preventing SMs from connecting to “rogue” APs). RADIUS authentication is used for SMs, but is not used for APs.  Cambium modules support EAP-TTLS and EAP-MSCHAPv2 authentication methods.  SM Configuration: Configures authenticated SMs with MIR (Maximum Information Rate), CIR (Committed Information Rate), High Priority, and VLAN (Virtual LAN) parameters from the RADIUS server when an SM registers to an AP.  SM Accounting provides support for RADIUS accounting messages for usage-based billing.  This accounting includes indications for subscriber session establishment, subscriber session disconnection, and bandwidth usage per session for each SM that connects to the AP.    Centralized AP and SM user name and password management allows AP and SM usernames and access levels (Administrator, Installer, Technician) to be centrally administered in the RADIUS server instead of on each radio and tracks access events (logon/logoff) for each username on the RADIUS server. This accounting does not track and report specific configuration actions performed on radios or pull statistics such as bit counts from the radios. Such functions require an Element Management System (EMS) such as Cambium Networks Wireless Manager. This accounting is not the ability to perform accounting functions on the subscriber/end user/customer account.
PMP 450 Planning Guide Security planning  pmp-0047 (June 2013)  2-63   Framed IP allows operators to use a RADIUS server to assign management IP addressing to SM modules (framed IP address). Planning for SNMP security Canopy modules provide the following Configuration web page parameters in the SNMP tab. These govern SNMP access from the manager to the agent:  Community String, which specifies the password for security between managers and the agent.  Accessing Subnet, which specifies the subnet mask that allows managers to poll the agents.
Ordering components Planning considerations  2-64  pmp-0047 (June 2013)  Ordering components This section describes how to select components for PMP 450 Greenfield network or PMP 450 network migration. It specifies Cambium part numbers for PMP 450 components. PMP 450 component part numbers Table 31 lists PMP 450 components. Table 31  PMP 450 components  Part Number Product Description Sales Models  C024045A001A 2.4 GHz PMP 450 Connectorized Access Point, US/Canada Only, AES C024045A002A 2.4 GHz PMP 450 Connectorized Access Point, US/Canada Only, DES C024045C001A 2.4 GHz PMP 450 Subscriber Module, 4 Mbps C024045C002A 2.4 GHz PMP 450 Subscriber Module, 10 Mbps C024045C003A 2.4 GHz PMP 450 Subscriber Module, 20 Mbps C024045C004A 2.4 GHz PMP 450 Subscriber Module, Uncapped C024045C005A 2.4 GHz PMP 450 Connectorized Subscriber Module, 4 Mbps C024045C006A 2.4 GHz PMP 450 Connectorized Subscriber Module, 10 Mbps C024045C007A 2.4 GHz PMP 450 Connectorized Subscriber Module, 20 Mbps C024045C008A 2.4 GHz PMP 450 Connectorized Subscriber Module, Uncapped C054045A001A 5 GHz PMP 450 Connectorized Access Point C054045A002A 5 GHz PMP 450 Connectorized Access Point, US C054045C005A 5 GHz PMP 450 Connectorized Subscriber Module, 4 Mbps C054045C006A 5 GHz PMP 450 Connectorized Subscriber Module, 10 Mbps
PMP 450 Planning Guide Ordering components  pmp-0047 (June 2013)  2-65  C054045C007A 5 GHz PMP 450 Connectorized Subscriber Module, 20 Mbps C054045C008A 5 GHz PMP 450 Connectorized Subscriber Module, Uncapped AP Antenna Options  C024045D901A 2.4 GHz Dual Slant Antenna for 90 Degree Sector C024045D601A 2.4 GHz Dual Slant Antenna for 60 Degree Sector 30009406002 N-type to N-type cable (16 inch length) AP Optional Equipment  ACPSSSW-22A POWER SUPPLY, 20W, 29.5V, 100-240VAC/50-60HZ – GIG-E support ACPSSW-20A POWER SUPPLY,20W, 29.5V, 100-240VAC/50-60HZ ACPSSW-21A POWER SUPPLY,20W,29.5V,100-240VAC/50-60HZ +C8 AC ACPS120WA POWER SUPPLY,120W 30VDC AT 60C 100-240VAC EL5 600SSH SURGE PROTECTOR SMMB2A UNIVERSAL MOUNTING BRACKET 1070CKHH CMM MICRO (OUTDOOR ENCLOSURE) 1090CKHH CMM4 W/RUGGEDIZED SWITCH AND GPS 1091HH CMM4 NO SWITCH 1092HH CMM4 RACK MOUNT ASSEMBLY 1096H UNIVERSAL GPS MODULE SM Optional Equipment  ACPSSW-09B POWER SUPPLY,13.6W, 29.5V, 100-240VAC/50-60HZ ACPSSW-10B POWER SUPPLY,13.6W,29.5V,100-240VAC/50-60HZ+ARG ACPSSW-11B POWER SUPPLY, 13.6W,29.5V,100-240VAC/50-60HZ+AUS ACPSSW-12C POWER SUPPLY,ASSY,P/S,29.5V90-240VAC/50-60HZ PS
Ordering components Planning considerations  2-66  pmp-0047 (June 2013)  ACPSSW-13B POWER SUPPLY,13.6W,29.5V,100-240/50-60+FIXED US ACPSSW-14A POWER SUPPLY,13.6W,29.5V,100-240VAC/50-60HZ+BRAZ HK2022A 53CM OFFSET, REFLECTOR DISH KIT,4PK SMMB1A UNIVERSAL MOUNTING KIT 600SSH SURGE PROTECTOR Upgrade Keys  C000045K002A PMP 450 4 TO 10 MBPS UPGRADE KEY C000045K003A PMP 450 4 TO 20 MBPS UPGRADE KEY C000045K004A PMP 450 4 TO Uncapped UPGRADE KEY C000045K005A PMP 450 10 TO 20 MBPS UPGRADE KEY C000045K006A PMP 450 10 TO Uncapped MBPS UPGRADE KEY C000045K007A PMP 450 20 TO Uncapped MBPS UPGRADE KEY Extended Warranty  SG00TS4009A PMP450 AP Extended Warranty, 1 Additional Year SG00TS4017A PMP450 AP Extended Warranty, 2 Additional Years SG00TS4025A PMP450 AP Extended Warranty, 4 Additional Years SG00TS4010A PMP450 SM Extended Warranty, 1 Additional Year SG00TS4018A PMP450 SM Extended Warranty, 2 Additional Years SG00TS4026A PMP450 SM Extended Warranty, 4 Additional Years Part Number Product Description Sales Models  C054045A001A 5 GHz PMP 450 Connectorized Access Point C054045A002A 5 GHz PMP 450 Connectorized Access Point, US C054045C005A 5 GHz PMP 450 Connectorized Subscriber Module, 4 Mbps
PMP 450 Planning Guide Ordering components  pmp-0047 (June 2013)  2-67  C054045C006A 5 GHz PMP 450 Connectorized Subscriber Module, 10 Mbps C054045C007A 5 GHz PMP 450 Connectorized Subscriber Module, 20 Mbps C054045C008A 5 GHz PMP 450 Connectorized Subscriber Module, Uncapped AP Antenna Options  30009406002 N-type to N-type cable (16 inch length) AP Optional Equipment  ACPSSSW-22A POWER SUPPLY, 20W, 29.5V, 100-240VAC/50-60HZ – GIG-E support ACPSSW-20A POWER SUPPLY,20W, 29.5V, 100-240VAC/50-60HZ ACPSSW-21A POWER SUPPLY,20W,29.5V,100-240VAC/50-60HZ +C8 AC ACPS120WA POWER SUPPLY,120W 30VDC AT 60C 100-240VAC EL5 600SSH SURGE PROTECTOR SMMB2A UNIVERSAL MOUNTING BRACKET 1070CKHH CMM MICRO (OUTDOOR ENCLOSURE) 1090CKHH CMM4 W/RUGGEDIZED SWITCH AND GPS 1091HH CMM4 NO SWITCH 1092HH CMM4 RACK MOUNT ASSEMBLY 1096H UNIVERSAL GPS MODULE SM Optional Equipment  ACPSSW-09B POWER SUPPLY,13.6W, 29.5V, 100-240VAC/50-60HZ ACPSSW-10B POWER SUPPLY,13.6W,29.5V,100-240VAC/50-60HZ+ARG ACPSSW-11B POWER SUPPLY, 13.6W,29.5V,100-240VAC/50-60HZ+AUS ACPSSW-12C POWER SUPPLY,ASSY,P/S,29.5V90-240VAC/50-60HZ PS ACPSSW-13B POWER SUPPLY,13.6W,29.5V,100-240/50-60+FIXED US ACPSSW-14A POWER SUPPLY,13.6W,29.5V,100-240VAC/50-60HZ+BRAZ
Ordering components Planning considerations  2-68  pmp-0047 (June 2013)  HK2022A 53CM OFFSET, REFLECTOR DISH KIT,4PK SMMB1A UNIVERSAL MOUNTING KIT 600SSH SURGE PROTECTOR Upgrade Keys  C000045K002A PMP 450 4 TO 10 MBPS UPGRADE KEY C000045K003A PMP 450 4 TO 20 MBPS UPGRADE KEY C000045K004A PMP 450 4 TO Uncapped UPGRADE KEY C000045K005A PMP 450 10 TO 20 MBPS UPGRADE KEY C000045K006A PMP 450 10 TO Uncapped MBPS UPGRADE KEY C000045K007A PMP 450 20 TO Uncapped MBPS UPGRADE KEY Extended Warranty  SG00TS4009A PMP450 AP Extended Warranty, 1 Additional Year SG00TS4017A PMP450 AP Extended Warranty, 2 Additional Years SG00TS4025A PMP450 AP Extended Warranty, 4 Additional Years SG00TS4010A PMP450 SM Extended Warranty, 1 Additional Year SG00TS4018A PMP450 SM Extended Warranty, 2 Additional Years SG00TS4026A PMP450 SM Extended Warranty, 4 Additional Years
PMP 450 Planning Guide Legal information    Chapter 3:  Legal information This chapter provides legal notices including software license agreements.   Intentional or unintentional changes or modifications to the equipment must not be made unless under the express consent of the party responsible for compliance.  Any such modifications could void the user’s authority to operate the equipment and will void the manufacturer’s warranty. The following topics are described in this chapter:  Cambium Networks end user license agreement on page 3-2  Hardware warranty on page 3-9  Limit of liability on page 3-10
Cambium Networks end user license agreement Legal information  3-2  pmp-0047 (June 2013)  Cambium Networks end user license agreement Acceptance of this agreement In connection with Cambium’s delivery of certain proprietary software or products containing embedded or pre-loaded proprietary software, or both, Cambium is willing to license this certain proprietary software and the accompanying documentation to you only on the condition that you accept all the terms in this End User License Agreement (“Agreement”). IF YOU DO NOT AGREE TO THE TERMS OF THIS AGREEMENT, DO NOT USE THE PRODUCT OR INSTALL THE SOFTWARE.  INSTEAD, YOU MAY, FOR A FULL REFUND, RETURN THIS PRODUCT TO THE LOCATION WHERE YOU ACQUIRED IT OR PROVIDE WRITTEN VERIFICATION OF DELETION OF ALL COPIES OF THE SOFTWARE.  ANY USE OF THE SOFTWARE, INCLUDING BUT NOT LIMITED TO USE ON THE PRODUCT, WILL CONSTITUTE YOUR ACCEPTANCE TO THE TERMS OF THIS AGREEMENT.   Definitions In this Agreement, the word “Software” refers to the set of instructions for computers, in executable form and in any media, (which may include diskette, CD-ROM, downloadable internet, hardware, or firmware) licensed to you.  The word “Documentation” refers to electronic or printed manuals and accompanying instructional aids licensed to you. The word “Product” refers to Cambium’s fixed wireless broadband devices for which the Software and Documentation is licensed for use.   Grant of license Cambium Networks Limited (“Cambium”) grants you (“Licensee” or “you”) a personal, nonexclusive, non-transferable license to use the Software and Documentation subject to the Conditions of Use set forth in “Conditions of use” and the terms and conditions of this Agreement.  Any terms or conditions relating to the Software and Documentation appearing on the face or reverse side of any purchase order, purchase order acknowledgment or other order document that are different from, or in addition to, the terms of this Agreement will not be binding on the parties, even if payment is accepted.   Conditions of use Any use of the Software and Documentation outside of the conditions set forth in this Agreement is strictly prohibited and will be deemed a breach of this Agreement.
PMP 450 Planning Guide Cambium Networks end user license agreement  pmp-0047 (June 2013)  3-3  1. Only you, your employees or agents may use the Software and Documentation.  You will take all necessary steps to insure that your employees and agents abide by the terms of this Agreement. 2. You will use the Software and Documentation (i) only for your internal business purposes; (ii) only as described in the Software and Documentation; and (iii) in strict accordance with this Agreement. 3. You may use the Software and Documentation, provided that the use is in conformance with the terms set forth in this Agreement.    4. Portions of the Software and Documentation are protected by United States copyright laws, international treaty provisions, and other applicable laws.  Therefore, you must treat the Software like any other copyrighted material (for example, a book or musical recording) except that you may either: (i) make 1 copy of the transportable part of the Software (which typically is supplied on diskette, CD-ROM, or downloadable internet), solely for back-up purposes; or (ii) copy the transportable part of the Software to a PC hard disk, provided you keep the original solely for back-up purposes.  If the Documentation is in printed form, it may not be copied.  If the Documentation is in electronic form, you may print out 1 copy, which then may not be copied.  With regard to the copy made for backup or archival purposes, you agree to reproduce any Cambium copyright notice, and other proprietary legends appearing thereon.  Such copyright notice(s) may appear in any of several forms, including machine-readable form, and you agree to reproduce such notice in each form in which it appears, to the extent it is physically possible to do so.  Unauthorized duplication of the Software or Documentation constitutes copyright infringement, and in the United States is punishable in federal court by fine and imprisonment.   5. You will not transfer, directly or indirectly, any product, technical data or software to any country for which the United States Government requires an export license or other governmental approval without first obtaining such license or approval.   Title and restrictions If you transfer possession of any copy of the Software and Documentation to another party outside of the terms of this agreement, your license is automatically terminated.  Title and copyrights to the Software and Documentation and any copies made by you remain with Cambium and its licensors.  You will not, and will not permit others to: (i) modify, translate, decompile, bootleg, reverse engineer, disassemble, or extract the inner workings of the Software or Documentation, (ii) copy the look-and-feel or functionality of the Software or Documentation; (iii) remove any proprietary notices, marks, labels, or logos from the Software or Documentation; (iv) rent or transfer all or some of the Software or Documentation to any other party without Cambium’s prior written consent; or (v) utilize any computer software or hardware which is designed to defeat any copy protection device, should the Software and Documentation be equipped with such a protection device.  If the Software and Documentation is provided on multiple types of media (such as diskette, CD-ROM, downloadable internet), then you will only use the medium which best meets your specific needs, and will not loan, rent, lease, or transfer the other media contained in the package without Cambium’s written consent.  Unauthorized copying of the Software or Documentation, or failure to comply with any of the provisions of this Agreement, will result in automatic termination of this license.
Cambium Networks end user license agreement Legal information  3-4  pmp-0047 (June 2013)  Confidentiality You acknowledge that all Software and Documentation contain valuable proprietary information and trade secrets and that unauthorized or improper use of the Software and Documentation will result in irreparable harm to Cambium for which monetary damages would be inadequate and for which Cambium will be entitled to immediate injunctive relief.  If applicable, you will limit access to the Software and Documentation to those of your employees and agents who need to use the Software and Documentation for your internal business purposes, and you will take appropriate action with those employees and agents to preserve the confidentiality of the Software and Documentation, using the same degree of care to avoid unauthorized or improper disclosure as you use for the protection of your own proprietary software, but in no event less than reasonable care. You have no obligation to preserve the confidentiality of any proprietary information that: (i) was in the public domain at the time of disclosure; (ii) entered the public domain through no fault of yours; (iii) was given to you free of any obligation to keep it confidential; (iv) is independently developed by you; or (v) is disclosed as required by law provided that you notify Cambium prior to such disclosure and provide Cambium with a reasonable opportunity to respond.   Right to use Cambium’s name Except as required in “Conditions of use”, you will not, during the term of this Agreement or thereafter, use any trademark of Cambium, or any word or symbol likely to be confused with any Cambium trademark, either alone or in any combination with another word or words.   Transfer The Software and Documentation may not be transferred to another party without the express written consent of Cambium, regardless of whether or not such transfer is accomplished by physical or electronic means.  Cambium’s consent may be withheld at its discretion and may be conditioned upon transferee paying all applicable license fees and agreeing to be bound by this Agreement.   Updates During the first 12 months after purchase of a Product, or during the term of any executed Maintenance and Support Agreement for the Product, you are entitled to receive Updates.  An “Update” means any code in any form which is a bug fix, patch, error correction, or minor enhancement, but excludes any major feature added to the Software.  Updates are available for download at the support website. Major features may be available from time to time for an additional license fee.  If Cambium makes available to you major features and no other end user license agreement is provided, then the terms of this Agreement will apply.
PMP 450 Planning Guide Cambium Networks end user license agreement  pmp-0047 (June 2013)  3-5  Maintenance Except as provided above, Cambium is not responsible for maintenance or field service of the Software under this Agreement.   Disclaimer CAMBIUM DISCLAIMS ALL WARRANTIES OF ANY KIND, WHETHER EXPRESS, IMPLIED, STATUTORY, OR IN ANY COMMUNICATION WITH YOU.  CAMBIUM SPECIFICALLY DISCLAIMS ANY WARRANTY INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILTY, NONINFRINGEMENT, OR FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE AND DOCUMENTATION ARE PROVIDED “AS IS.” CAMBIUM DOES NOT WARRANT THAT THE SOFTWARE WILL MEET YOUR REQUIREMENTS, OR THAT THE OPERATION OF THE SOFTWARE WILL BE UNINTERRUPTED OR ERROR FREE, OR THAT DEFECTS IN THE SOFTWARE WILL BE CORRECTED.  CAMBIUM MAKES NO WARRANTY WITH RESPECT TO THE CORRECTNESS, ACCURACY, OR RELIABILITY OF THE SOFTWARE AND DOCUMENTATION.  Some jurisdictions do not allow the exclusion of implied warranties, so the above exclusion may not apply to you.   Limitation of liability THE TOTAL LIABILITY OF CAMBIUM UNDER THIS AGREEMENT FOR DAMAGES WILL NOT EXCEED THE TOTAL AMOUNT PAID BY YOU FOR THE PRODUCT LICENSED UNDER THIS AGREEMENT.  IN NO EVENT WILL CAMBIUM BE LIABLE IN ANY WAY FOR INCIDENTAL, CONSEQUENTIAL, INDIRECT, SPECIAL OR PUNITIVE DAMAGES OF ANY NATURE, INCLUDING WITHOUT LIMITATION, LOST BUSINESS PROFITS, OR LIABILITY OR INJURY TO THIRD PERSONS, WHETHER FORESEEABLE OR NOT, REGARDLESS OF WHETHER CAMBIUM HAS BEEN ADVISED OF THE POSSIBLITY OF SUCH DAMAGES. Some jurisdictions do not permit limitations of liability for incidental or consequential damages, so the above exclusions may not apply to you.
Cambium Networks end user license agreement Legal information  3-6  pmp-0047 (June 2013)  U.S. government If you are acquiring the Product on behalf of any unit or agency of the U.S. Government, the following applies.  Use, duplication, or disclosure of the Software and Documentation is subject to the restrictions set forth in subparagraphs (c) (1) and (2) of the Commercial Computer Software – Restricted Rights clause at FAR 52.227-19 (JUNE 1987), if applicable, unless being provided to the Department of Defense.  If being provided to the Department of Defense, use, duplication, or disclosure of the Products is subject to the restricted rights set forth in subparagraph (c) (1) (ii) of the Rights in Technical Data and Computer Software clause at DFARS 252.227-7013 (OCT 1988), if applicable.  Software and Documentation may or may not include a Restricted Rights notice, or other notice referring specifically to the terms and conditions of this Agreement.  The terms and conditions of this Agreement will each continue to apply, but only to the extent that such terms and conditions are not inconsistent with the rights provided to you under the aforementioned provisions of the FAR and DFARS, as applicable to the particular procuring agency and procurement transaction.   Term of license Your right to use the Software will continue in perpetuity unless terminated as follows. Your right to use the Software will terminate immediately without notice upon a breach of this Agreement by you.  Within 30 days after termination of this Agreement, you will certify to Cambium in writing that through your best efforts, and to the best of your knowledge, the original and all copies, in whole or in part, in any form, of the Software and all related material and Documentation, have been destroyed, except that, with prior written consent from Cambium, you may retain one copy for archival or backup purposes. You may not sublicense, assign or transfer the license or the Product, except as expressly provided in this Agreement.  Any attempt to otherwise sublicense, assign or transfer any of the rights, duties or obligations hereunder is null and void.   Governing law This Agreement is governed by the laws of the United States of America to the extent that they apply and otherwise by the laws of the State of Illinois.   Assignment This agreement may not be assigned by you without Cambium’s prior written consent.   Survival of provisions The parties agree that where the context of any provision indicates an intent that it survives the term of this Agreement, then it will survive.
PMP 450 Planning Guide Cambium Networks end user license agreement  pmp-0047 (June 2013)  3-7    Entire agreement This agreement contains the parties’ entire agreement regarding your use of the Software and may be amended only in writing signed by both parties, except that Cambium may modify this Agreement as necessary to comply with applicable laws.   Third party software The software may contain one or more items of Third-Party Software supplied by other third-party suppliers.  The terms of this Agreement govern your use of any Third-Party Software UNLESS A SEPARATE THIRD-PARTY SOFTWARE LICENSE IS INCLUDED, IN WHICH CASE YOUR USE OF THE THIRD-PARTY SOFTWARE WILL THEN BE GOVERNED BY THE SEPARATE THIRD-PARTY LICENSE. ZLIB Copyright Notice Copyright © 1995-1998 Jean-loup Gailly and Mark Adler This software is provided 'as-is', without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. 3. This notice may not be removed or altered from any source distribution. Jean-loup Gailly jloup@gzip.org Mark Adler madler@alumni.caltech.edu Modernizr Copyright Notice MIT License  Copyright © 2009-2010 Faruk Ates
Cambium Networks end user license agreement Legal information  3-8  pmp-0047 (June 2013)  Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. BSD License  Copyright © 2010, Faruk Ates All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:  Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. Neither the name of the Organization nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission.  THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDER BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
PMP 450 Planning Guide Hardware warranty  pmp-0047 (June 2013)  3-9  Hardware warranty Cambium’s standard hardware warranty is for one (1) year from date of shipment from Cambium or a Cambium Point-To-Point Distributor. Cambium warrants that hardware will conform to the relevant published specifications and will be free from material defects in material and workmanship under normal use and service. Cambium shall within this time, at its own option, either repair or replace the defective product within thirty (30) days of receipt of the defective product. Repaired or replaced product will be subject to the original warranty period but not less than thirty (30) days.
Limit of liability Legal information  3-10  pmp-0047 (June 2013)  Limit of liability IN NO EVENT SHALL CAMBIUM NETWORKS BE LIABLE TO YOU OR ANY OTHER PARTY FOR ANY DIRECT, INDIRECT, GENERAL, SPECIAL, INCIDENTAL, CONSEQUENTIAL, EXEMPLARY OR OTHER DAMAGE ARISING OUT OF THE USE OR INABILITY TO USE THE PRODUCT (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS INTERRUPTION, LOSS OF BUSINESS INFORMATION OR ANY OTHER PECUNIARY LOSS, OR FROM ANY BREACH OF WARRANTY, EVEN IF CAMBIUM HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. (Some states do not allow the exclusion or limitation of incidental or consequential damages, so the above exclusion or limitation may not apply to you.) IN NO CASE SHALL CAMBIUM’S LIABILITY EXCEED THE AMOUNT YOU PAID FOR THE PRODUCT.
  pmp-0047 (June 2013)  4-1  Chapter 4:  Reference information This chapter contains reference information and regulatory notices that apply to the PMP 450 Series products. The following topics are described in this chapter:  Equipment specifications on page 4-2 contains specifications of the AP, SM and other equipment required for PMP 450 installations.  Wireless specifications on page 4-8 contains specifications of the PMP 450 wireless interface, including RF bands, channel width and link loss.  Data network specifications on page 4-9 contains specifications of the PMP 450 Ethernet interface.  Compliance with safety standards on page 4-10 lists the safety specifications against which the PMP 450 has been tested and certified. It also describes how to keep RF exposure within safe limits.  Compliance with radio regulations on page 4-15 describes how the PMP 450 complies with the radio regulations that are enforced in various countries.  Notifications on page 4-33 contains notifications made to regulatory bodies for the PMP 450.
Equipment specifications Reference information  4-2  pmp-0047 (June 2013)  Equipment specifications This section contains specifications of the AP, SM, associated supplies required for PMP 450 installations. AP specifications The PMP 450 AP conforms to the specifications listed in Table 32.  These specifications apply to all PMP 450 product variants. Table 32 Connectorized AP physical specifications  Category Specification Product Model Number 2.4 GHz C024045A001A, C024045A002A (US Only) 5 GHz C054045A001A, C054045A002A (US Only) Spectrum Channel Spacing 5 MHz channel bandwidth Configurable on 2.5 MHz increments 10 MHz, 20 MHz channel bandwidth Configurable on 5 MHz increments Frequency Range 2.4 GHz 2400 – 2483.5 MHz 5 GHz 5470 – 5875 MHz (dependent upon Region Code setting) Channel Width 5 MHz (2.4 GHz and 5.8 GHz), 10 MHz or 20 MHz Interface MAC (Media Access Control) Layer Cambium Proprietary Physical Layer 2x2 MIMO OFDM Ethernet Interface 10/100BaseT, half/full duplex, rate auto negotiated (802.3 compliant) Protocols Used IPv4, UDP, TCP, IP, ICMP, SNMP, HTTP, FTP, RADIUS
PMP 450 Planning Guide Equipment specifications  pmp-0047 (June 2013)  4-3  Category Specification Network Management HTTP, FTP, SNMP v2c, Syslog VLAN 802.1ad (DVLAN Q-inQ), 802.1Q with 802.1p priority, dynamic port VID Performance Nominal Receive Sensitivity (w/ FEC) @ 5 MHz Channel, Single Branch 2.4 GHz OFDM: 2x = -90 dBm, 4x = -83 dBm, 6x = -76 dBm 5 GHz OFDM: 2x = -86 dBm, 4x = -79 dBm, 6x = -72 dBm Nominal Receive Sensitivity (w/ FEC) @ 10 MHz Channel, Single Branch 2.4 GHz OFDM: 2x = -87 dBm, 4x = -80 dBm, 6x = -73 dBm 5 GHz OFDM: 2x = -86 dBm, 4x = -79 dBm, 6x = -72 dBm Nominal Receive Sensitivity (w/ FEC) @ 20 MHz Channel, Single Branch 2.4 GHz OFDM: 2x = -84 dBm, 4x = -77 dBm, 6x = -70 dBm 5 GHz OFDM: 2x = -83 dBm, 4x = -76 dBm, 6x = -69 dBm Maximum Deployment Range 2.4 GHz Up to 40 km (25 mi) 5 GHz Up to 40 km (25 mi) Subscribers Per Sector Up to 200 ARQ Yes Cyclic Prefix 1/16
Equipment specifications Reference information  4-4  pmp-0047 (June 2013)  Category Specification Modulation Levels (Adaptive) QPSK, QPSK (MIMO-B), 16-QAM (MIMO-B), 64-QAM (MIMO-B) Latency 5 – 7 ms Packets Per Second 12, 500 GPS Synchronization Yes, via CMM3, CMM4, or UGPS Quality of Service Diffserv QoS Link Budget Antenna Beam Width 60º sectors Combined Transmit Power -30 to +22 dBm (to EIRP limit by region) in 1 dB-configurable intervals Antenna Gain 2.4 GHz 15 dBi Horizontal and Vertical 5 GHz 17 dBi Horizontal and Vertical Maximum Transmit Power 22 dBm combined OFDM Physical Wind Loading 190 km/hour (118 mi/hour) Antenna Connection 50 ohm, N-type Environmental IP67 Temperature -40ºC to +55ºC (-40ºF to +131ºF) Weight 5.9 kg (13 lbs) with antenna 2.5 kg (5.5 lbs) without antenna Dimensions (H x W x D) Radio: 27 x 21 x 7 cm (10.6” x 8.3” x 2.8”) Antenna: 51 x 13 x 7.3 cm (20.2” x 5.1” x 2.9”) Maximum Power Consumption 18 W Input Voltage 29 V Security Encryption 56-bit DES, AES Certifications
PMP 450 Planning Guide Equipment specifications  pmp-0047 (June 2013)  4-5  Category Specification FCC ID Z8H89FT0002 Industry Canada Cert 109W-0002  SM specifications The PMP 450 SM conforms to the specifications listed in Table 33. These specifications apply to all PMP 450 product variants. Table 33 SM physical specifications  Category Specification Product Model Number C054045C001A (4 Mbps Cap), C054045C002A (10 Mbps Cap), C054045C003A (20 Mbps Cap), C054045C004A (Uncapped), C024045C001A (4 Mbps cap), C024045C002A (10 Mbps cap), C024045C003A (20 Mbps cap), C024045C004A (Uncapped), C024045C005A (4 Mbps cap), C024045C006A (10 Mbps cap), C024045C007A (20 Mbps cap), C024045C008A (Uncapped) Spectrum Channel Spacing 5 MHz channel bandwidth Configurable on 2.5 MHz increments 10MHz, 20 MHz channel bandwidth Configurable on 5 MHz increments Frequency Range 2.4 GHz 2400 – 2483.5 MHz 5 GHz 5470 – 5875 MHz (dependent upon Region Code setting) Channel Width 5 MHz (2.4 GHz and 5.8 GHz only), 10 MHz or 20 MHz Interface MAC (Media Access Control) Layer Cambium Proprietary Physical Layer 2x2 MIMO OFDM
Equipment specifications Reference information  4-6  pmp-0047 (June 2013)  Category Specification Ethernet Interface 10/100BaseT, half/full duplex, rate auto negotiated (802.3 compliant) Protocols Used IPv4, UDP, TCP, IP, ICMP, SNMP, HTTP, FTP, RADIUS Network Management HTTP, FTP, SNMP v2c, Syslog VLAN 802.1ad (DVLAN Q-in-Q), 802.1Q with 802.1p priority, dynamic port VID Performance Maximum Deployment Range 2.4 GHz Up to 40 km (25 mi) 5 GHz Up to 40 km (25 mi) ARQ Yes Cyclic Prefix 1/16 Modulation Levels (Adaptive) 1x = QPSK, 2x = QPSK-MIMO-B, 4x = 16-QAM-MIMO-B, 6x = 64-QAM-MIMO-B Latency 5 - 7 ms GPS Synchronization Yes Quality of Service Diffserv QoS Link Budget Antenna Beam Width 55º azimuth, 55º elevation (both horizontal and vertical) Combined Transmit Power -30 to +22 dBm (to EIRP limit by region)  Antenna Gain 9 dBi H+V, integrated patch Maximum Transmit Power 22 dBm combined Reflector Gain (Connectorized models only) +14 dBi CLIP Gain (5 GHz only) +8 dBi LENS Gain (5 GHz only) +5.5 dBi Physical Wind Loading 190 km/hour (118 mi/hour)
PMP 450 Planning Guide Equipment specifications  pmp-0047 (June 2013)  4-7  Category Specification Environmental IP55 Temperature -40ºC to +55ºC (-40ºF to +131ºF) Weight 0.45 kg (1 lb) Dimensions (H x W x D) 30 x 9 x 9 cm (11.75” x 3.4” x 3.4”) Maximum Power Consumption 12 W Input Voltage 29 V Security Encryption 56-bit DES, AES Certifications FCC ID Z8H89FT0001 Industry Canada Cert 109W-0001
Wireless specifications Reference information  4-8  pmp-0047 (June 2013)  Wireless specifications This section contains specifications of the PMP 450 wireless interface. These specifications include RF bands, channel bandwidth, spectrum settings, maximum power and link loss. General wireless specifications Table 34 lists the wireless specifications that apply to all PMP 450 variants.  Table 34  PMP 450 wireless specifications Item  Specification  Channel selection Manual selection (fixed frequency). Manual power control  To avoid interference to other users of the band, maximum power can be set lower than the default power limit. Duplex scheme Adaptive TDD Range 25 mi / 40 km Over-the-air encryption DES Error Correction FEC
PMP 450 Planning Guide Data network specifications  pmp-0047 (June 2013)  4-9  Data network specifications This section contains specifications of the PMP 450 Ethernet interface. Ethernet interface The PMP 450 Ethernet port conforms to the specifications listed in Table 35. Table 35  PMP 450 Ethernet bridging specifications Ethernet Bridging  Specification Protocol  IEEE 802.3 compatible QoS IEEE 802.1p, IEEE 802.1Q, IEEE 802.1ad, DSCP IPv4 Interface  10/100BaseT, half/full duplex, rate auto negotiated Maximum Ethernet Frame Size 1522 Bytes   Practical Ethernet rates will depend on network configuration, higher layer protocols and platforms used. Over the air throughput is restricted to the rate of the Ethernet interface at the receiving end of the link.
Compliance with safety standards Reference information  4-10  pmp-0047 (June 2013)  Compliance with safety standards This section lists the safety specifications against which the PMP 450 has been tested and certified. It also describes how to keep RF exposure within safe limits. Electrical safety compliance  The PMP 450 hardware has been tested for compliance to the electrical safety specifications listed in Table 36. Table 36  PMP 450 safety compliance specifications Region Specification USA UL 60950 Canada CSA C22.2 No.60950 International CB certified & certificate to IEC 60950  Electromagnetic compatibility (EMC) compliance Table 37 lists the EMC specification type approvals that have been granted for PMP 450. Table 37  EMC emissions compliance  Variant Region Specification (Type Approvals) PMP 450 USA FCC Part 15 Class B Canada RSS Gen and RSS 210 International EN 301 489-1 V1.9.2 EN 301 489-17 V2.1.1
PMP 450 Planning Guide Compliance with safety standards  pmp-0047 (June 2013)  4-11  Human exposure to radio frequency energy Standards Relevant standards (USA and EC) applicable when working with RF equipment are:  ANSI IEEE C95.1-1991, IEEE Standard for Safety Levels with Respect to Human Exposure to Radio Frequency Electromagnetic Fields, 3 kHz to 300 GHz.  Council recommendation of 12 July 1999 on the limitation of exposure of the general public to electromagnetic fields (0 Hz to 300 GHz) (1999/519/EC) and respective national regulations.  Directive 2004/40/EC of the European Parliament and of the Council of 29 April 2004 on the minimum health and safety requirements regarding the exposure of workers to the risks arising from physical agents (electromagnetic fields) (18th individual Directive within the meaning of Article 16(1) of Directive 89/391/EEC).  US FCC limits for the general population. See the FCC web site at http://www.fcc.gov, and the policies, guidelines, and requirements in Part 1 of Title 47 of the Code of Federal Regulations, as well as the guidelines and suggestions for evaluating compliance in FCC OET Bulletin 65.   Health Canada limits for the general population. See the Health Canada web site at http://www.hc-sc.gc.ca/ewh-semt/pubs/radiation/99ehd-dhm237/limits-limites_e.html and Safety Code 6.  EN 50383:2002 Basic standard for the calculation and measurement of electromagnetic field strength and SAR related to human exposure from radio base stations and fixed terminal stations for wireless telecommunication systems (110 MHz - 40 GHz).  BS EN 50385:2002 Product standard to demonstrate the compliances of radio base stations and fixed terminal stations for wireless telecommunication systems with the basic restrictions or the reference levels related to human exposure to radio frequency electromagnetic fields (110 MHz – 40 GHz) – general public.  ICNIRP (International Commission on Non-Ionizing Radiation Protection) guidelines for the general public. See the ICNIRP web site at http://www.icnirp.de/ and Guidelines for Limiting Exposure to Time-Varying Electric, Magnetic, and Electromagnetic Fields. Power density exposure limit Install the radios for the PMP 450 family of PMP wireless solutions so as to provide and maintain the minimum separation distances from all persons.  The applicable power density exposure limit from the standards (see Human exposure to radio frequency energy on page 4-11) is:  10 W/m2 for RF energy in the 5.4-GHz and 5.8-GHz frequency bands.
Compliance with safety standards Reference information  4-12  pmp-0047 (June 2013)  Calculation of power density  The following calculation is based on the ANSI IEEE C95.1-1991 method, as that provides a worst case analysis.  Details of the assessment to EN50383:2002 can be provided, if required. Peak power density in the far field of a radio frequency point source is calculated as follows:    Where:  Is:   S  power density in W/m2  P  maximum average transmit power capability of the radio, in W  G  total Tx gain as a factor, converted from dB  d  distance from point source, in m  Rearranging terms to solve for distance yields:     Calculated distances and power compliance margins Table 38 shows calculated minimum separation distances, recommended distances and resulting margins for each frequency band and antenna combination. These are conservative distances that include compliance margins. At these and greater separation distances, the power density from the RF field is below generally accepted limits for the general population. PMP 450 equipment adheres to all applicable EIRP limits for transmit power when operating in MIMO mode.  Separation distances and compliance margins include compensation for both transmitters. Explanation of terms used in Table 38: Tx burst – maximum average transmit power in burst (Watt) P – maximum average transmit power capability of the radio (Watt) (combined transmitters) G – total transmit gain as a factor, converted from dB S – power density (W/m2) d – minimum distance from point source (meters) R – recommended distances (meters) C – compliance factor    24.dGPSSGPd.4.
PMP 450 Planning Guide Compliance with safety standards  pmp-0047 (June 2013)  4-13  Table 38  Power Compliance Margins  Freq. Band Antenna Variable d Recom-mended Separation Distance Power Compliance Margin P G S 2.4/5.4/5.8 GHz OFDM Integrated SM, 9 dBi patch 0.158 W (22 dBm) 7.9  (9 dB) 10 W/m2 or 1 mW/cm2 10 cm 20 cm (8 in) 40.27 Integrated SM, 9 dBi patch with 8 dBi CLIP (5 GHz only) 0.158 W (22 dBm) 50 (17 dB) 10 W/m2 or 1 mW/cm2 25 cm 50 cm (20 in) 39.7 Integrated SM, 9 dBi patch with 5.5 dBi LENS (5 GHz only) 0.158 W (22 dBm) 28 (14.5 dB) 10 W/m2 or 1 mW/cm2 18.7 cm 50 cm (20 in) 71.01 Integrated SM, 9 dBi patch with 14 dBi Reflector Dish 0.158 W (22 dBm) 199 (23 dB) 10 W/m2 or 1 mW/cm2 50 cm 100 cm (40 in)  40 Connectorized AP, with 17 dBi Sector Antenna 0.158 W (22 dBm) 50  (17 dB) 10 W/m2 or 1 mW/cm2 25.1 cm 50 cm (20 in)  39.8    Gain of antenna in dBi = 10*log(G). The regulations require that the power used for the calculations is the maximum power in the transmit burst subject to allowance for source-based time-averaging.
Compliance with safety standards Reference information  4-14  pmp-0047 (June 2013)  If there are no EIRP limits in the country of deployment, use the distance calculations for FCC 5.8 GHz for all frequency bands.
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-15  Compliance with radio regulations This section describes how the PMP 450 complies with the radio regulations that are enforced in various countries.  Changes or modifications not expressly approved by Cambium could void the user’s authority to operate the system.  Type approvals This system has achieved Type Approval in various countries around the world. This means that the system has been tested against various local technical regulations and found to comply. The frequency bands in which the system operates may be ‘unlicensed’ and, in these bands, the system can be used provided it does not cause interference. The system is not guaranteed protection against interference from other products and installations. Table 39 lists the radio specification type approvals that have been granted for PMP 450 frequency variants. Table 39  Radio certifications  Variant Region Specification (Type Approvals) 2.4-GHz PMP 450 Canada RSS Gen and RSS 210 USA FCC Part 15 Class B 5.4-GHz PMP 450 Europe ETSI EN 301 893 v1.6.1 USA FCC Part 15 Class B 5.8-GHz PMP 450 Canada RSS Gen and RSS 210 USA FCC Part 15 Class B Europe ETSI EN 302 502 v1.2.1
Compliance with radio regulations Reference information  4-16  pmp-0047 (June 2013)  DFS for 5.4 GHz Radios Dynamic Frequency Selection (DFS) is a requirement in several countries and regions for 5 GHz unlicensed systems to detect radar systems and avoid co-channel operation. DFS and other regulatory requirements drive the settings for the following parameters, as discussed in this section:   Country Code  Primary Frequency  Alternate 1 and Alternate 2 Frequencies  External Antenna Gain  On the AP, the Home => DFS Status” page shows current DFS status of all three frequencies and a DFS log of past DFS events.   Figure 27  AP DFS Status   Background and Operation The modules use region-specific DFS based on the Country Code selected on the module’s Configuration, General page.  By directing installers and technicians to set the Country Code correctly, the operator gains confidence the module is operating according to national or regional regulations without having to deal with the details for each region.  Some regions have requirements to avoid certain 5.4-GHz frequencies used by some weather radar. To meet this requirement, modules set to Europe will display the center channel frequencies shown in  Table 41  Center channel details based on Country Code, 2.4-GHz
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-17  OFDM Radio Model Country Channel Size Band Edges (MHz) Range of Center Frequencies Available (MHz) Center Channel Spacing # of Center Channels (based on PMP 450 available range) PMP 450 Series AP, 2.4-GHz United States, Canada 5 MHz 2400-2483.5 2402.5 – 2475 2.5 MHz 30 10 MHz 2405 – 2470 5 MHz 14 20 MHz 2417.5– 2457.5 5 MHz 9 PMP 450 Series SM, 2.4-GHz, Patch Antenna 5 MHz 2402.5 – 2475 2.5 MHz 30 10 MHz 2405 – 2470 5 MHz 14 20 MHz 2417.5– 2457.5 5 MHz 9 PMP 450 Series SM, 2.4-GHz, Dish Antenna 5 MHz 2407.5 – 2465 2.5 MHz 24 10 MHz 2420 – 2450 5 MHz 7 20 MHz 2430 – 2445 5 MHz 4 PMP 450 Series SM, 2.4-GHz, Panel Antenna 5 MHz 2402.5 – 2475 2.5 MHz 30 10 MHz 2405 – 2470 5 MHz 14 20 MHz 2420 - 2460 5 MHz 9   Table 42 on page 4-20 on the AP’s Carrier Frequency pop-up and on the SM’s Frequency Scan Selection List.  Table 40 on page 4-18 shows the details of DFS operation and channels available for each Country Code, including whether DFS is active on the AP, SM, which DFS regulation apply, and any channel restrictions. DFS does not apply to 4.9 GHz.
Compliance with radio regulations Reference information  4-18  pmp-0047 (June 2013)  Table 40  OFDM DFS operation based on Country Code setting  Region Country Band AP SM Weather Radar Notch-Out Oceania Australia 5.4-GHz FCC DFS No effect Yes 5.8-GHz No effect No effect No Europe Denmark, Finland, Germany, Greece, Iceland, Ireland, Liechtenstein, Norway, Portugal, Serbia, Spain, Switzerland, United Kingdom 5.4-GHz ETSI EN 301 893 v1.6.1 DFS ETSI EN 301 893 v1.6.1 DFS Yes 5.8-GHz ETSI EN 302 502 v1.2.1 DFS ETSI EN 302 502 v1.2.1 DFS No South America Brazil 5.4-GHz ETSI EN 301 893 v1.6.1 DFS No effect No 5.8-GHz No effect No effect No North America Canada 2.4-GHz No effect No effect No 5.4-GHz FCC/IC DFS No effect Yes 5.8-GHz No effect No effect No United States 2.4GHz No effect No effect No 5.4-GHz FCC  DFS No effect Yes 5.8-GHz No effect No effect No Other-Regulatory  Other-FCC 5.4-GHz FCC DFS FCC DFS No 5.8-GHz No effect No effect No Other-ETSI 5.4-GHz ETSI EN 301 893 v1.6.1 DFS ETSI EN 301 893 v1.6.1 DFS No 5.8-GHz ETSI EN 302 502 v1.2.1 DFS ETSI EN 302 502 v1.2.1 DFS No
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-19    Country Codes and available spectrum Table 41, Table 42, and Table 43 list the Country Codes available on PMP 450 AP and SM units.  Country Code settings affect the radios in the following ways:  Maximum transmit power limiting (based on radio transmitter power plus configured antenna gain)  DFS operation is enabled based on the configured region code, if applicable PMP 450 equipment shipped to the United States is locked to a Country Code setting of “United States”.  Units shipped to regions other than the United States must be configured with the corresponding Country Code to comply with local regulatory requirements.
Compliance with radio regulations Reference information  4-20  pmp-0047 (June 2013)  Table 41  Center channel details based on Country Code, 2.4-GHz OFDM Radio Model Country Channel Size Band Edges (MHz) Range of Center Frequencies Available (MHz)§ Center Channel Spacing # of Center Channels (based on PMP 450 available range) PMP 450 Series AP, 2.4-GHz United States, Canada 5 MHz 2400-2483.5 2402.5 – 2475 2.5 MHz 30 10 MHz 2405 – 2470 5 MHz 14 20 MHz 2417.5– 2457.5 5 MHz 9 PMP 450 Series SM, 2.4-GHz, Patch Antenna 5 MHz 2402.5 – 2475 2.5 MHz 30 10 MHz 2405 – 2470 5 MHz 14 20 MHz 2417.5– 2457.5 5 MHz 9 PMP 450 Series SM, 2.4-GHz, Dish Antenna 5 MHz 2407.5 – 2465 2.5 MHz 24 10 MHz 2420 – 2450 5 MHz 7 20 MHz 2430 – 2445 5 MHz 4 PMP 450 Series SM, 2.4-GHz, Panel Antenna 5 MHz 2402.5 – 2475 2.5 MHz 30 10 MHz 2405 – 2470 5 MHz 14 20 MHz 2420 - 2460 5 MHz 9                                                              § For each edge frequency, transmit power must be reduced by 3 dB.
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-21  Table 42  Center channel details based on Country Code, 5.4-GHz OFDM Radio Model Country Channel Size Band Edges (MHz) Range of Center Frequencies Available (MHz) Center Channel Spacing # of Center Channels (based on PMP 450 available range, weather notch-out) PMP 450 Series AP, 5.4-GHz Brazil 10 MHz 5470 – 5725 5475 – 5720 5 MHz 50 20 MHz 5480 – 5715 5 MHz 48 Australia, Denmark, Finland, Germany, Greece, Iceland, Ireland, Liechtenstein, Norway, Portugal, Serbia, Spain, Switzerland, United Kingdom  10 MHz 5470 – 5600; 5650 - 5725 5475 – 5595; 5655 - 5720** 5 MHz 39 20 MHz 5480 – 5590; 5660 – 5710** 5 MHz 34 United States, Canada 10 MHz 5470 – 5600; 5650 – 5725 5475 – 5595; 5655 - 5720 5 MHz 39 20 MHz 5480 – 5590; 5660 – 5715 5 MHz 35 Other 10 MHz 5470 – 5725 5475 - 5720 5 MHz 50 20 MHz 5480 – 5715 5 MHz 48     Table 43  Center channel details based on Country Code, 5.8-GHz                                                            ** Frequencies 5600 – 5650 MHz are excluded, as ten minute Channel Availability Check is required
Compliance with radio regulations Reference information  4-22  pmp-0047 (June 2013)  OFDM Radio Model Country Channel Size Band Edges (MHz) Range of Center Frequencies Available (MHz) Center Channel Spacing # of Center Channels (based on PMP 450 available range, weather notch-out) PMP 450 Series AP, 5.8-GHz Denmark, Norway, United Kingdom, Finland 10 MHz 5725 – 5795; 5815 – 5850 5730 – 5790; 5820 – 5845 5 MHz 19 20 MHz 5735 – 5785; 5825 – 5840 5 MHz 15 Germany 10 MHz 5755 – 5875; 5760 – 5870 5 MHz 23 20 MHz 5765 – 5865 5 MHz 21 Spain 10 MHz 5725 – 5795; 5815 – 5855 5730- 5790; 5820 – 5850 5 MHz 20 20 MHz 5735 – 5785; 5825 – 5845 5 MHz 16 Greece 10 MHz 5725 – 5795 5730 – 5790 5 MHz 13 20 MHz 5735 – 5785 5 MHz 11 Portugal, Iceland, Serbia 10 MHz 5725 – 5875 5730 – 5870 5 MHz 29 20 MHz 5735 – 5865 5 MHz 27 Switzerland, Liechtenstein 10 MHz 5725 – 5795; 5815 – 5875 5730 – 5790; 5820 – 5870 5 MHz 24 20 MHz 5735 – 5785; 5825 – 5865 5 MHz 20 Australia, Canada, United States 10 MHz 5725 - 5850 5730 – 5845 5 MHz 24 20 MHz 5735 – 5840 5 MHz 22
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-23   Table 44  AP Default combined transmit power per Country Code – 2.4-GHz band  Country Ant. Gain (dBi) (18 dBi – 1dB cable loss) Comb. TX Default Setting AP EIRP Limit Comb. TX Default Setting AP EIRP Limit Comb. TX Default Setting AP EIRP Limit Device Country Code Setting 5 MHz Channel Bandwidth (dBm) 10 MHz Channel Bandwidth (dBm) 20 MHz Channel Bandwidth (dBm) Canada 17 19 36 19 36 19 36 Canada United States 17 19 36 19 36 19 36 United States    Lower Band Edge Frequency (MHz) Path A Max TX Power Path B Max TX Power  AP                          5 MHz 2402.5 16 16 10 MHz 2405 15 14 20 MHz 2417.5 15 15  SM    5 MHz 2402.5 15 15 10 MHz 2405 15 15 20 MHz 2417.5 18 18   Upper Band Edge Frequency (MHz) Path A Max TX Power Path B Max TX Power  AP                          5 MHz 2475 16 16 10 MHz 2470 15 14
Compliance with radio regulations Reference information  4-24  pmp-0047 (June 2013)  20 MHz 2457.5 15 15  SM    5 MHz 2475 15 15 10 MHz 2470 15 15 20 MHz 2457.5 18 18
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-25  Table 45  Default combined transmit power per Country Code – 5.4-GHz band Country Antenna Gain (dBi) (18 dBi – 1dB cable loss) Combined TX Default Setting AP EIRP Limit Combined TX Default Setting AP EIRP Limit Device Country Code Setting 10 MHz Channel Bandwidth (dBm) 20 MHz Channel Bandwidth (dBm) United States, Canada 17 10 27 13 30  United States, Canada Brazil 17 10 27 13 30  Brazil Australia 17 10 27 13 30  Australia Austria, Belgium, Bosnia & Herzegovina, Bulgaria, Croatia, Cyprus, Czech Republic, France, , Hungary, Ireland, Italy, Latvia, Lithuania, Luxembourg, Macedonia, Malta, Netherlands, Poland, Romania, Slovakia,  Slovenia , Sweden  17 10 27‡‡ 13 30  Other-ETSI Denmark 17 10 27 13 30 Denmark Finland 17 10 27 13 30 Finland Germany 17 10 27 13 30 Germany Greece 17 10 27 13 30 Greece                                                            ‡‡ At 5.4 GHz, EU regulations are harmonized. 5600 – 5650 MHz excluded, as ten minute Channel Availability Check (CAC) is required
Compliance with radio regulations Reference information  4-26  pmp-0047 (June 2013)  Country Antenna Gain (dBi) (18 dBi – 1dB cable loss) Combined TX Default Setting AP EIRP Limit Combined TX Default Setting AP EIRP Limit Device Country Code Setting 10 MHz Channel Bandwidth (dBm) 20 MHz Channel Bandwidth (dBm) Liechtenstein 17 10 27 13 30 Liechtenstein Norway 17 10 27 13 30 Norway Portugal 17 10 27 13 30 Portugal Spain 17 10 27 13 30 Spain United Kingdom 17 10 27 13 30 United Kingdom Other 17 19 No EIRP / Conducted power limit 19 No EIRP / Conducted power limit Other   Table 46  Default combined transmit power per Country Code – 5.8-GHz band   Country Antenna Gain (dBi) (18 dBi – 1dB cable loss) Combined TX Default Setting AP EIRP Limit Combined TX Default Setting AP EIRP Limit Device Country Code Setting 10 MHz Channel Bandwidth (dBm) 20 MHz Channel Bandwidth (dBm) Australia 17 16 36 19 36 Australia Brazil 17 13 27 13 30 Brazil Canada 17 16 36 (SM EIRP Limit=53) 19 36 (SM EIRP Limit=53) Canada Denmark 17 16 33 19 36 Denmark Finland 17 16 33 19 36 Finland Germany 17 16 33 19 36 Germany Greece 17 16 33 19 36 Greece India 17 16 36 19 36 India
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-27  Country Antenna Gain (dBi) (18 dBi – 1dB cable loss) Combined TX Default Setting AP EIRP Limit Combined TX Default Setting AP EIRP Limit Device Country Code Setting 10 MHz Channel Bandwidth (dBm) 20 MHz Channel Bandwidth (dBm) Iceland 17 16 33 19 36 Iceland Indonesia 17 16 36 19 36 Indonesia Ireland 17 13 30 16 33 Ireland Liechtenstein 17 16 33 19 36 Liechtenstein Norway 17 16 33 (SM EIRP Limit=50)  19 36 (SM EIRP Limit=53) Norway Portugal 17 16 33 19 36 Portugal Serbia 17 16 33 19 36 Serbia Spain 17 16 33 19 36 Spain Switzerland 17 16 33 19 36 Switzerland United Kingdom 17 16 33 19 36 United Kingdom United States 17 16 33 (SM EIRP Limit=50) 19 36 (SM EIRP Limit=53) United States   After an AP with DFS is powered on it performs a channel availability check on its main carrier frequency for 1 minute, monitoring for the radar signature without transmitting. If no radar signature is detected during this minute, the module then proceeds to normal beacon transmit mode. If it does detect a radar signature, the frequency is marked for a 30 minute non-occupancy period, and the module moves to its 1st alternate carrier frequency. The AP continues this behavior through its 2nd alternate frequency if needed and then waits until the first frequency ends the 30 minute non-occupancy period.  While operating, if the AP detects a weather radar signature it marks the current carrier frequency for a 30 minute non-occupancy period and moves to check the next-in-line carrier frequency.  An SM does not begin transmission until it detects a beacon from an AP. If APs are not transmitting, SMs will be silent.
Compliance with radio regulations Reference information  4-28  pmp-0047 (June 2013)  Europe applies the ETSI specification to both APs  and SMs, while Brazil applies it only to APs. In the ETSI case, when an SM is powered on, it scans to find a Canopy beacon from a AP. If an AP  is found, the SM performs a channel availability check on that frequency for 1 minute, monitoring for the radar signature, without transmitting. A DFS decision is made based on the following:   If no radar pulse is detected during this 1 minute, the SM proceeds through normal steps to register to an AP.  If the SM does detect radar, it locks out that frequency for 30 minutes and continues scanning other frequencies in its scan list.  After an SM with DFS has seen a radar signature on a frequency and locked out that frequency, it may connect to a different AP if color codes, AP transmitting frequencies, and SM scanned frequencies support that connection.  To simplify operation and ensure compliance, an SM takes on the DFS type of the AP to which it registers. For example, when an SM in Europe registers to an AP with the Country Code set to “United Kingdom”, that SM will use ETSI DFS, no matter what its Country Code is set to, even if its Country Code is set to “None”. Note, the operator should still configure the Country Code in the SM correctly, as future releases may use the Country Code for additional region-specific options.   For all modules running DFS, the module displays its DFS state on its Home => General Status page as one of the following:  Checking Channel Availability Remaining time n seconds, where n counts down from 60 to 1.  Normal Transmit  Radar Detected Stop Transmitting for n minutes, where n counts down from 30 to 1.  Idle, only for SM/BHS, indicates module is scanning, but has not detected a beacon from an AP/BHM. Once it detects beacon, the SM/BHS begins a Channel Availability Check on that frequency.   Regulatory Note: A PMP 450 Series AP with a Country Code set to United States will not be configurable to another Country Code by installers or end users. This is in response to FCC KDB 594280 and ensures that end users and professional installers will not have access to settings which could allow a radio to be configured to operate in a manner other than that which was specified in the FCC equipment authorization grant.  Within the United States and its territories the PMP 450 Country Code is pre-configured to United States and not selectable in the Configuration, General web page. Radios sold in regions outside of the United States and its territories are required to set the Country Code to the region in which it is used.
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-29  FCC compliance testing With  GPS synchronization installed, the system has been tested for compliance to US (FCC) specifications. It has been shown to comply with the limits for emitted spurious radiation for a Class B digital device, pursuant to Part 15 of the FCC Rules in the USA. These limits have been designed to provide reasonable protection against harmful interference. However the equipment can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to other radio communications. There is no guarantee that interference will not occur in a particular installation.  A Class B Digital Device is a device that is marketed for use in a residential environment, notwithstanding use in commercial, business and industrial environments.   Notwithstanding that Cambium has designed (and qualified) the PMP 450 products to generally meet the Class B requirement to minimize the potential for interference, the PMP 450 product range is not marketed for use in a residential environment.  FCC and ICC IDs and certification numbers Table 47  US FCC IDs and Industry Canada Certification Numbers and Covered Configurations  FCC ID   Industry Canada Cert Number Module Families Frequencies Antenna (OFDM) Maximum Combined Tx Output Power Z8H89FT0004 109W-0004 PMP 450 AP 2.4-GHz 20 MHz channels, centered on 2420 – 2463.5 in 5 MHz increments (within the 2400 – 2483.5 MHz ISM band) 17 dBi Connectorized 19 dBm 10 MHz channels, centered on 2410 – 2473.5 in 5 MHz increments (within the 2400 – 2483.5 MHz ISM band) 5 MHz channels, centered on 2405 – 2478.5 in 2.5 MHz increments (within the 2400 – 2483.5 MHz ISM band)
Compliance with radio regulations Reference information  4-30  pmp-0047 (June 2013)  FCC ID   Industry Canada Cert Number Module Families Frequencies Antenna (OFDM) Maximum Combined Tx Output Power Z8H89FT0002 109W-0002 PMP 450 AP 5.8-GHz 20 MHz channels, centered on 5735-5840 in 5 MHz increments (within the 5725-5850 MHz ISM band) 17 dBi Connectorized 19 dBm 10 MHz channels, centered on 5730-5845 in 5 MHz increments (within the 5725-5850 MHz ISM band) 5 MHz channels, centered on 5725-5850 in 2.5 MHz increments (within the 5725-5850 MHz ISM band) Z8H89FT0002 109W-0002 PMP 450 AP 5.4-GHz 20 MHz channels, centered on 5480 – 5590; 5660 – 5715  in 5 MHz increments (within the 5470 – 5600; 5650 – 5725 MHz UNII band) 17 dBi Connectorized 13 dBm 10 MHz channels, centered on 5475 – 5595; 5655 – 5720  in 5 MHz increments (within the 5470 – 5600; 5650 – 5725 MHz UNII band) 10 dBm 5 MHz channels, centered on 5470 – 5600; 5650 – 5725 in 2.5 MHz increments (within the 5470 – 5600; 5650 – 5725 MHz UNII band) 7 dBm Z8H89FT0003 109W-0003 PMP 450 SM 2.4-GHz 20 MHz channels, centered on 2420 – 2463.5 in 5 MHz increments (within the 2400 – 2483.5 MHz ISM band) 8 dBi Integrated 19 dBm 8 dBi Integrated with 12 dBi Reflector Dish 16 dBm 14 dBi Connectorized 19 dBm 10 MHz channels, centered on 2410 – 2473.5 in 5 MHz increments (within the 2400 – 2483.5 MHz ISM band) 8 dBi Integrated 19 dBm 8 dBi Integrated with 12 dBi Reflector Dish 16 dBm
PMP 450 Planning Guide Compliance with radio regulations  pmp-0047 (June 2013)  4-31  FCC ID   Industry Canada Cert Number Module Families Frequencies Antenna (OFDM) Maximum Combined Tx Output Power 14 dBi Connectorized 19 dBm 5 MHz channels, centered on 2405 – 2478.5 in 2.5 MHz increments (within the 2400 – 2483.5 MHz ISM band) 8 dBi Integrated 19 dBm 8 dBi Integrated with 12 dBi Reflector Dish 16 dBm 14 dBi Connectorized 19 dBm Z8H89FT0001 109W-0001 PMP 450 SM 5.8-GHz 20 MHz channels, centered on 5735-5840 in 5 MHz increments (within the 5725-5850 MHz ISM band) 9 dBi Integrated 19 dBm 9 dBi Integrated with 14 dBi Reflector Dish 9 dBi Integrated with 5.5 dBi LENS 9 dBi Integrated with 8 dBi CLIP 10 MHz channels, centered on 5730-5845 in 5 MHz increments (within the 5725-5850 MHz ISM band) 9 dBi Integrated 19 dBm 9 dBi Integrated with 14 dBi Reflector Dish 9 dBi Integrated with 5.5 dBi LENS 9 dBi Integrated with 8 dBi CLIP 5 MHz channels, centered on 5725-5845 in 2.5 MHz increments (within the 5725-5850 MHz ISM band) 9 dBi Integrated 19 dBm 9 dBi Integrated with 14 dBi Reflector Dish
 Reference information  4-32  pmp-0047 (June 2013)  FCC ID   Industry Canada Cert Number Module Families Frequencies Antenna (OFDM) Maximum Combined Tx Output Power 9 dBi Integrated with 5.5 dBi LENS 9 dBi Integrated with 8 dBi CLIP Z8H89FT0001 109W-0001 PMP 450 SM 5.4-GHz 20 MHz channels, centered on 5480 – 5590; 5660 – 5715  in 5 MHz increments (within the 5470 – 5600; 5650 – 5725 MHz UNII band) 9 dBi Integrated 11 dBm 9 dBi Integrated with 14 dBi Reflector Dish 7 dBm 9 dBi Integrated with 5.5 dBi LENS 15 dBm 9 dBi Integrated with 8 dBi CLIP 13 dBm 10 MHz channels, centered on 5475 – 5595; 5655 – 5720  in 5 MHz increments (within the 5470 – 5600; 5650 – 5725 MHz UNII band) 9 dBi Integrated 10 dBm 9 dBi Integrated with 14 dBi Reflector Dish 4 dBm 9 dBi Integrated with 5.5 dBi LENS 12 dBm 9 dBi Integrated with 8 dBi CLIP 10 dBm
PMP 450 Planning Guide Notifications  pmp-0047 (June 2013)  4-33  Notifications This section contains notifications of compliance with the radio regulations that are enforced in various regions. PMP 450 regulatory compliance The PMP 450 complies with the regulations that are enforced in the USA and Canada. The relevant notifications are specified in this section. PMP 450 FCC and IC notification U.S. Federal Communication Commission (FCC) and Industry Canada (IC) Notification. This system has achieved Type Approval in various countries around the world. This means that the system has been tested against various local technical regulations and found to comply. The frequency band in which the system operates is ‘license exempt’ and the system is allowed to be used provided it does not cause interference. The licensing authority does not guarantee protection against interference from other products and installations. This device complies with part 15 of the US FCC Rules and Regulations and with RSS-210 of Industry Canada.  Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) This device must accept any interference received, including interference that may cause undesired operation. In Canada, users should be cautioned to take note that high power radars are allocated as primary users (meaning they have priority) of the 5650 – 5850 MHz spectrum and these radars could cause interference and/or damage to license-exempt local area networks (LELAN). Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. L'exploitation est autorisée aux deux conditions suivantes : (1) l'appareil ne doit pas produire de brouillage, et (2) l'utilisateur de l'appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement. Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (EIRP) is not more than that necessary for successful communication. Conformément à la réglementation d'Industrie Canada, le présent émetteur radio peut fonctionner avec une antenne d'un type et d'un gain maximal (ou inférieur) approuvé pour l'émetteur par Industrie Canada. Dans le but de réduire les risques de brouillage radioélectrique à l'intention des autres utilisateurs, il faut choisir le type d'antenne et son gain de sorte que la puissance isotrope rayonnée équivalente (PIRE) ne dépasse pas l'intensité nécessaire à l'établissement d'une communication satisfaisante. This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the US FCC Rules and with RSS-210 of Industry Canada.  These limits are designed to provide reasonable protection against harmful interference in a residential installation.  This equipment generates, uses, and can radiate radio-frequency energy and, if not installed and used in accordance with these instructions, may cause harmful interference to radio communications. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment on and off, the user is encouraged to correct the interference by one or more of the following measures:
Notifications Reference information  4-34  pmp-0047 (June 2013)   Increase the separation between the affected equipment and the unit;  Connect the affected equipment to a power outlet on a different circuit from that which the receiver is connected to;  Consult the dealer and/or experienced radio/TV technician for help.  Where necessary, the end user is responsible for obtaining any National licenses required to operate this product and these must be obtained before using the product in any particular country. Contact the appropriate national administrations for details on the conditions of use for the bands in question and any exceptions that might apply. This radio transmitter (identify the device by certification number, or model number if Category II) has been approved by Industry Canada to operate with the antenna types listed below with the maximum permissible gain and required antenna impedance for each antenna type indicated. Antenna types not included in this list, having a gain greater than the maximum gain indicated for that type, are strictly prohibited for use with this device. Le présent émetteur radio (identifier le dispositif par son numéro de certification ou son numéro de modèle s'il fait partie du matériel de catégorie I) a été approuvé par Industrie Canada pour fonctionner avec les types d'antenne énumérés ci-dessous et ayant un gain admissible maximal et l'impédance requise pour chaque type d'antenne. Les types d'antenne non inclus dans cette liste, ou dont le gain est supérieur au gain maximal indiqué, sont strictement interdits pour l'exploitation de l'émetteur. Table 48  Industry Canada approved antenna list Approved Antenna Model Description Input Impedance <2.4 GHz AP antenna – 60 degree sector model #> 2.4 GHz Dual Slant Antenna for 60 Degree Sector, 17 dBi 50 Ω 85009324001 5 GHz Dual Slant Antenna for 90 Degree Sector, 17 dBi 50 Ω 85009325001 5 GHz Dual Slant Antenna for 60 Degree Sector, 17 dBi 50 Ω <2.4 GHz Connectorized SM Antenna Model #> 2.4 GHz Subscriber Module Panel Antenna, 14 dBi 50 Ω   Equipment Disposal   Waste (Disposal) of Electronic and Electric Equipment Please do not dispose of Electronic and Electric Equipment or Electronic and Electric Accessories with your household waste. In some countries or regions, collection systems have been set up to handle waste of electrical and electronic equipment. In European Union countries, please contact your local equipment supplier representative or service center for information about the waste collection system in your country.
PMP 450 Planning Guide Notifications  pmp-0047 (June 2013)  4-35  European Union Notification for 5.4 and 5.8 GHz Product The 5.4 and 5.8 GHz connectorized product is a two-way radio transceiver suitable for use in Broadband Wireless Access System (WAS), Radio Local Area Network (RLAN), or Fixed Wireless Access (FWA) systems. It is a Class 2 device and uses operating frequencies that are not harmonized throughout the EU member states. The operator is responsible for obtaining any national licenses required to operate this product and these must be obtained before using the product in any particular country. Hereby, Cambium declares that the 5.4 and 5.8 GHz product complies with the essential requirements and other relevant provisions of Directive 1999/5/EC.  The relevant Declaration of Conformity can be found at http://www.cambiumnetworks.com/doc.php. This equipment is marked   to show compliance with the European R&TTE directive 1999/5/EC.  Regulatory Requirements for CEPT Member States (www.cept.org) When operated in accordance with the instructions for use, Cambium Wireless equipment operating in the 5.4 GHz bands is compliant with CEPT Recommendation 70-03 Annex 3 for Wideband Data Transmission and HIPERLANs. For compliant operation in the 5.4 GHz band, the transmit power (EIRP) from the integrated antenna or a connectorized antenna shall be no more than 0.5 W (27 dBm). For EU member states, RLAN equipment in the 5.4GHz bands is exempt from individual licensing under Commission Recommendation 2003/203/EC. Contact the appropriate national administrations for details on the conditions of use for the bands in question and any exceptions that might apply. Also see www.ero.dk for further information. 10 MHz channels are used, centered on 5475 to 5595 and 5655 to 5715 in 5 MHz increments. This is within the 5470 to 5725 MHz U-NII band with 5600 to 5650 MHz excluded. Cambium Radio equipment operating in the 5470 to 5725 MHz band are categorized as “Class 1” devices within the EU in accordance with ECC DEC(04)08 and are “CE” marked    to show compliance with the European Radio & Telecommunications Terminal Equipment (R&TTE) directive 1999/5/EC. The relevant Declaration of Conformity can be found at http://www.cambiumnetworks.com/doc.php.  A European Commission decision, implemented by Member States on 31 October 2005, makes the frequency band 5470-5725 MHz available in all EU Member States for wireless access systems. Under this decision, the designation of Canopy 5.4GHz products become “Class 1 devices” and these do not require notification under article 6, section 4 of the R&TTE Directive. Consequently, these 5.4GHz products are only marked with the  symbol and may be used in any member state.
Notifications Reference information  4-36  pmp-0047 (June 2013)  UK Notification The 5.8 GHz connectorized product has been notified for operation in the UK, and when operated in accordance with instructions for use it is compliant with UK Interface Requirement IR2007. For UK use, installations must conform to the requirements of IR2007 in terms of EIRP spectral density against elevation profile above the local horizon in order to protect Fixed Satellite Services. The frequency range 5795-5815 MHz is assigned to Road Transport & Traffic Telematics (RTTT) in the U.K. and shall not be used by FWA systems in order to protect RTTT devices. UK licensing specifies that radiolocation services shall be protected by a Dynamic Frequency Selection (DFS) mechanism to prevent co-channel operation in the presence of radar signals. Brazil Notification For compliant operation in the 5.4 GHz band, the Equivalent Isotropic Radiated Power from the integrated antenna or connectorized antenna shall not exceed 27 dBm (0.5 W). The operator is responsible for enabling the DFS feature on any Canopy 5.4 GHz radio by setting the Region Code to “Brazil”, including after the module is reset to factory defaults. Important Note: This equipment operates as a secondary application, so it has no rights against harmful interference, even if generated by similar equipment, and cannot cause harmful interference on systems operating as primary applications. Luxembourg Notification 5.4GHz products can only be used for mobile services. Czech Republic Notification 5.4 GHz products can be operated in accordance with the Czech General License No. GL-30/R/2000. Italy Notification In Italy, there is a regulation which requires a general authorization of any 5.4 GHz radio link which is used outside the operator’s own premises. It is the responsibility of the installer or operator to have the link authorized. Details may be found at:  http://www.sviluppoeconomico.gov.it/index.php?option=com_content&view=article&idmenu=672&idarea1=593&andor=AND&idarea2=1052&id=68433&sectionid=1,16&viewType=1&showMenu=1&showCat=1&idarea3=0&andorcat=AND&partebassaType=0&idareaCalendario1=0&MvediT=1&idarea4=0&showArchiveNewsBotton=0&directionidUser=0  The form to be used for general authorization may be found at:  http://www.sviluppoeconomico.gov.it/images/stories/mise_extra/Allegato%20n19.doc
PMP 450 Planning Guide Glossary   pmp-0047 (June 2013)  I  Appendix A:  Glossary Table 49  Glossary  Term Definition 10Base-T Technology in Ethernet communications that can deliver 10 Mb of data across 328 feet (100 meters) of CAT 5 cable. 169.254.0.0 Gateway IP address default in Cambium fixed wireless broadband IP network modules. 169.254.1.1 IP address default in Cambium fixed wireless broadband IP network modules. 255.255.0.0 Subnet mask default in Cambium fixed wireless broadband IP network modules and in Microsoft and Apple operating systems. 802.3 An IEEE standard that defines the contents of frames that are transferred through Ethernet connections. Each of these frames contains a preamble, the address to which the frame is sent, the address that sends the frame, the length of the data to expect, the data, and a checksum to validate that no contents were lost. 802.11 The IEEE standard for wireless local area networks. 802.15 The IEEE standard for wireless personal area networks. Access Point Cluster Two to six Access Point Modules that together distribute network or Internet services to a community of subscribers. Each Access Point Module covers a 60° or 90° sector. This cluster covers as much as 360°. Also known as AP cluster. Access Point Module Also known as AP. One module that distributes network or Internet services in a 60° or 90° sector. ACT/4 Second-from-left LED in the module. In the operating mode, this LED is lit when data activity is present on the Ethernet link. Activate To provide feature capability to a module, but not to enable (turn on) the feature in the module. See also Enable. Address Resolution Protocol Protocol defined in RFC 826 to allow a network element to correlate a host IP address to the Ethernet address of the host. See http://www.faqs.org/rfcs/rfc826.html. Aggregate Throughput The sum of the throughputs in the uplink and the downlink. AP Access Point Module. One module that distributes network or Internet services to subscriber modules.
PMP 450 Planning Guide Glossary  II  pmp-0047 (June 2013)  Term Definition APs MIB Management Information Base file that defines objects that are specific to the Access Point Module. See also Management Information Base. ARP Address Resolution Protocol. A protocol defined in RFC 826 to allow a network element to correlate a host IP address to the Ethernet address of the host. See http://www.faqs.org/rfcs/rfc826.html. ASN.1 Abstract Syntax Notation One language. The format of the text files that compose the Management Information Base. Attenuation Reduction of signal strength caused by the travel from the transmitter to the receiver, and caused by any object between. In the absence of objects between, a signal that has a short wavelength experiences a high degree of attenuation nevertheless. BER Bit Error Rate. The ratio of incorrect data received to correct data received. Bit Error Rate Ratio of incorrect data received to correct data received. Box MIB Management Information Base file that defines module-level objects. See also Management Information Base. Bridge Network element that uses the physical address (not the logical address) of another to pass data. The bridge passes the data to either the destination address, if found in the simple routing table, or to all network segments other than the one that transmitted the data. Modules are Layer 2 bridges except that, where NAT is enabled for an SM, the SM is a Layer 3 switch. Compare to Switch and Router, and see also NAT. Bridge Entry Timeout Field Value that the operator sets as the maximum interval for no activity with another module, whose MAC address is the Bridge Entry. This interval should be longer than the ARP (Address Resolution Protocol) cache timeout of the router that feeds the network. Buckets Theoretical data repositories that can be filled at preset rates or emptied when preset conditions are experienced, such as when data is transferred. Burst Preset amount limit of data that may be continuously transferred. C/I Ratio Ratio of intended signal (carrier) to unintended signal (interference) received. Carrier-to-interference Ratio Ratio of intended reception to unintended reception. CarSenseLost Field This field displays how many carrier sense lost errors occurred on the Ethernet controller.  CAT 5 Cable Cable that delivers Ethernet communications from module to module. Later modules auto-sense whether this cable is wired in a straight-through or crossover scheme.
PMP 450 Planning Guide Glossary  pmp-0047 (June 2013)  III  Term Definition CIR Committed Information Rate.  For an SM or specified group of SMs, a level of bandwidth that can be guaranteed to never fall below a specified minimum (unless oversubscribed). In the Cambium implementation, this is controlled by the Low Priority Uplink CIR, Low Priority Downlink CIR, High Priority Uplink CIR, and High Priority Downlink CIR parameters. CLIP Cassegrain Lens for Improved Performance Cluster Management Module Module that provides power, GPS timing, and networking connections for an AP cluster. Also known as CMM. CMM Cluster Management Module. A module that provides power, GPS timing, and networking connections for an Access Point cluster. CodePoint See DiffServ. Color Code Field Module parameter that identifies the other modules with which communication is allowed. The range of valid values is 0 to 255. Community String Field Control string that allows a network management station to access MIB information about the module. CRCError Field This field displays how many CRC errors occurred on the Ethernet controller. Data Encryption Standard Over-the-air link option that uses secret 56-bit keys and 8 parity bits. Data Encryption Standard (DES) performs a series of bit permutations, substitutions, and recombination operations on blocks of data. Demilitarized Zone Internet Protocol area outside of a firewall. Defined in RFC 2647. See http://www.faqs.org/rfcs/rfc2647.html. DES Data Encryption Standard. An over-the-air link option that uses secret 56-bit keys and 8 parity bits. DES performs a series of bit permutations, substitutions, and recombination operations on blocks of data. Desensed Received an undesired signal that was strong enough to make the module insensitive to the desired signal. DFS See Dynamic Frequency Selection DHCP Dynamic Host Configuration Protocol, defined in RFC 2131. Protocol that enables a device to be assigned a new IP address and TCP/IP parameters, including a default gateway, whenever the device reboots. Thus DHCP reduces configuration time, conserves IP addresses, and allows modules to be moved to a different network within the system. See http://www.faqs.org/rfcs/rfc2131.html. See also Static IP Address Assignment.
PMP 450 Planning Guide Glossary  IV  pmp-0047 (June 2013)  Term Definition DiffServ Differentiated Services, consistent with RFC 2474. A byte in the type of service (TOS) field of packets whose values correlates to the channel on which the packet should be sent. The value is a numeric code point. Cambium modules map each of 64 code points to values of 0 through 7. Three of these code points have fixed values, and the remaining 61 are settable. Values of 0 through 3 map to the low-priority channel; 4 through 7 to the high-priority channel. The mappings are the same as 802.1p VLAN priorities. (However, configuring DiffServ does not automatically enable the VLAN feature.) Among the settable parameters, the values are set in the AP for all downlinks within the sector and in the SM for each uplink. Disable To turn off a feature in the module after both the feature activation file has activated the module to use the feature and the operator has enabled the feature in the module. See also Activate and Enable. DMZ Demilitarized Zone as defined in RFC 2647. An Internet Protocol area outside of a firewall. See http://www.faqs.org/rfcs/rfc2647.html. Dynamic Frequency Selection A requirement in certain countries and regions for systems to detect interference from other systems, notably radar systems, and to avoid co-channel operation with these systems. Dynamic Host Configuration Protocol See DHCP.  Electronic Serial Number Hardware address that the factory assigns to the module for identification in the Data Link layer interface of the Open Systems Interconnection system. This address serves as an electronic serial number. Same as MAC Address. Enable To turn on a feature in the module after the feature activation file has activated the module to use the feature. See also Activate. ESN Electronic Serial Number. The hardware address that the factory assigns to the module for identification in the Data Link layer interface of the Open Systems Interconnection system. This address serves as an electronic serial number. Same as MAC Address. EthBusErr Field This field displays how many Ethernet bus errors occurred on the Ethernet controller. Ethernet Protocol Any of several IEEE standards that define the contents of frames that are transferred from one network element to another through Ethernet connections. Fade Margin The difference between strength of the received signal and the strength that the receiver requires for maintaining a reliable link. A higher fade margin is characteristic of a more reliable link. Standard operating margin. FCC Federal Communications Commission of the U.S.A. Field-programmable Gate Array Array of logic, relational data, and wiring data that is factory programmed and can be reprogrammed.
PMP 450 Planning Guide Glossary  pmp-0047 (June 2013)  V  Term Definition File Transfer Protocol Utility that transfers of files through TCP (Transport Control Protocol) between computing devices that do not operate on the same platform. Defined in RFC 959. See http://www.faqs.org/rfcs/rfc959.html. FPGA Field-programmable Gate Array. An array of logic, relational data, and wiring data that is factory programmed and can be reprogrammed. Frame Timing Pulse Gated Field Toggle parameter that prevents or allows the module to continue to propagate GPS sync timing when the module no longer receives the timing. Free Space Path Loss Signal attenuation that is naturally caused by atmospheric conditions and by the distance between the antenna and the receiver. Fresnel Zone Space in which no object should exist that can attenuate, diffract, or reflect a transmitted signal before the signal reaches the target receiver.  FTP File Transfer Protocol, defined in RFC 959. Utility that transfers of files through TCP (Transport Control Protocol) between computing devices that do not operate on the same platform. See http://www.faqs.org/rfcs/rfc959.html. Global Positioning System Network of satellites that provides absolute time to networks on earth, which use the time signal to synchronize transmission and reception cycles (to avoid interference) and to provide reference for troubleshooting activities. GPS Global Positioning System. A network of satellites that provides absolute time to networks on earth, which use the time signal to synchronize transmission and reception cycles (to avoid interference) and to provide reference for troubleshooting activities.  GPS/3 Third-from-left LED in the module. In the operating mode for an Access Point Module, this LED is continuously lit as the module receives sync pulse. In the operating mode for a Subscriber, this LED flashes on and off to indicate that the module is not registered. GUI Graphical user interface. High-priority Channel Channel that supports low-latency traffic (such as Voice over IP) over low-latency traffic (such as standard web traffic and file downloads). To recognize the latency tolerance of traffic, this channel reads the IPv4 Type of Service DiffServ Control Point (DSCP) bits. Enabling the high-priority channel reduces the maximum number of SMs that can be served in the sector. HTTP Hypertext Transfer Protocol, used to make the Internet resources available on the World Wide Web. Defined in RFC 2068. See http://www.faqs.org/rfcs/rfc2068.html. ICMP Internet Control Message Protocols defined in RFC 792, used to identify Internet Protocol (IP)-level problems and to allow IP links to be tested. See http://www.faqs.org/rfcs/rfc792.html. indiscards count Field How many inbound packets were discarded without errors that would have prevented their delivery to a higher-layer protocol. (Some of these packets may have been discarded to increase buffer space.)
PMP 450 Planning Guide Glossary  VI  pmp-0047 (June 2013)  Term Definition inerrors count Field How many inbound packets contained errors that prevented their delivery to a higher-layer protocol. innucastpkts count Field How many inbound non-unicast (subnetwork-broadcast or subnetwork-multicast) packets were delivered to a higher-layer protocol. inoctets count Field How many octets were received on the interface, including those that deliver framing information. Intel A registered trademark of Intel Corporation. inucastpkts count Field How many inbound subnetwork-unicast packets were delivered to a higher-layer protocol. inunknownprotos count Field How many inbound packets were discarded because of an unknown or unsupported protocol. IP Internet Protocol defined in RFC 791. The Network Layer in the TCP/IP protocol stack. This protocol is applied to addressing, routing, and delivering, and re-assembling data packets into the Data Link layer of the protocol stack. See http://www.faqs.org/rfcs/rfc791.html. IP Address 32-bit binary number that identifies a network element by both network and host. See also Subnet Mask. IPv4 Traditional version of Internet Protocol, which defines 32-bit fields for data transmission. ISM Industrial, Scientific, and Medical Equipment radio frequency band, in the 900-MHz, 2.4-GHz, and 5.8-GHz ranges. L2TP over IPSec Level 2 Tunneling Protocol over IP Security. One of several virtual private network (VPN) implementation schemes. Regardless of whether Subscriber Modules have the Network Address Translation feature (NAT) enabled, they support VPNs that are based on this protocol. Late Collision Field This field displays how many late collisions occurred on the Ethernet controller. A normal collision occurs during the first 512 bits of the frame transmission. A collision that occurs after the first 512 bits is considered a late collision.  A late collision is a serious network problem because the frame being transmitted is discarded.  A late collision is most commonly caused by a mismatch between duplex configurations at the ends of a link segment. Latency Tolerance Acceptable tolerance for delay in the transfer of data to and from a module. Line of Sight Wireless path (not simply visual path) direct from module to module. The path that results provides both ideal aim and an ideal Fresnel zone. LNK/5 Furthest left LED in the module. In the operating mode, this LED is continuously lit when the Ethernet link is present. In the aiming mode for a Subscriber Module, this LED is part of a bar graph that indicates the quality of the RF link.
PMP 450 Planning Guide Glossary  pmp-0047 (June 2013)  VII  Term Definition Logical Unit ID Final octet of the 4-octet IP address of the module. LOS Line of sight. The wireless path (not simply visual path) direct from module to module. The path that results provides both ideal aim and an ideal Fresnel zone.  LUID Logical Unit ID. The final octet of the 4-octet IP address of the module. MAC Address Media Access Control address. The hardware address that the factory assigns to the module for identification in the Data Link layer interface of the Open Systems Interconnection system. This address serves as an electronic serial number.  Management Information Base Space that allows a program (agent) in the network to relay information to a network monitor about the status of defined variables (objects). Maximum Information Rate (MIR) The cap applied to the bandwidth of an SM or specified group of SMs. In the Cambium implementation, this is controlled by the Sustained Uplink Data Rate, Uplink Burst Allocation, Sustained Downlink Data Rate, and Downlink Burst Allocation parameters. Media Access Control Address Hardware address that the factory assigns to the module for identification in the Data Link layer interface of the Open Systems Interconnection system. This address serves as an electronic serial number. MIB Management Information Base. Space that allows a program (agent) in the network to relay information to a network monitor about the status of defined variables (objects). MIR See Maximum Information Rate. NAT Network Address Translation defined in RFC 1631. A scheme that isolates Subscriber Modules from the Internet. See http://www.faqs.org/rfcs/rfc1631.html. NEC National Electrical Code. The set of national wiring standards that are enforced in the U.S.A. NetBIOS Protocol defined in RFC 1001 and RFC 1002 to support an applications programming interface in TCP/IP. This interface allows a computer to transmit and receive data with another host computer on the network. RFC 1001 defines the concepts and methods. RFC 1002 defines the detailed specifications. See http://www.faqs.org/rfcs/rfc1001.html and http://www.faqs.org/rfcs/rfc1002.html. Network Address Translation Scheme that defines the Access Point Module as a proxy server to isolate registered Subscriber Modules from the Internet. Defined in RFC 1631. See http://www.faqs.org/rfcs/rfc1631.html. Network Management Station See NMS. NMS Network Management Station. A monitor device that uses Simple Network Management Protocol (SNMP) to control, gather, and report information about predefined network variables (objects). See also Simple Network Management Protocol.
PMP 450 Planning Guide Glossary  VIII  pmp-0047 (June 2013)  Term Definition Object Network variable that is defined in the Management Information Base. outdiscards count Field How many outbound packets were discarded without errors that would have prevented their transmission. (Some of these packets may have been discarded to increase buffer space.) outerrrors count Field How many outbound packets contained errors that prevented their transmission. outnucastpkts count Field How many packets for which the higher-level protocols requested transmission to a non-unicast (subnetwork-broadcast or subnetwork-multicast) address. The number includes those that were discarded or not sent. outoctets count Field How many octets were transmitted out of the interface, including those that deliver framing information. outucastpkts count Field How many packets for which the higher-level protocols requested transmission to a subnetwork-unicast address. The number includes those that were discarded or not sent. Override Plug Device that enables the operator to regain control of a module that has been locked by the No Remote Access feature, the 802.3 Link Disable feature, or a password or IP address that cannot be recalled. This device can be either fabricated on site or ordered. PMP See Point-to-Multipoint Protocol. Point-to-Multipoint Protocol Defined in RFC 2178, which specifies that data that originates from a central network element can be received by all other network elements, but data that originates from a non-central network element can be received by only the central network element. See http://www.faqs.org/rfcs/rfc2178.html. Also referenced as PMP. PPPoE Point to Point Protocol over Ethernet. Supported on SMs for  operators who use PPPoE in other parts of their network operators who want to deploy PPPoE to realize per-subscriber authentication, metrics, and usage control. PPTP Point to Point Tunneling Protocol. One of several virtual private network implementations. Regardless of whether the Network Address Translation (NAT) feature enabled, Subscriber Modules support VPNs that are based on this protocol.  Protective Earth Connection to earth (which has a charge of 0 volts). Also known as ground. Proxy Server Network computer that isolates another from the Internet. The proxy server communicates for the other computer, and sends replies to only the appropriate computer, which has an IP address that is not unique or not registered. PTMP See Point-to-Multipoint Protocol. Quick Start Interface page that requires minimal configuration for initial module operation. Radio Signal Strength Indicator Relative measure of the strength of a received signal. An acceptable link displays an Radio Signal Strength Indicator (RSSI) value of greater than 700.
PMP 450 Planning Guide Glossary  pmp-0047 (June 2013)  IX  Term Definition Recharging Resumed accumulation of data in available data space (buckets). See Buckets. Reflection Change of direction and reduction of amplitude of a signal that encounters an object larger than the wavelength. Reflection may cause an additional copy of the wavelength to arrive after the original, unobstructed wavelength arrives. This causes partial cancellation of the signal and may render the link unacceptable. However, in some instances where the direct signal cannot be received, the reflected copy may be received and render an otherwise unacceptable link acceptable. Region Code A parameter that offers multiple fixed selections, each of which automatically implements  frequency band range restrictions for the selected region. Units shipped to regions other than the United States must be configured with the corresponding Region Code to comply with local regulatory requirements. Registrations MIB Management Information Base file that defines registrations for global items such as product identities and product components. See also Management Information Base. RetransLimitExp Field This field displays how many times the retransmit limit has expired. RF Radio frequency. How many times each second a cycle in the antenna occurs, from positive to negative and back to positive amplitude. RJ-11 Standard cable that is typically used for telephone line or modem connection. RJ-45 Standard cable that is typically used for Ethernet connection. This cable may be wired as straight-through or as crossover. Later modules auto-sense whether the cable is straight-through or crossover. Router Network element that uses the logical (IP) address of another to pass data to only the intended recipient. Compare to Switch and Bridge. RSSI Radio Signal Strength Indicator. A relative measure of the strength of a received signal. An acceptable link displays an RSSI value of greater than 700. RxBabErr Field This field displays how many receiver babble errors occurred. RxOverrun Field This field displays how many receiver overrun errors occurred on the Ethernet controller. Secure Shell A trademark of SSH Communications Security. Self-interference Interference with a module from another module in the same network. SES/2 Third-from-right LED in the module. In the Access Point Module, this LED is unused. In the operating mode for a Subscriber Module, this LED flashes on and off to indicate that the module is not registered. In the aiming mode for a Subscriber Module, this LED is part of a bar graph that indicates the quality of the RF link. Simple Network Management Protocol Standard that is used for communications between a program (agent) in the network and a network management station (monitor). Defined in RFC 1157. See http://www.faqs.org/rfcs/rfc1157.html.
PMP 450 Planning Guide Glossary  X  pmp-0047 (June 2013)  Term Definition SM Customer premises equipment (CPE) device that extends network or Internet services by communication with an Access Point Module or an Access Point cluster. SM MIB Management Information Base file that defines objects that are specific to the Subscriber Module. See also Management Information Base. SNMP See Simple Network Management Protocol, defined in RFC 1157. SNMP Trap Capture of information that informs the network monitor through Simple Network Management Protocol of a monitored occurrence in the module. Static IP Address Assignment Assignment of Internet Protocol address that can be changed only manually. Thus static IP address assignment requires more configuration time and consumes more of the available IP addresses than DHCP address assignment does. RFC 2050 provides guidelines for the static allocation of IP addresses. See http://www.faqs.org/rfcs/rfc2050.html. See also DHCP. Subnet Mask 32-bit binary number that filters an IP address to reveal what part identifies the network and what part identifies the host. The number of subnet mask bits that are set to 1 indicates how many leading bits of the IP address identify the network. The number of subnet mask bits that are set 0 indicate how many trailing bits of the IP address identify the host. Subscriber Module Customer premises equipment (CPE) device that extends network or Internet services by communication with an Access Point Module or an Access Point cluster. Sustained Data Rate Preset rate limit of data transfer. Switch Network element that uses the port that is associated with the physical address of another to pass data to only the intended recipient. Compare to Bridge and Router. SYN/1 Second-from-right LED in the module. In the Access Point Module or  in a registered Subscriber, this LED is continuously lit to indicate the presence of sync. In the operating mode for a Subscriber Module, this LED flashes on and to indicate that the module is not registered.  Sync GPS (Global Positioning System) absolute time, which is passed from one module to another. Sync enables timing that prevents modules from transmitting or receiving interference. Sync also provides correlative time stamps for troubleshooting efforts. TCP Alternatively known as Transmission Control Protocol or Transport Control Protocol. The Transport Layer in the TCP/IP protocol stack. This protocol is applied to assure that data packets arrive at the target network element and to control the flow of data through the Internet. Defined in RFC 793. See http://www.faqs.org/rfcs/rfc793.html. TDD Time Division Duplexing. Synchronized data transmission with some time slots allocated to devices transmitting on the uplink and some to the device transmitting on the downlink.
PMP 450 Planning Guide Glossary  pmp-0047 (June 2013)  XI  Term Definition telnet Utility that allows a client computer to update a server. A firewall can prevent the use of the telnet utility to breach the security of the server. See http://www.faqs.org/rfcs/rfc818.html,  http://www.faqs.org/rfcs/rfc854.html and http://www.faqs.org/rfcs/rfc855.html. Textual Conventions MIB Management Information Base file that defines system-specific textual conventions. See also Management Information Base. Tokens Theoretical amounts of data. See also Buckets. TOS 8-bit field in that prioritizes data in a IP transmission. See http://www.faqs.org/rfcs/rfc1349.html. TxUnderrun Field This field displays how many transmission-underrun errors occurred on the Ethernet controller. UDP User Datagram Protocol. A set of Network, Transport, and Session Layer protocols that RFC 768 defines. These protocols include checksum and address information but does not retransmit data or process any errors. See http://www.faqs.org/rfcs/rfc768.html. udp User-defined type of port. U-NII Unlicensed National Information Infrastructure radio frequency band, in the 5.1-GHz through 5.8-GHz ranges. VID VLAN identifier. See also VLAN. VLAN Virtual local area network. An association of devices through software that contains broadcast traffic, as routers would, but in the switch-level protocol. VPN Virtual private network for communication over a public network. One typical use is to connect remote employees, who are at home or in a different city, to their corporate network over the Internet. Any of several VPN implementation schemes is possible. SMs support L2TP over IPSec (Level 2 Tunneling Protocol over IP Security) VPNs and PPTP (Point to Point Tunneling Protocol) VPNs, regardless of whether the Network Address Translation (NAT) feature enabled.

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