PTP 600 Series User Guide MOTOROLA POINT-TO-POINT WIRELESS SOLUTIONS
MOTOROLA, Inc. Point-to-Point Wireless Bridges – PTP 600 Series Software Release PTP 600-08-xx System User Guide December 2nd, 2008 Ref: PHN-0896-08.00 Copyright Information This document is the confidential property of Motorola, Inc. and without its prior written consent may not be copied or released to third parties. MOTOROLA, the stylized M Logo and all other trademarks indicated as such herein are trademarks of Motorola, Inc. ® Reg. U.S. Pat & Tm. Office. PTP 600 is a trademark of Motorola, Inc.
The system has been tested for compliance to both US (FCC) and European (ETSI) 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 and appropriate European ENs. These limits have been designed to provide reasonable protection against harmful interference.
The system has been tested for compliance to both US (FCC) and European (ETSI) 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 and appropriate European ENs. These limits have been designed to provide reasonable protection against harmful interference.
Regulations applicable to PTP 54600 variant Examples of Regulatory Limits at 5.4GHz Operation of this product is only allowed with a License Key for Region 12. This implements Radar Detection in accordance with FCC Regulations and limits the EIRP to the regulatory limits below: FCC EIRP Max of [(17 +10 x Log(Channel BW)) and 30] dBm. Oeration of this product is only allowed with a License Key for Region 26.
Regulations applicable to PTP 58600 variant Examples of Regulatory Limits Equipment can be operated in any mode, best results will be obtained using USA/ Canada/ Region 1 settings. There are some limitations on the use of antennas above 4ft Taiwan/ Brazil diameter plus a band edge power reduction. China Operation of this product is only allowed with a License Key for Region 2 (33 dBm or 2W EIRP). Australia Operation of this product is only allowed with a License Key for Region 3 (36 dBm or 4W EIRP).
General Notice Applicable to Europe This equipment complies with the essential requirements for the EU R&E Directive 1999/5/EC. The use of 5.8GHz for Point to Point radio links is not harmonized across the EU and currently the product may only be deployed in the UK, Eire (IRL), Germany, Denmark and Norway. However, the regulatory situation in Europe is changing and the radio spectrum may become available in other countries in the near future. Please contact Motorola for the latest situation.
The parameters quoted in this document must be specifically confirmed in writing before they become applicable to any particular order or contract. The company reserves the right to make alterations or amendments to the detail specification at its discretion. The publication of information in this document does not imply freedom from patent or other rights of Motorola, Inc. or others.
Contents 1 About This User Guide ....................................................................................................... 28 1.1 Interpreting Typeface and Other Conventions ...................................................................... 28 1.2 Getting Additional Help ......................................................................................................... 30 1.3 Sending Feedback .....................................................................................
5 Radio Link Planning and Regulations ............................................................................. 49 5.1 Spectrum Planning ................................................................................................................ 49 5.2 Licenses and Region Codes ................................................................................................. 50 5.2.1 PTP 25600 Licenses and Region Codes ...........................................................................
5.14 Distance ................................................................................................................................ 80 5.15 Networking Information ......................................................................................................... 81 5.16 Lightning Protection............................................................................................................... 81 5.17 Electrical Requirements .....................................................
7.7.7 Making the ODU Connection at the PTP 600 Series Bridge PIDU Plus............................. 109 7.7.8 Making the Network Connection at The PIDU Plus – PTP 600 Series Bridge ................... 110 7.7.9 Mounting the PTP 600 Series Bridge PIDU Plus ................................................................ 111 7.7.10 Powering Up........................................................................................................................ 113 7.7.
8.3.7.5 Spectrum Management Configuration ................................................................................ 176 8.3.7.6 Barring Channels................................................................................................................. 177 8.3.7.7 Master and Slave Channel Spectrum Graphics.................................................................. 177 8.3.7.8 Active Channel History.....................................................................................
10.4.1 Typical Mast or Tower Installation....................................................................................... 216 10.4.2 Typical Wall Installation....................................................................................................... 217 10.4.3 Mast or Tower Installation with E1/T1 ................................................................................. 218 10.4.4 Wall Installation with E1/T1 .................................................................
13.6 Regulatory Issues with Connectorized Units ...................................................................... 240 13.6.1 Cable Losses (FCC Regions Only) .................................................................................... 241 13.6.2 Antenna Choices ................................................................................................................. 241 13.6.3 FCC Antenna Restrictions on the PTP 58600 ................................................................
15.6 Lightning Protection and E1/T1........................................................................................... 275 15.6.1 Overview ............................................................................................................................. 275 15.6.2 Recommended Additional Components for E1/T1 Installation. .......................................... 275 15.7 Testing the E1/T1 Installation.................................................................................
19.8.1 Motorola Inc. End User License Agreement ....................................................................... 312 19.8.1.1 Definitions............................................................................................................................ 312 19.8.1.2 Grant of License .................................................................................................................. 312 19.8.1.3 Conditions of Use .................................................................
20.3 EMC Emissions Compliance............................................................................................... 331 20.3.1 PTP 25600 Variant .............................................................................................................. 331 20.3.2 PTP 45600 Variant .............................................................................................................. 331 20.3.3 PTP 48600 Variant .......................................................................
List of Figures Figure 1 - Typical PTP 600 Series Bridge Deployment........................................................................ 36 Figure 2 - Mod Record Label................................................................................................................ 37 Figure 3 – PTP 600 Series Bridge Outdoor Unit (ODU) with PTP-LPU ............................................... 38 Figure 4 - Power Indoor Unit (PIDU Plus) – PTP 300/500/600 Series.............................................
Figure 27 - 5.8 GHz Available Spectrum Settings - 15 MHz Channel Bandwidth................................ 71 Figure 28 - 5.8 GHz Available Spectrum Settings - 10 MHz Channel Bandwidth................................ 71 Figure 29 - 5.8 GHz Available Spectrum Settings - 5 MHz Channel Bandwidth.................................. 71 Figure 30 - 5.9 GHz Available Spectrum Settings – 30 MHz Channel Bandwidth ............................... 74 Figure 31 - 5.
Figure 54 - Configuration Reboot Page - Ethernet Auto Negotiation Disabled .................................. 135 Figure 55 - VLAN Configuration Fields............................................................................................... 136 Figure 56 - LAN Configuration Page - Manual Ethernet Configuration .............................................. 137 Figure 57 - Save and Restore Configuration Page ............................................................................
Figure 81 - Reboot Confirmation Pop Up ........................................................................................... 171 Figure 82 - Spectrum Management as seen from the Master............................................................ 174 Figure 83 - Spectrum Management as seen from the Slave.............................................................. 175 Figure 84 - Example Spectrum Management Graphic .......................................................................
Figure 108 - Reboot Confirmation Pop Up ......................................................................................... 202 Figure 109 - Confirm Reset to Factory Default Pop Up...................................................................... 203 Figure 110 - IP and Ethernet Erased Successfully page.................................................................... 203 Figure 111 - Reboot Confirmation Pop Up .....................................................................................
Figure 127 - Connectorized PTP 600 Series Bridge ‘Installation Wizard’ Page ................................ 237 Figure 128 - Connectorized 600 Series bridge ‘Confirm Installation’ Page........................................ 238 Figure 129 - Connectorized 600 Series bridge ‘Disarm Installation’ Page......................................... 239 Figure 130 - Forming a Drip Loop ......................................................................................................
Figure 154 – PTP 600 Range Adjustment for Data Rates, Curve B .................................................. 286 Figure 155 – PTP 600 Range Adjustment for Data Rates, Curve C .................................................. 287 Figure 156 – PTP 600 Range Adjustment for Data Rates, Curve D .................................................. 288 Figure 157 – PTP 600 Range Adjustment for Data Rates, Curve E ..................................................
List of Tables Table 1 - Font types ............................................................................................................................ 28 Table 2 - Admonition types................................................................................................................... 29 Table 3 - Power Compliance Margins .................................................................................................. 32 Table 4 - Contact Information ....................................
Table 23 - PTP 49600 - IP Mode – Loss, Output Power and System Threshold Vs Modulation Mode ....................................................................................................................................................... 91 Table 24 - PTP 49600 - TDM Mode – Loss, Output Power and System Threshold Vs Modulation Mode..............................................................................................................................................
Table 46 - Resistance Table Referenced To the E1/T1 Source ........................................................ 276 Table 47 – Data Throughput for PTP 600 Full, Link Symmetry = 1:1, Link Optimization = IP ........... 280 Table 48 – Data Throughput for PTP 600 Full, Link Symmetry = 1:1, Link Optimization = TDM....... 281 Table 49 – Data Throughput for PTP 600 Full, Link Symmetry = 2:1, Link Optimization = IP ...........
1 About This User Guide 1 About This User Guide This guide covers the installation, commissioning, operation and fault finding of the Motorola PTP 600 Series of Point-to-Point Wireless Ethernet Bridges. 1.1 Interpreting Typeface and Other Conventions This document employs distinctive fonts to indicate the type of information, as described in Table 1.
1 About This User Guide This document also employs a set of consistently used admonitions. Each type of admonition has a general purpose that underlies the specific information in the box. These purposes are indicated in Table 2. Table 2 - Admonition types Admonition Label General Message Note Informative content that may: x Defy common or cursory logic. x Describe a peculiarity of the 600 Series solutions implementation. x Add a conditional caveat. x Provide a reference.
1 About This User Guide 1.2 Getting Additional Help To get information or assistance as soon as possible for problems that you encounter, follow this procedure: 1. Search this document, the user manuals that support the modules, and the software release notes of supported releases: a. In the Table of Contents for the topic. b. In the Adobe Reader® search capability for keywords that apply (Reader is a registered trademark of Adobe Systems, Incorporated). 2. Visit the Motorola website at www.motorola.
2 Avoiding Hazards 2 Avoiding Hazards 2.1 Preventing Overexposure to RF Energy WARNING: To protect from overexposure to RF energy, install the radios for the 600 family of PTP wireless solutions so as to provide and maintain the minimum separation distances from all persons as shown in Table 3. When the system is operational, avoid standing directly in front of the antenna. Strong RF fields are present when the transmitter is on.
2 Avoiding Hazards The applicable power density exposure limit from the documents referenced above is: 10 W/m2 for RF energy in the 2.4-, 5.2-, 5.4-, 5.8- and 5.9 GHz frequency bands. x Peak power density in the far field of a radio frequency point source is calculated as follows: Equation 1 - Peak power density in the far field S P .
2 Avoiding Hazards Band Antenna Integrated Max Average Transmit Power in Burst (Watt) 0.005 (7dBm) Variable P (Watt) 0.00250 d (m) G 200 (23dBi) S (W/m2) 10 5.8 GHz 5.9 GHz Power mended Compliance Distance (m) Margin 1 15.9 0.06 0.00035 5.4 GHz Recom- External 4ft Dish (4.6dBm) 0.00017 2884 (34.6dBi) 10 0.06 Integrated 0.32 (25dBm) 0.16 200 (23dBi) 10 0.5 2 4.0 External 2ft Flat Plate 0.32 (25dBm) 0.16 631 (28dBi) 10 0.9 4 4.5 External 6ft Dish 0.32 (25dBm) 0.
3 Getting Started 3 Getting Started 3.1 For Your Safety WARNING: Use extreme care when installing antennas near power lines. WARNING: Use extreme care when working at heights. WARNING: The Outdoor Unit (ODU) for the PTP 600 Series Bridge must be properly grounded to protect against lightning. In the USA and Canada it is the user’s responsibility to install the equipment in accordance with Section 810 of the National Electric Code, ANSI/NFPA No.70-1984 or Section 54 of the Canadian Electrical Code.
3 Getting Started 3.2 Welcome Congratulations on the purchase of the PTP 600 Series Bridge from Motorola. The PTP 600 Series Bridge is the latest innovation in high-speed wireless networking that lets you deploy wireless networks in areas previously unattainable. 3.2.1 Who Should Use This Guide The guide is for use by the system installer and the end user IT professional. The system installer will require expertise in the following areas: 3.2.
3 Getting Started 3.3 Product Description This User Manual is specifically written for the 600 family of point-to-point broadband wireless solutions. The PTP 600 Series Bridge has been developed to provide Point-to-Point data connectivity via a 2.5 GHz, 4.5 GHz, 4.8 GHz, 4.9 GHz, 5.4 GHz, 5.8 GHz or 5.9 GHz wireless Ethernet bridge operating at broadband data rates. The PTP 600 Series Bridge is aimed at a wide range of applications.
3 Getting Started Each end of the link consists of: x An integrated (or connectorized -see section 13) outdoor transceiver unit containing all the radio and networking electronics hereafter referred to as the Outdoor Unit (ODU). x An indoor connection box containing a mains power supply, status indicators and network connection port. Hereafter referred to as the Power Indoor Unit Plus (PIDU Plus). A pair of units is normally supplied pre-configured as a link.
3 Getting Started 3.3.1 The Outdoor Unit (ODU) The ODU is a self-contained unit. It houses both radio and networking electronics. The ODU for the PTP 600 Series Bridge should only be deployed using the supplied PTP 600 Series Bridge PIDU Plus. Figure 3 shows an installation example of a PTP 600 Series ODU with a Motorola lightning protection unit (PTP-LPU).
3 Getting Started 3.3.2 PIDU Plus – PTP 600 Series Bridge The PTP 600 Series Bridge PIDU Plus is used to generate the ODU supply voltage from the mains supply and inject this supply voltage into the 1000BaseT Ethernet connection to the ODU. Connection uses a CAT5e cable using standard RJ45 wiring. CAUTION: Care should be taken not to connect equipment other than an ODU for the PTP 600 Series Bridge to a PIDU Plus ODU port as equipment damage may occur.
3 Getting Started The Recovery switch is used to recover the unit from configuration errors or software image corruption. To put a PTP 600 Series Bridge into Recovery mode the Recovery switch should be pressed then the power applied. The Recovery switch should be kept pressed for at least 20 seconds after the power has been applied. Full instruction on the recovery mode can be found in Section 9 “Recovery Mode”.
3 Getting Started 3.3.3 Redundancy and Alternative Powering Configurations NOTE: The use of DC supplies of less than 55v will reduce the usable distance between the PIDU Plus and ODU see Figure 7. Figure 7 – PTP 600 Series Bridge PIDU Plus to ODU Cable Length Graph CAUTION: The maximum distance from the ODU to the connected network equipment is 100m (330 ft) when using 1000BaseT. Powering distances over 100m (330 ft) are only applicable when using a 1000BaseSX (Fiber Optic) connection. 3.3.3.
3 Getting Started 3.3.3.2 External DC Supply and AC Supply This configuration provides redundancy through the use of mains and DC supply. Figure 9 - External DC Supply and AC Supply 3.3.3.3 External DC Supply and Redundant AC Supply This configuration guards against mains failure and failure of the DC output of single PTP 300/500/600 PIDU Plus.
3 Getting Started 3.3.4 Remote LEDs and Recovery Switch The PTP 600 Series Bridge PIDU Plus provides a facility to connect remote LEDs and Recovery switch allowing the PIDU Plus to be mounted inside an enclosure. At the left hand end of the PIDU Plus under the ODU connection cover can be found a PCB header and three jumpers. Jumpers J906 and J907 should be removed and connection to the remote LEDs and Recovery switch made to J908 as shown in Figure 11. Figure 11 - Remote LED and Recovery Switch Wiring 3.
3 Getting Started The PIDU Plus to ODU and the PIDU Plus to Network Equipment cables may be unscreened (UTP) or screened (STP). However, unscreened cables reduce the system’s ability to cope with nearby lightning strikes. If lightning activity is common in the area of deployment, the use of screened cable is highly recommended. See Section 10 “Lightning Protection”. The PIDU Plus provides screen continuity between the ODU and Network Equipment connections.
3 Getting Started 3.3.8 Configuration and Management Configuration and Management of the PTP 600 Series Bridge is implemented using an inbuilt web server hosting a number of Configuration and Management web pages. This approach allows Configuration and Management to be carried out on any standard web browsing technology. The PTP 600 Series Bridge can also be managed remotely using the SNMP management protocol. Connection to the bridge is via the Ethernet connection carrying the bridge network traffic.
4 Product Architecture 4 Product Architecture 4.1 Radio Link The PTP 600 Series Bridge consists of an identical pair of units deployed one at each end of the link. The radio link operates on a single frequency channel in each direction using Time Division Duplex (TDD). One unit is deployed as a master and the other as a slave. The master unit takes responsibility for controlling the link in both directions.
4 Product Architecture 4.3 Ethernet Frames The PTP 600 series provides wireless Ethernet bridging between two fixed locations. To be more precise, it forwards Ethernet frames as a two-port transparent heterogeneous encapsulation bridge, meaning that each bridge forwards frames between two dissimilar interfaces (Ethernet and wireless), encapsulating Ethernet MAC frames within a PTP MAC frames for transmission at the wireless interface.
4 Product Architecture Each unit in the link is manageable through an IP connection. Standard IP protocols are utilized for all management functions, for example, HP, SNMP, etc. The unit can be configured to use a VLAN with a single C-tag or S-tag on the management interfaces. 4.
5 Radio Link Planning and Regulations 5 5.1 Radio Link Planning and Regulations Spectrum Planning The PTP 600 Series Bridge has seven frequency variants in its product range. Table 5 - PTP 600 Series Bridge Frequency Variants Variant Definition Frequency Coverage Variable Channel Width Channel Raster PTP 25600 FCC BRS-EBS PostTransition Band 2496-2568 MHz 5, 10, 15 and 30 MHz 5.5 MHz 2572-2614 MHz 5, 10, 15 and 30 MHz 6 MHz 2618-2690 MHz 5, 10, 15 and 30 MHz 5.
5 Radio Link Planning and Regulations NOTE: For PTP 54600, PTP 58600 and PTP 59600, use of the product is allowed according to local regulations. There are two alternative methods of spectrum planning: x First an operator can utilize the default spectrum management mode i-DFS (intelligent Dynamic Frequency Selection). This mode uses the PTP 600 Series Bridge ability to measure the interference levels in all channels to build up a picture of the interference / noise levels in all channels.
5 Radio Link Planning and Regulations 5.2.1 PTP 25600 Licenses and Region Codes PTP 25600 units may be operated in any of the regions listed in Table 6. When shipped, PTP 25600 units are configured with a license key for Region Code 16. An alternative license key is provided in the Deployment Guide for Region Code 18. NOTE: For a PTP 25600 in Region Code 16, the EIRP limit is approximately 63 dBm + 10 x Log(360/Antenna Azimuth BW).
5 Radio Link Planning and Regulations 5.2.3 PTP 48600 Licenses and Region Codes PTP 48600 units may be operated in any of the regions listed in Table 8. When shipped, PTP 48600 units are configured with a license key for Region Code 23. An alternative license key is provided in the Deployment Guide for Region Code 14. If the link is to be installed in any other permitted region, the user must obtain a new license key from the reseller or distributor.
5 Radio Link Planning and Regulations 5.2.4 PTP 49600 Licenses and Region Codes PTP 49600 units may be operated in any of the regions listed in Table 9. When shipped, PTP 49600 units are configured with a license key for Region Code 14. An alternative license key is provided in the Deployment Guide for Region Code 18.
5 Radio Link Planning and Regulations 5.2.5 PTP 54600 Licenses and Region Codes PTP 54600 units may be operated in any of the regions listed in Table 10. When shipped, PTP 54600 units are configured with a license key for Region Code 26. Alternative license keys are provided in the Deployment Guide for Region Codes 12 and 13. If the link is to be installed in any other permitted region, the user must obtain a new license key from the reseller or distributor.
5 Radio Link Planning and Regulations Region Code License / Regulation 26 ETSI 5.2.6 Frequencies DFS Channel Bandwidth Max Power Notes 5470 - 5600 MHz 5650 - 5725 MHz Yes 30 MHz 30 dBm EIRP 15 MHz 27 dBm EIRP The band 5600 MHz to 5650 MHz is reserved for the use of weather radars 10 MHz 25 dBm EIRP 5 MHz 22 dBm EIRP PTP 58600 Licenses and Region Codes PTP 58600 units may be operated in any of the regions listed in Table 11.
5 Radio Link Planning and Regulations Region Code License / Regulation Frequencies 5 Singapore 6 Eire 7 Norway Channel Bandwidth Max Power 5725 - 5850 MHz 5, 10, 15, 30 MHz 20 dBm EIRP 5725 - 5850 MHz 30 MHz 33 dBm EIRP 15 MHz 31 dBm EIRP 10 MHz 30 dBm EIRP 5 MHz 27 dBm EIRP 30 MHz 53 dBm EIRP 15 MHz 51 dBm EIRP 10 MHz 50 dBm EIRP 5 MHz 47 dBm EIRP 5725 - 5795 MHz 5815 - 5850 MHz DFS Yes 8 Full Power 5725 - 5850 MHz 5, 10, 15, 30 MHz 25 dBm 11 Korea 5725 - 5825 MHz
5 Radio Link Planning and Regulations Region Code License / Regulation Frequencies DFS Channel Bandwidth Max Power Notes 27 Denmark 5725 - 5795 5815 - 5850 MHz Yes 30 MHz 35 dBm EIRP 15 MHz 34 dBm EIRP 10 MHz 32 dBm EIRP 5 MHz 29 dBm EIRP 5795 MHz to 5815 MHz is assigned for Road Transport and Traffic Telematics (RTTT) 5.2.7 PTP 59600 Licenses and Region Codes PTP 59600 units may be operated in any of the regions listed in Table 12.
5 Radio Link Planning and Regulations 5.3 Operational Restrictions 5.3.1 Radar Avoidance Radar Avoidance requires that equipment used in the region: x Detects interference from other systems and avoids co-channel operation with these systems, notably radar systems. x Provide on aggregate a uniform loading of the spectrum across all devices, that is, Fixed Frequency operation is not allowed. Radar avoidance is not applicable to the PTP 25600 product or the PTP 45600 product.
5 Radio Link Planning and Regulations 5.3.2 RTTT Avoidance and Other Channel Use Restrictions Where regulatory restrictions apply to certain channels these channels are barred. RTTT avoidance may be necessary in all channel bandwidths. The number of channels barred is dependant on the channel raster selected. For example see the effect of the UK RTTT channel restrictions in the 30 MHz bandwidth (Figure 13), where blocks in red indicate channels that are barred.
5 Radio Link Planning and Regulations 5.3.3 Radar Avoidance, i-DFS and Variable (Narrow) Bandwidth Operation PTP 600 Series bridges do not support operation with 5, 10 or 15 MHz channel bandwidth in regions where radar avoidance is enabled. NOTE: Radar avoidance requirements in the 5.4GHz band in the EU is detailed in specification EN 301-893 version 1.4.1 and in the US in the specification FCC part 15.437. Radar avoidance at 5.
5 Radio Link Planning and Regulations The PTP 25600 product variant support channel centre frequencies as specified in Table 13. Table 13 - PTP 25600 Product Variant Channel Plan - FCC BRS-EBS Post-Transition Band Block Channel Bandwidth (MHz) Channel Centre Frequencies (MHz) Lower Band Segment 5 2499.25, 2504.75, 2510.25, 2515.75, 2521.25, 2526.75, 2532.25, 2537.75, 2543.25, 2548.75, 2554.25, 2559.75, 2565.25 10 2502, 2507.5, 2513, 2518.5, 2524, 2529.5, 2535, 2540.5, 2546, 2551.5, 2557, 2562.
5 Radio Link Planning and Regulations Figure 14 - 2.5 GHz BRS Band Channel Assignments 5.5.1 Power Reduction in the Upper Band Operation in the Upper Band Segment (Table 14) will result in a lower maximum transmit power and the reduction depends on the channel bandwidth. The maximum power levels produced are shown below.
5 Radio Link Planning and Regulations 5.6 PTP 45600 Specific Frequency Planning Considerations Adjustment of the lower centre frequency allows the operator to slide the available frequency settings up and down the 4.5 GHz band. Figure 15 to Figure 18 show the available spectrum settings for the 30 MHz, 15 MHz, 10 MHz and 5 MHz channel bandwidths All channel centre frequencies may not be available for all Region Codes. . Figure 15 - 4.
5 Radio Link Planning and Regulations Figure 16 - 4.5 GHz Available Spectrum Settings – 15 MHz Channel Bandwidth Figure 17 - 4.
5 Radio Link Planning and Regulations Figure 18 - 4.5 GHz Available Spectrum Settings – 5 MHz Channel Bandwidth 5.6.1 PTP 45600 Raster Considerations The PTP 45600 variant operates on a 10 MHz channel raster (for 30 MHz channel bandwidth) and 6 MHz for the variant channel bandwidths 5, 10 and 15 MHz. The channel raster is set to even centre frequencies. See Figure 15 to Figure 18. 5.6.
5 Radio Link Planning and Regulations 5.8 PTP 49600 Specific Frequency Planning Considerations Adjustment of the lower centre frequency allows the operator to slide the available frequency settings up and down the 4.9 GHz band. Figure 19 to Figure 21 show the available spectrum settings for the 20 MHz, 10 MHz and 5 MHz channel bandwidths All channel centre frequencies may not be available for all Region Codes. Figure 19 - 4.9 GHz Available Spectrum Settings - 20 MHz Channel Bandwidth Figure 20 - 4.
5 Radio Link Planning and Regulations Figure 21 - 4.9 GHz Available Spectrum Settings - 5 MHz Channel Bandwidth 5.9 PTP 54600 Specific Frequency Planning Considerations Adjustment of the lower centre frequency allows the operator to slide the available frequency settings up and down the 5.4 GHz band. Figure 22 to Figure 25 show the available spectrum settings for the 30 MHz, 15 MHz, 10 MHz and 5 MHz channel bandwidths All channel centre frequencies may not be available for all Region Codes.
5 Radio Link Planning and Regulations Figure 23 - 5.4 GHz Available Spectrum Settings - 15 MHz Channel Bandwidth Figure 24 - 5.4 GHz Available Spectrum Settings - 10 MHz Channel Bandwidth Figure 25 - 5.
5 Radio Link Planning and Regulations 5.9.1 PTP 54600 Raster Considerations: The PTP 54600 variant operates on a 10 MHz channel raster (for 30 MHz channel bandwidth) and 6 MHz for the variant channel bandwidths 5, 10 and 15 MHz. The channel raster is set to even centre frequencies. See Figure 22 to Figure 25. 5.9.2 Transmit Power Reduction at the Band Edges The PTP 54600 product variant does not apply any band edge power reduction.
5 Radio Link Planning and Regulations 5.10 PTP 58600 Specific Frequency Planning Considerations Adjustment of the lower center frequency allows the operator to slide the available frequency settings up and down the 5.8 GHz bands. Figure 26 to Figure 29 show the available spectrum settings for the 30 MHz, 15 MHz, 10 MHz and 5 MHz channel bandwidths in those regions where the band edge is 5850 MHz (for example FCC). All channel centre frequencies may not be available for all Region Codes. Figure 26 - 5.
5 Radio Link Planning and Regulations Figure 27 - 5.8 GHz Available Spectrum Settings - 15 MHz Channel Bandwidth Figure 28 - 5.8 GHz Available Spectrum Settings - 10 MHz Channel Bandwidth Figure 29 - 5.
5 Radio Link Planning and Regulations 5.10.1 PTP 58600 Raster Considerations The PTP 58600 variant operates on a 10 MHz channel raster (for 30 MHz channel bandwidth) and 6 MHz for the variant channel bandwidths 5, 10 and 15 MHz. The channel raster is set to even center frequencies. See Figure 26 to Figure 29.
5 Radio Link Planning and Regulations 5.10.2 PTP 58600 Transmit Power Reduction at the Band Edges Operation at or near the 5.8 GHz band edges can results in a lower maximum transmit power. In some configurations the PTP 600 Series Bridge solution reduces the power when operating at the edge channels. The amount of reduction, if any, is dependant on the region code of the region of operation. This currently only affects systems configured with Region Code 1.
5 Radio Link Planning and Regulations 5.11 PTP 59600 Specific Frequency Planning Considerations Adjustment of the lower center frequency allows the operator to slide the available frequency settings up and down the 5.9 GHz bands. Figure 30 to Figure 33 show the available spectrum depending on the channel width (30 MHz, 15 MHz, 10 MHz and 5 MHz respectively). Figure 30 - 5.
5 Radio Link Planning and Regulations Figure 31 - 5.9 GHz Available Spectrum Settings - 15 MHz Channel Bandwidth Figure 32 - 5.
5 Radio Link Planning and Regulations Figure 33 - 5.9 GHz Available Spectrum Settings - 5 MHz Channel Bandwidth 5.11.1 PTP 59600 Raster Considerations The PTP 59600 variant operates on a 10 MHz channel raster (for 30 MHz channel bandwidth) and 6 MHz for the variant channel bandwidths 5, 10 and 15 MHz. The channel raster is set to even center frequencies. See Figure 30 to Figure 33.
5 Radio Link Planning and Regulations 5.12 Time Division Duplex (TDD) Synchronization 5.12.1 Introduction In a TDD system, a radio transmits for a portion of the radio frame and receives in a different portion of the frame. Motorola PTP600 links consist of a Master unit and a Slave unit with the Master transmitting for the first part of the radio frame (Slave receiving) and the Slave transmitting in the remainder of the radio frame (Master receiving).
5 Radio Link Planning and Regulations Interference can be minimised by increasing the radio channel separation between units which are in close proximity, for example for units on the same mast. This may not always be possible if the mast is hosting a large number of links and if spectrum is limited. Also, the achieved reduction may not always be sufficient. Another way to reduce interference is to reduce the transmit power of an interfering radio.
5 Radio Link Planning and Regulations 5.12.3 Implementation of TDD Synchronization TDD synchronization is achieved by connecting each Master unit to a GPS Synchronization Unit. Installation details are covered in Section 14 “TDD Synchronization Configuration and Installation Guide”. The GPS unit provides the Master unit with a precise 1Hz signal where the leading edge occurs at the same point in time for all units in the network which have been locked to the GPS Satellite system.
5 Radio Link Planning and Regulations 5.13 Color Codes Color Codes allow the user to optimize densely populated synchronized PTP 600 networks. There are two such parameters to be configured for each link: x Tx Color Code x Rx Color Code The Color Code parameters have 5 possible values: A, B, C, D and E. Different color codes have subtly different transmit waveforms.
5 Radio Link Planning and Regulations 5.15 Networking Information The PTP 600 Series Bridge operates as a transparent Ethernet bridge. Although each unit requires an IP address, this IP address is for management purposes only, and it plays no part in the forwarding of bridged Ethernet frames. IP addresses are assigned during initial configuration as described in Section 7.2 “Installation Procedure”. 5.
6 Site Planning 6 Site Planning 6.1 Site Selection Criteria The following are guidelines for selecting the installation location of the ODU and PIDU Plus for a PTP 600 Series Bridge. 6.1.
6 Site Planning 6.1.3 Path Loss Considerations The path loss is the amount of attenuation the radio signal undergoes between the two ends of the link. 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).
6 Site Planning Sensitivity: Sensitivity is defined as the combined receive input signal level on both -7 horizontal and vertical inputs that produces a Null BER Error ratio of 3x10 . Output Power: The output power is for a centre channel in Region 1. The output power will be reduced on the edge channels and may vary if different region codes are selected.
6 Site Planning 6.1.5 PTP 25600 Product Variant - Link Loss, Output Power and System Threshold versus Modulation Mode PTP 25600 system threshold figures are given in the following tables: x Table 17 - IP Mode. x Table 18 - TDM Mode. These figures assume that antenna gain is 23 dBi.
6 Site Planning Table 18 - PTP 25600 - TDM Mode – Loss, Output Power and System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -97.57 -95.14 -92.95 -90.39 +23 156.6 154.1 152.0 149.4 QPSK 0.63 single -91.55 -89.12 -88.20 -85.19 +23 150.6 148.1 147.2 144.2 QPSK 0.87 single -88.28 -85.58 -85.
6 Site Planning 6.1.6 PTP 45600 Product Variant - Link Loss, Output Power and System Threshold versus Modulation Mode PTP 45600 system threshold figures are given in the following tables: x Table 19 - IP Mode. x Table 20 - TDM Mode. These figures assume that antenna gain is 23 dBi.
6 Site Planning Table 20 - PTP 45600 - TDM Mode – Loss, Output Power and System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -97.86 -95.25 -93.00 -89.56 +25 165.9 163.3 161.0 157.6 QPSK 0.63 single -90.42 -88.78 -85.56 -82.82 +25 158.4 156.8 153.6 150.8 QPSK 0.87 single -86.07 -84.02 -80.
6 Site Planning 6.1.7 PTP 48600 Product Variant - Link Loss, Output Power and System Threshold versus Modulation Mode PTP 48600 system threshold figures are given in the following tables: x Table 21 - IP Mode. x Table 22 - TDM Mode. These figures assume that antenna gain is 22 dBi.
6 Site Planning Table 22 - PTP 48600 - TDM Mode – Loss, Output Power and System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -97.86 -95.25 -93.00 -89.56 +25 165.9 163.3 161.0 157.6 QPSK 0.63 single -90.42 -88.78 -85.56 -82.82 +25 158.4 156.8 153.6 150.8 QPSK 0.87 single -86.07 -84.02 -80.
6 Site Planning 6.1.8 PTP 49600 Product Variant - Link Loss, Output Power and System Threshold versus Modulation Mode PTP 49600 system threshold figures are given in the following tables: x Table 23 - IP Mode. x Table 24 - TDM Mode. These figures assume that antenna gain is 22 dBi.
6 Site Planning Table 24 - PTP 49600 - TDM Mode – Loss, Output Power and System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -97.86 -95.25 -93.00 -89.56 +25 165.9 163.3 161.0 157.6 QPSK 0.63 single -90.42 -88.78 -85.56 -82.82 +25 158.4 156.8 153.6 150.8 QPSK 0.87 single -86.07 -84.02 -80.
6 Site Planning 6.1.9 PTP 54600 Product Variant - Link Loss, Output Power and System Thresholds versus Modulation Mode PTP 54600 system threshold figures are given in the following tables: x Table 25 - IP Mode. x Table 26 - TDM Mode. These figures assume that antenna gain is 23 dBi.
6 Site Planning Table 26 – PTP 54600 - TDM Mode - Link Loss, Output Power, System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -98.24 -94.58 -92.26 -88.90 +25 169.2 165.6 163.3 159.9 QPSK 0.63 single -89.70 -88.28 -86.35 -81.35 +24 159.7 158.3 156.4 151.4 QPSK 0.87 single -86.70 -84.30 -82.
6 Site Planning 6.1.10 PTP 58600 Product Variant - Link Loss, Output Power and System Thresholds versus Modulation Mode PTP 58600 system threshold figures are given in the following tables: x Table 27 - IP Mode. x Table 28 - TDM Mode. These figures assume that antenna gain is 23 dBi.
6 Site Planning Table 28 - PTP 58600 - TDM Mode - Link Loss, Output Power, System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -95.05 -92.51 -90.78 -86.33 +25 166.1 163.5 161.8 157.3 QPSK 0.63 single -88.70 -87.77 -85.95 -80.59 +24 158.7 157.8 155.9 150.6 QPSK 0.87 single -85.51 -83.79 -81.
6 Site Planning 6.1.11 PTP 59600 Product Variant - Link Loss, Output Power and System Thresholds versus Modulation Mode PTP 59600 system threshold figures are given in the following tables: x Table 29 - IP Mode. x Table 30 - TDM Mode. These figures assume that antenna gain is 23 dBi.
6 Site Planning Table 30 - PTP 59600 - TDM Mode - Link Loss, Output Power, System Threshold Vs Modulation Mode Modulation Mode Threshold Output Maximum Value (dBm) Power (dBm) Link Loss (dB) Channel Bandwidth (MHz) 5 10 15 30 All 5 10 15 30 MHz MHz MHz MHz Bands MHz MHz MHz MHz BPSK 0.63 single -97.11 -94.07 -91.96 -88.66 +25.0 168.1 165.1 163.0 159.7 QPSK 0.63 single -88.47 -86.12 -84.37 -79.38 +24.0 158.5 156.1 154.4 149.4 QPSK 0.87 single -84.64 -81.
7 Installation 7 Installation IMPORTANT Motorola recommends that only qualified personnel undertake the installation of a PTP 600 Series Bridge solution. We recommend that the practices and procedures detailed in the Motorola manual R56 "STANDARDS AND GUIDELINES FOR COMMUNICATION SITES" (68P81089E50) be applied to all new site build activities. For a copy of the manual please see your local Motorola representative. The manual can be downloaded from the Motorola Intranet site http://compass.mot.
7 Installation 7.3 Tools Required The following specific tools are required to install a PTP 600 Series Bridge in addition to general tools: x 13mm Spanner / Wrench x RJ45 Crimp Tool x IBM Compatible Personal Computer (PC) running Windows 98 or later with 10, 100 or 1000 BaseT Ethernet (Ability to change IP settings easily is recommended) 7.4 x Either Internet Explorer version 6 or higher, or FireFox 1.5 or higher are recommended.
7 Installation 7.6 Mounting the ODUs The ODU mounting bracket is designed to ease installation by fixing the bracket to a pole and then bringing the ODU into position using a single bolt fixing. The ODU should be mounted using the following steps ensuring that the cable entry is at the bottom. The ODU mounting bracket is designed to work with poles with diameters in the range 50mm (2”) to 75mm (3”).
7 Installation WARNING: The integral safety loop should be used both for hoisting the ODU up a mast or building and into position, and also as a fixing point to secure a permanent safety lanyard from the tower/building to the ODU in case of mounting failure. Figure 37 - Integral Safety Loop The length of the safety lanyard must not exceed 1m (approx 3 ft) in length. The lanyard should be made from a material that does not degrade in an outdoor environment.
7 Installation 7.7 Connecting Up 7.7.1 Preparing the PIDU Plus To ODU Cable The maximum cable length between the ODU and the user’s Network Equipment is 100m (330 ft). Cable lengths up to 300m (984 ft) can be used where the PIDU Plus to ODU cable is supplying power only, that is, when using the PTP 600 Series Bridge Optical Interface. WARNING: The copper screen of the recommended Superior Essex cable is very sharp and may cause personal injury.
7 Installation The cable should be assembled as shown in Figure 38: Figure 38 - Correct Cable Preparation for the Recommended Cable CAUTION: Check that the crimp tool matches the RJ45 connector being used. Both ends of the ODU cable are terminated in the same way. The above procedure should be repeated for the PIDU Plus end of the cable when the cable routing process is complete. This assumes that the installation uses PTP LPUs.
7 Installation Figure 39 shows a completed ODU to PIDU Plus cable. Figure 39 - Completed ODU Connector CAUTION: Do not over tighten the glands as the internal seal and structure may be damaged. See Figure 40 for an example of an over tightened cable gland.
7 Installation 7.7.2 Making the Connections at the ODU Looking at the back of the unit with the cable entry at the bottom, the PTP 600 Series Bridge PIDU Plus connection is the first hole on the right (Figure 41) and is labeled “PIDU +”.
7 Installation 7.7.3 Making the PTP 600 Series Bridge PIDU Plus Connection At The ODU The following procedure describes how connection is made at the ODU. It is often easier to carry out this procedure on the ground or a suitable surface prior to mounting the ODU. Ensure that no power is connected to the PIDU Plus or present on the cable before connecting the ODU. Figure 42 - Connecting the PIDU+ to the ODU Step 1: Assemble the cable as described in 7.7.
7 Installation Should it be necessary to disconnect the PIDU Plus to ODU cable at the ODU, this can be achieved by removing the weather proofing gland and depressing the RJ45 locking tab with a small screwdriver as shown below. Figure 43 - Disconnecting the ODU CAUTION: Ensure that power is removed from the system at the PIDU Plus to prevent damage to the ODU while making or breaking the connection. 7.7.
7 Installation 7.7.6 Grounding the Installation The Outdoor Unit (ODU) must be properly grounded to protect against power surges. It is the user’s responsibility to install the equipment in accordance with Section 810 of the National Electric Code, ANSI/NFPA No.70-1984 or Section 54 of the National Electrical Code in the country of installation.
7 Installation Step 3: Replace the cover and secure with the retaining screw 7.7.8 Making the Network Connection at The PIDU Plus – PTP 600 Series Bridge The Network connection is made by connecting the user’s Network Equipment directly to the PIDU Plus LAN port as shown in Figure 44.
7 Installation 7.7.9 Mounting the PTP 600 Series Bridge PIDU Plus This step is optional. Motorola recommends that you mount the PIDU Plus on a wall or other suitable mounting surface. This prevents the unit from being knocked or kicked and can help maintain link availability. Ensure that the Recovery switch can be accessed when mounting the unit. Step 1: Fix the PIDU Plus to the wall using the lugs provided. Step 2: Make connections as per Section 7.7.
7 Installation It is also recommended that you fit a drip loop on the PIDU Plus to ODU cable to ensure that any moisture that runs down the cable into the cabinet or enclosure cannot enter the PIDU Plus. This is shown in Figure 45. The network connection and mains cable should be treated in the same way if there is a risk that they can carry moisture to the PIDU Plus.
7 Installation 7.7.10 Powering Up The PTP 600 Series Bridge is supplied as a pair of matched Master/Slave units. The Master unit can now be powered up and accessed using the default URL http://169.254.1.2/; the Slave unit can be accessed using http://169.254.1.1/. Prior to powering up the PTP 600 Series Bridge, a computer with web browsing capabilities should be configured with an IP address of 169.254.n.n and subnet mask of 255.255.0.0 where n is any value between 1 and 254 but excluding 1.1 or 1.2.
7 Installation 7.7.11 Aligning the PTP 600 Series Bridge ODUs The following is a description of the steps taken to establish a radio link between the two units forming the bridge and align the units for the best signal strength. The PTP 600 Series Bridge uses audible tones during installation to assist the installer with alignment. The installer should adjust the alignment of the ODU in both azimuth and elevation until highest pitch tone is achieved .
7 Installation For the ease of alignment, both Master and Slave units use the install tones in the same way but with some small behavioral differences. This allows the installer to install the Slave unit first and carry out the initial alignment with the Master unit if desired. However, due to the behavioral differences of Master and Slave units, it is recommended that the Master unit is installed first and the initial alignment carried out at the Slave unit.
7 Installation When the alignment process is complete, the installer MUST REMEMBER TO DISARM BOTH UNITS in the link, as described in Section 8.3.4 “Install Pages”. This is necessary in order to: x Turn off the audible alignment aid (section 8.3.4.
8 Web Page Reference 8 Web Page Reference The web user interface has three main sections. The home page presents to the operator a high level summary of the PTP 600 Series Bridge point-to-point wireless link. The status page presents a more detailed set of system parameters describing the performance of the wireless link together with other key system performance metrics. The final section is the system administration section.
8 Web Page Reference The navigation bar on the left hand side of the web page is used to move between the various management pages. The currently selected page is always highlighted with a light blue background. The menu is hierarchical. Selecting a menu item which has associated submenu options will automatically display all sub options. A sample web page with the navigation menu is shown in Figure 46 when the ‘Home’ Link is highlighted as the current page.
8 Web Page Reference 8.1 Home Page – PTP 600 Series Bridge The home page for the PTP 600 Series Bridge has been designed to display a high level summary of the status of the wireless link and associated equipment. The home page (Figure 47) normally displays four key system attributes: Wireless Link Status: The Wireless Link Status attribute displays the current status of the PTP 600 Series Bridge wireless link. A state of ‘Up’ on a green background indicates that a point-to-point link is established.
8 Web Page Reference 8.1.1 Home Page Alarm Display The home page is also used to display all outstanding major system alarms. Whenever system alarms are asserted, a yellow warning triangle is displayed on web page navigation bar. The warning triangle will be visible from all web pages. Clicking the warning triangle will cause the web page to jump back to the system homepage. Figure 48 shows a sample alarm screen.
8 Web Page Reference The following system alarms are defined: Ethernet Link Status: Current status of the Ethernet link. If there are any problems with the Ethernet interface, this alarm will be asserted. This alarm will most likely be seen if the unit has no Ethernet cable plugged into its Ethernet socket. Note that a change of state may generate an SNMP trap and/or SMTP email alert. Telecoms Channel A Status (see section 8.3.4.
8 Web Page Reference Install Status: A non-OK value indicates that signaling was received with the wrong MAC address. Note that it is very unusual to detect this, because units with wrongly configured Target MAC Address will normally fail to establish a wireless link. However, rare circumstances may establish a partial wireless link and detect this situation. NB: A non-OK value on start-up, or a change of value during operation, may generate an SNMP trap and/or SMTP email alert.
8 Web Page Reference Ethernet Link Disable Warning: This warning is displayed if the Ethernet link has been administratively disabled via the SNMP Interface (see section 8.3.11 “Remote Management Page”). The Ethernet Interface MIB-II ifAdminStatus attribute has been set to DOWN. To enable the Ethernet interface, set the ifAdminStatus attribute to UP. Note that a change of state may generate an SNMP trap and/or SMTP email alert.
8 Web Page Reference 8.2 Systems Status Page The status page has been designed to give the system administrator a detailed view of the operation of the 600 Series Bridge from both the wireless and network perspectives. The page is subdivided into four main categories Equipment, Wireless, Telecoms and Ethernet/Internet. The ‘Equipment’ section contains the unit’s inventory and identification information.
8 Web Page Reference The following section details all the attributes displayed on the status page: Link Name: The link name is allocated by the system administrator and is used to identify the equipment on the network. The link name attribute is limited to a maximum size of 63 ASCII characters. Link Location: The link location is allocated by the system administrator and can be used as a generic scratch pad to describe the location of the equipment or any other equipment related notes.
8 Web Page Reference Ethernet Speed and Duplex: The negotiated speed and duplex setting of the Ethernet interface. The speed setting is specified in Mbps. Full Duplex data transmission means that data can be transmitted in both directions on a signal carrier at the same time. For example, on a local area network with a technology that has full duplex transmission; one workstation can be sending data on the line while another workstation is receiving data.
8 Web Page Reference Vector Error: The vector error measurement compares the received signal’s In phase / Quadrature (IQ) modulation characteristics to an ideal signal to determine the composite error vector magnitude. The results are stored in an histogram and expressed in dB and presented as: max, mean, min and latest. The max, min and latest are true instantaneous measurements; the mean is the mean of a set of one second means.
8 Web Page Reference Link Capacity: The maximum aggregate data rate capacity available for user traffic, assuming the units have been connected using Gigabit Ethernet. The link capacity is variable and depends of the prevailing wireless conditions as well as the distance (range) between the two wireless units.. Transmit Modulation Mode: The modulation mode currently being used on the transmit channel.
8 Web Page Reference 8.2.1 Histogram Data The histogram is calculated over a one hour period. If the equipment has been running for less than one hour, then the histogram is calculated over the current elapsed time. The data used to compute the histogram statistics can be downloaded in an ASCII comma separated value (CSV) format via the diagnostics CSV Download page, see Section 8.3.12.2 “Diagnostics Download”.
8 Web Page Reference 8.3 System Administration Pages The following menu options are available for the system administrator and can be password protected. Figure 50 shows the system administration login page. By default a system administrator password is not set. Simply click the login button to access the system administration features.
8 Web Page Reference 8.3.1 System Configuration The configuration of the 600 Series Bridge is organized into three sections: x General configuration x LAN configuration x Telecoms Configuration x Save and Restore The general configuration allows modification of high level administrative (descriptive) attributes and high level wireless configuration. The LAN configuration sub menu allows the system administrator to modify the Ethernet and IP configuration of the 600 Series Bridge.
8 Web Page Reference While the majority of the system configuration is entered during installation and should never require changing, this page offers the system administrator the ability to change the basic system parameters for both the wireless and Ethernet components. Link Name: User defined identity for the unit (max 63 characters). Link Location: Can be used as a generic scratch pad to describe the location of the equipment.
8 Web Page Reference 8.3.1.2 LAN Configuration Page The LAN configuration page (Figure 52) is used by the system administrator to configure the 600 Series Bridge’s LAN interface. Figure 52 - LAN Configuration Page IP Address: Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. Subnet Mask: A subnet allows the flow of network traffic between hosts to be segregated based on a network configuration.
8 Web Page Reference Gateway IP Address: The IP address of a computer / router on the current network that acts as a gateway. VLAN High Priority Traffic Threshold: All packets with an 802.1P priority tag greater than or equal to the indicated value will be treated as a high priority packet for transmission over the wireless link. Use VLAN For Management Interfaces: This controls use of VLAN tags at the management interfaces (WWW/SNMP/SMTP/SNTP). See Section 8.3.1.
8 Web Page Reference Local Packet Filtering: When Local Packet Filtering is “Enabled”, the bridge learns the source MAC addresses of devices transmitting Ethernet packets on the local Ethernet network, and only bridges packets to the remote unit if the destination MAC address has not been learned as a 'local' device.
8 Web Page Reference NOTE: At this point you will lose connection to the unit. If you have just changed the IP Address you now have to reconnect to the unit using the address just set. 8.3.1.3 LAN Configuration Page – Use VLAN For Management Interfaces The layout of the LAN Configuration page changes if this attribute is enabled in order to allow the VLAN VID and VLAN Priority to be set, see Figure 55. The VLAN settings are applied only after the unit is rebooted.
8 Web Page Reference Use VLAN For Management Interfaces: This control can be configured with one of the following three values: x No VLAN Tagging x IEEE 802.1Q Tagged (C-Tag, Type 8100) x IEEE 802.1ad Tagged (S-Tag or B-Tag, Type 88a8) VLAN Management VID: This 802.1Q or 802.1ad VLAN ID (VID) will be included in packets generated by the management interfaces. Valid settings are in the range 0 to 4094. VLAN Management Priority: This 802.1Q or 802.
8 Web Page Reference CAUTION: Over the air throughput will be capped to the rate of the Ethernet interface at the receiving end of the link. 8.3.1.5 Save and Restore Configuration File The save and restore feature of a PTP 600 Series Bridge allows the system administrator to backup the operation configuration of the wireless unit. It is recommended that this facility is used immediately after a successful PTP 600 Series Bridge installation or prior to any software upgrade.
8 Web Page Reference Figure 58 - Save Configuration File Screen The configuration file is encoded using an ASCII encoding scheme. An example is show in Figure 59.
8 Web Page Reference CAUTION: The configuration file is currently restricted to a single software version and can only be restored into a wireless unit operating the software version indicated in the configuration file header. 8.3.1.5.2 Restore Configuration File The configuration file can also be used when swapping out a faulty wireless unit.
8 Web Page Reference Figure 61 - Reset Configuration and Reboot Confirmation Pop-up On confirmation the PTP 600 Series Bridge will: x Upload the configuration file x Perform data integrity checking x Erase previous configuration x Apply the new configuration x Restart After the unit has restarted the entire configuration from the configuration file will now be active. Note: The IP address of the unit may have also been changed.
8 Web Page Reference 8.3.1.6 Telecoms Configuration Page The Telecoms page is only available when the Telecoms Interface has been set to either T1 or E1 in the Installation Wizard. It displays the interface setting and line code for the available telecoms channels. The PTP 600 Series Bridge is able to support two T1 or E1 channels. However, in the “Lite” configuration one of these channels is disabled. The channels are referred to as "Channel A" and "Channel B".
8 Web Page Reference Cable Length: The Cable Length setting is applicable in T1 mode only and shows the cable length specified in the installation wizard. Loopback: Allows the T1 or E1 data stream to be looped back at the copper or wireless interface. During normal operation the loopback must be set to "None". It may be helpful during installation to test the telecoms links by performing loopback connections. A "Copper" loopback connects the received data on a given telecoms interface to the Transmit.
8 Web Page Reference 8.3.2 Statistics Page The 600 Series bridge statistics page is designed to display some key statistics of the Ethernet Bridge and the underlying wireless performance. The numbers in brackets display the number of packets received since the last page refresh. Figure 63 - System Statistics Wireless Tx Packets: This displays the total number of good packets the bridge has sent for transmission by the wireless interface.
8 Web Page Reference Ethernet Tx Packets: This displays the total number of good packets the bridge has sent for transmission by the local Ethernet interface. Ethernet Rx Packets: This displays the total number of good packets the bridge has received from the local Ethernet interface. Packets To Internal Stack: This displays the total number of good packets the bridge has transmitted to the internal stack (for example, ARP requests, PING requests, HTTP requests).
8 Web Page Reference Transmit Modulation Mode: The modulation mode currently being used on the transmit channel. The number in brackets after the modulation mode and coding rate string is the effective data rate available to all MAC layer protocols. List of all the modulation modes can be found in Section 16 “Data Rate Calculations” where data rate calculations plots are given for each available modulation mode. Receive Modulation Mode: The modulation mode currently being used on the receive channel.
8 Web Page Reference 8.3.
8 Web Page Reference The detailed counters page is subdivided into two columns. Column one presents the detailed statistics for the bridge’s Ethernet interface. Column two relates to the wireless interface. The Counters have the following definitions: Tx & Rx Octets: Total number of octets (bytes) transmitted or received over the interface. Rx Drops: Total number of frames dropped due to the lack of sufficient capacity in the receive buffer. Rx Packets: Total number of packets received by the interface.
8 Web Page Reference Tx Packets: Total number of packets received by the interface. This includes both good and bad packets. Tx Broadcasts: Total number of good broadcast packets. Tx Multicasts: Total number of good multicast packets. Tx Collisions: Total number frames experiencing collisions. Tx 64 Bytes: Total number 64 byte frames transmitted Tx 65 to 127 Bytes: Total number frames transmitted in the size range 65 to 127 bytes.
8 Web Page Reference 8.3.4 Install Pages These pages are used during system installation. There follows a description of the install pages along with their use during the installation configuration process. The actual installation process is described in Section 8.3.4.1 “Manually Configuring The Wireless Units”. NOTE: This section assumes that the integrated PTP 600 is being installed. If the connectorized variant is being installed, refer to Section 13.
8 Web Page Reference 00:04:56:80:0F:C7 00:04:56:80:0F:FF License Key License Key A471-FE88-428D-E1F3 534F-4F54-D1B0-E2DA IP Address IP Address 169.254.1.2 169.254.1.1 CAUTION: The factory default configuration is limited in range to 40 Km (25 miles). If you wish to install a wireless link with a range of > 40 Km (> 25 miles) and < 200 Km (< 124 miles) or < 5 Km (< 3 miles) you must follow the ‘Manually Configuring The Wireless Units’ in Section 8.3.4.1.
8 Web Page Reference Figure 65 - License Key Data Entry A license key is programmed into each unit during production and can be found written on the Configuration Data Summary Label which is attached to the Quick Install Guide. If subsequently the license key has been mislaid, replacement keys can be applied for online or via your distributor. If a valid license key is not detected in the unit’s non-volatile memory then the user is prompted to enter a valid key.
8 Web Page Reference 8.3.4.2 Internet Protocol Configuration Step 1 of the installation wizard requires the installer to enter the Internet Protocol (IP) configuration. Figure 66 - Installation Wizard Internet Protocol Configuration IP Address: Internet protocol (IP) address. This address is used by the family of Internet protocols to uniquely identify this unit on a network. Subnet Mask: A subnet allows the flow of network traffic between hosts to be segregated based on a network configuration.
8 Web Page Reference Telecoms Interface This allows the activation of the 600 Series bridge telecoms interface. The selection options are None, E1 or T1. Mixed T1/E1 configurations are not permitted. Figure 67 - VLAN Warning Once complete, click the ‘Submit Internet Protocol Configuration’ button or the ‘Next’ link.
8 Web Page Reference 8.3.4.3 Telecoms Interface If the telecoms interface is configured to either T1 or E1 then Step 1 of the installation wizard contains additional configuration fields. Figure 68 - Telecoms Configuration Interface The additional E1 or T1 fields are: Telecoms Channel Selection: This controls the selection of the telecoms interface standard supported options or T1 and E1. Channel A Line Code: The line code setting of the telecoms interface.
8 Web Page Reference 8.3.4.4 Wireless Configuration Step 2 of the installation wizard requires the installer to enter the wireless configuration parameters. Figure 69 is an example of the Wireless Configuration screen.
8 Web Page Reference The contents of the Wireless Configuration screen vary depending upon the PTP 600 variant as follows: x PTP 25600: Frequency Band field is also displayed. x PTP 48600 and PTP 49600: Channel Bandwidth options are 20, 10 and 5 MHz. x PTP 49600: Lower Center Frequency is not displayed.
8 Web Page Reference In IP Mode, the PTP 600 product runs an Adaptive TDD scheme. Basically an unloaded link runs 10:10 mode (10 OFDM bursts alternately in each direction). A sustained traffic load in one direction for example may cause a threshold to be reached where the TDD mode automatically adapts to say 20:10. If the load continues to increase, then the TDD structure may adapt even further through 30:10 to 40:10.
8 Web Page Reference Secondly, the point at which a modulation mode changes for given RF conditions is more conservative. In practice, this means that the link will typically stay in a lower modulation mode, but with increased tolerance to RF variability. Depending upon the link characteristic that the customer requires, this may very well be the best choice. It increases consistency of link performance and equality in each direction as a trade-off against maximum throughput.
8 Web Page Reference Frequency Band: Only displayed for the PTP 25600 product variant, which operates in one of three bands as described in Section 5.4 “Variable Channel Bandwidth Operation”: x Lower: 2496 MHz to 2568 MHz x Middle: 2572 MHz to 2614 MHz x Upper: 2624 MHz to 2690 MHz Channel Bandwidth: Users can choose a variable channel bandwidth for the available spectrum.
8 Web Page Reference CAUTION: The lower center frequency attribute must be configured to the same value for both the master and slave. Failure to do so will cause the wireless link to fail reestablishment. The only way to recover from this situation is to modify the Lower Center Frequency attribute so that they are identical on both the master and slave unit. Default Raster: If this is set to “On”, the list of options presented in the fixed Tx frequency box is limited by the default raster.
8 Web Page Reference Installation Tones: Where the use of audio installation tones is not required, this control allows the installer to optionally disable the tone generator during the installation process. Once the installer is satisfied with the wireless configuration options then the “Submit Wireless Configuration” button or the “Next” link should be clicked.
8 Web Page Reference 8.3.4.5 Confirm Configuration Step 3 of the installation wizard requires the installer to confirm the wireless configuration parameters. Figure 71 is an example of the Confirm Configuration screen. The screen contents vary depending upon the product variant and configuration options selected.
8 Web Page Reference If the settings are correct and appropriate, click the “Confirm Configuration, Arm Installation and Reboot” button. The user will now be prompted to confirm the action (Figure 72). Figure 72 - Reboot Confirmation Pop Up All the attributes are committed to non-volatile memory. Immediately following the write to non-volatile memory the unit is reset. NOTE: If you have changed the Ethernet parameters you must reconnect using the correct network and address settings.
8 Web Page Reference 8.3.4.6 Disarm Figure 73 is an example of the Disarm Installation screen. The screen contents vary depending upon the product variant and configuration options selected.
8 Web Page Reference When Section 8.3.4.5 “Confirm Configuration” is complete, the installation is armed and rebooted. Pressing the “Disarm Installation Agent” button completes the installation process and the audible installation tone will be switched off. If the installer wishes to modify the installation configuration then the ‘Back’ link can be used to access the installation wizard steps described above. The installation process is completed when both ends of the link are ‘disarmed’.
8 Web Page Reference 8.3.5 Graphical Install To aid the installation of wireless links two graphical installation aids have been introduced in this 600 Series system version. x A PDA installation screen x A larger installation screen available from the main HTTP management interface. The design of the installation screen has been deliberately kept simple and uncluttered. An example of the installation screen is shown in Figure 76.
8 Web Page Reference For the more technically, aware the installation metric is simply the instantaneous receive power in dBm + 100. The PDA installation tool is accessed via a hidden URL http:///pda.cgi. It should be noted that this link is only available after the user has logged in as system administrator. The large screen version of the graphical user interface is available as a submenu option of the installation wizard. 8.3.
8 Web Page Reference The software upgrade pages are used to update a unit’s operational software. The software image to be uploaded should be downloaded to local storage from the Motorola web site. The software image is delivered by Motorola as a compressed zip file. Once the zip file has been downloaded, the user should extract the PTP 600 Series Software image, identifiable by its ‘.dld’ file extension.
8 Web Page Reference The user should ensure that the correct image is shown before pressing the “Program Software Image into Non-Volatile Memory” button. Once this button has been pressed the image is stored into non-volatile memory, this process can take up to 60 seconds and must not be interrupted. CAUTION: If the upgrade process is interrupted during the erasure of the image bank, or during the reprogramming of the image bank, the image bank will be left in a corrupt state.
8 Web Page Reference Reboot the unit by clicking the “Reboot Wireless Unit” button. You will be asked to confirm this action as shown in Figure 81. Figure 81 - Reboot Confirmation Pop Up This will reboot the unit, taking up to 120 seconds. During this time you will not be able to communicate with the unit. If you cannot communicate with the unit after 120 seconds, this could indicate a problem with the memory update process.
8 Web Page Reference 8.3.7 Spectrum Management Spectrum Management Selection is the PTP 600 Series Bridge feature that monitors the available wireless spectrum and directs both ends of the wireless link to operate on a channel with a minimum level of co-channel and adjacent channel interference. 8.3.7.1 Wireless Channels The PTP 600 Series Bridge operates using a set of predefined overlapping channels. There are a different number of channels, depending on the raster mode selected.
8 Web Page Reference The analysis produces three key metrics for each channel: x Peak of Means x 99.9% Percentile of the Means x Mean of Means Peak of Means is the largest mean interference measurement encountered during the quantization period. The peak of means is similar to the peak of peaks and is useful for detecting slightly longer duration spikes in the interference environment. 99.9% Percentile of the Means is the value of mean interference measurement which 99.
8 Web Page Reference All configuration changes are applied at the master only. These changes are then messaged from the master to the slave. Any Spectrum Management configuration messages received at the slave are stored in non-volatile memory. This enables both master and slave to keep identical copies of Spectrum Management configuration data in their non-volatile memories.
8 Web Page Reference Figure 83 - Spectrum Management as seen from the Slave NOTE: These plots are for 30 MHz operation; 5/10/15/20 MHz operation is similar - the width of the vertical green bar represents the channel width. Figure 82 shows an example Spectrum Management webpage as seen from the master. Figure 83 shows an example Spectrum Management webpage as seen from the slave. It should be noted that the key configuration attributes are not available on the slave web page.
8 Web Page Reference 8.3.7.5 Spectrum Management Configuration The following section describes the user modifiable configuration accessible from the Spectrum Management webpage. It is recommended that the default values are maintained. If the user believes that the performance of the Spectrum Management algorithm requires some modifications this should only be done after consulting your Motorola Point-to-Point distributor or one of the system field support engineers.
8 Web Page Reference 8.3.7.6 Barring Channels Channels can only be barred / unbarred by the system administrator from the master Spectrum Management web page. The barring / unbarring operations are disabled on the slave web page. If an attempt to bar / unbar a channel is made at the slave, a warning dialog is generated. Barring/Unbarring of channels is performed by clicking the appropriate channel on the local or peer channel spectrum plots on the master web page.
8 Web Page Reference The colored bar represents the following channel state: Table 34 - Spectrum Management change state key Green Active The channel is currently in use, hosting the Point-to-Point wireless link Orange Interference The channel has interference above the interference threshold Available The channel has an interference level below the interference threshold and is considered by the Spectrum Management algorithm suitable for hosting the Point-to-Point link Barred The system administr
8 Web Page Reference 8.3.7.8 Active Channel History The active channel history is a time series display of the channels used by the PTP 600 Series Bridge over the last 25 hours. The active channel history is activated from the main Spectrum Management page using the ‘Active Channel History’ hyperlink. An example of the active channel history display is shown in Figure 85.
8 Web Page Reference 8.3.7.9 Viewing Historic Spectrum Management Metrics Spectrum Management allows the system administrator to view the results of previous measurement quantization periods. Holding down the shift key and clicking the appropriate channel on the local channel spectrum plots activates this feature. This feature is available on both the master and slave web page. Figure 86 - Spectrum Management Time Series Plot Figure 86 shows an example time series plot.
8 Web Page Reference 8.3.8 Spectrum Management (Fixed Frequency) The PTP 600 Series Bridge software allows a user to optionally fix transmit and receive frequencies for a wireless link. Once configured, the spectrum management software will not attempt to move the wireless link to a channel with lower co and adjacent channel interference. Therefore this mode of operation is only recommended for deployments where the installer has a good understanding the prevailing interference environment. (See Section 8.
8 Web Page Reference The only controls available to the master are the Statistics Window and Interference Threshold attributes. They will have no effect on the operation of the wireless link and will only effect the generation of the channel spectrum graphics. The active channel history menu is removed in this mode of operation as channel hopping is prohibited. Figure 88 - Spectrum Management Help Page (Fixed Frequency) 8.3.
8 Web Page Reference x Extra color coding of the interference histogram is provided. See Table 36. When operating with RTTT (Road transport and Traffic Telematics) Avoidance enabled or other regulatory restrictions on channel usage the following variances apply: x All channels marked with a ‘no entry’ symbol with their associated statistics colored black are the prohibited channels. See Figure 89 and Figure 90.
8 Web Page Reference Figure 90 - Spectrum Management Slave Screen With Operational Restrictions The colored bar represents the following channel state: Table 36 - Spectrum Management Change State Key With Operational Restrictions Green Active The channel is currently in use hosting the Point-to-Point wireless link Orange Interference The channel has interference above the interference threshold Blue Available The channel has an interference level below the interference threshold and is considered
8 Web Page Reference Region Bar Region Bar This channel has been barred from use by the local region regulator 8.3.10 Spectrum Management – Example of PTP 25600 Product variant As described in Section 5.5 “PTP 25600 Specific Frequency Planning Considerations”, the PTP 25600 product variant can operate in three frequency bands. Figure 91 shows an example of a Lower Band with a 30 MHz channel bandwidth.
8 Web Page Reference 8.3.11 Remote Management Page The Remote Management page (Figure 92) allows the system administrator to configure the remote management of the PTP 600 Series Bridge.
8 Web Page Reference 8.3.11.1 Control Access to HTTP Interface The attribute HTTP Access Enabled allows a user to stop any access to a unit via the web interface. The default value for this control is set to “yes”, which means that the unit can be accessed using the web interface. If the option “No” is selected, then a warning is displayed as shown in Figure 93. 8.3.11.
8 Web Page Reference SNMP TRAPs supported: x Cold Start x Link Up x Link Down x DFS Channel Change x DFS Impulsive Interference Figure 93 – Warning when disabling HTTP interface 188
8 Web Page Reference 8.3.11.5 Diagnostics Alarms A number of diagnostics alarms have been added to allow SNMP agents to receive traps and emails if required. Refer to Section 8.1.1 “Home Page Alarm Display” for a description of all these alarms. Checking the control “Enabled Diagnostic Alarms” in SNMP and/or SNTP selects all the alarms shown in Figure 94. Users can access the sub-menu “Diagnostic Alarms” to modify the alarms selected.
8 Web Page Reference 8.3.11.6 SNMP Configuration SNMP State: The SNMP state attribute controls the creation of the SNMP features. Changing the SNMP state attribute requires a mandatory reboot of the unit. Only when the SNMP state is enabled at system start-up will the SNMP processor task be created. SNMP Enabled Traps: The SNMP Enabled Traps attribute controls which SNMP Traps the unit will send.
8 Web Page Reference SMTP Port Number: The SMTP Port Number is the port number used by the networked SMTP server. By convention the default value for the port number is 25. SMTP Source Email Address: The email address used by the 600 Series to log into the SMTP server. This must be a valid email address that will be accepted by your SMTP Server. SMTP Destination Email Address: The email address to which the 600 Series bridge will send the alert messages. 8.3.11.
8 Web Page Reference Set Date: Displays the current date. The year, month and day can be set using the dropdown selection boxes. Time Zone: See Section.8.3.11.9 “Setting the clock”. Daylight Saving: See Section 8.3.11.9 “Setting the clock” 8.3.12 Diagnostics To further enhance the diagnostic capabilities of the PTP 600 Series, the storage of link performance histograms has been extended to 31. To optimize RAM (volatile memory) usage a cascading histogram approach has been adopted.
8 Web Page Reference 8.3.12.1 Diagnostic Plotter New for the PTP 600 Series is the system administration diagnostic plotter facility see Figure 95. Figure 95 - Diagnostic Plotter The diagnostic plotter allows the system administrator to view the cascading histogram data in an easily accessible graphical form. The plot always displays three traces, maximum, minimum and mean by default. The diagnostic selector allows the user to select the various categories of histogram.
8 Web Page Reference The trace selection allows the user to control which traces are plotted. As with other management pages the page refresh period can be used to interactively monitor the wireless link. 8.3.12.2 Diagnostics Download The diagnostics Download page allows the system administrator to download snapshots of system diagnostics.
8 Web Page Reference 8.3.13 Change System Administration Password This page (Figure 97) is used to change the password for the system administration (The factory default is blank). Figure 97 - Password Change The password may contain any combination of characters, up to 31 characters in length. 8.3.14 License Key The License Key data entry page allows the system administrator to update the 600 Series bridge license key. Figure 98 shows a sample license key data entry page.
8 Web Page Reference The user must enter the license key and click the ‘Validate License Key’ button to check that the key is valid and program it to non-volatile memory. If a valid license key is detected then the user will be presented by a system reboot screen. Figure 99: License Key reboot Screen The user will then be asked to confirm the reboot (Figure 100).
8 Web Page Reference 8.3.15 Properties The web page properties screen allows the user to configure the web page interface. Figure 101 – Properties WEB Properties: Disable Front Page Login. Allows access to homepage and status page web pages without forcing a login as the system administrator. WEB Properties: Disable HTTP NO-CACHE META data. Removes the HTTP NO-CACHE META clause from all dynamically created web pages.
8 Web Page Reference 8.3.16 Reboot The reboot page allows the system administrator to perform commanded reboots of the wireless unit. The reboot page also allows the system administrator to view a list of past reboot reasons. The “Previous Reasons For Reset/Reboot” field has been implemented as a drop down selection box, where the latest reason for reboot is located at the top of the list.
9 Recovery Mode 9 Recovery Mode The Motorola PTP 600 point-to-point wireless Ethernet bridges have a special mode of operation that allows the user to recover a unit from configuration errors or software image corruption. Recovery mode is entered by depressing the Recovery Switch located on the underside of the PIDU Plus while applying mains power, as shown in Section 3.3.
9 Recovery Mode Clicking on the warning page image will take the user on to the Recovery Option Page (Figure 105). Figure 105 - Recovery Options Page The recovery options available are: Upgrade Software Image: This allows the user to reload a software image. This may be the original image if software corruption is suspected or a step back to an old image if an incorrect image has just been loaded.
9 Recovery Mode Recovery Reason: Indicates the reason the unit is operating in Recovery mode. Possible reasons are “Recovery button active” or “Invalid or corrupt image” MAC Address: The MAC address shown here is the MAC address of the unit programmed during manufacture. 9.1 Upgrade Software Image The first step (Figure 105) is to use the ‘Browse’ button to locate the software image to be downloaded.
9 Recovery Mode After carefully checking that correct image has been downloaded the user should reboot the unit by pressing the “Reboot Wireless Unit” button. The user will then be presented with a pop up box asking them to confirm the action (Figure 108). Figure 108 - Reboot Confirmation Pop Up The unit will now reboot. Providing the unit configuration is still intact the unit should restart in normal operational mode and the link should recover.
9 Recovery Mode 9.2 Reset IP & Ethernet Configuration To reset IP & Ethernet configuration back to factory defaults the user should press the “Reset IP & Ethernet Configuration back to factory defaults” button on the “Recovery Options” page (Figure 105). The user will now be presented with a pop up box asking them to confirm the 1 action (Figure 109). Figure 109 - Confirm Reset to Factory Default Pop Up On confirmation the following page will be displayed (Figure 110).
9 Recovery Mode The user will now be presented with a pop up box asking them to confirm the action (Figure 111). Figure 111 - Reboot Confirmation Pop Up The unit will now reboot. The unit should now start up in normal mode but with the IP address set to 169.254.1.1 and the Ethernet interface set to auto-negotiate and auto-MDI/MDIX. Should the unit fail to start up the user should refer to Section 11 “ (Fault Finding”. 9.
9 Recovery Mode On confirmation the following page will be displayed (Figure 113). The user should now reboot the unit by pressing the “Reboot” button.
9 Recovery Mode The user will now be presented with a pop up box asking them to confirm the action (Figure 114) Figure 114 – Erase Configuration - Reboot Confirmation Pop Up The unit will now reboot. The unit should now start up in normal mode but with all configuration erased. Should the unit fail to start up the user should refer to Section 11 “ (Fault Finding”.
9 Recovery Mode 9.4 Reboot This option can be used to reboot the unit. The user will now be presented with a pop up box asking them to confirm the action (Figure 115). Figure 115 – Recovery - Reboot Confirmation Pop Up The unit will now reboot. The unit should now start up in normal operational mode. Should the unit fail to start up the user should refer to Section 11 “Troubleshooting (Fault Finding)”.
10 Lightning Protection 10 Lightning Protection CAUTION: EMD (Lightning) damage is not covered under standard warranty. The recommendations in this user manual, when implemented correctly, give the user the best protection from the harmful effects of EMD. However 100% protection is neither implied nor possible. 10.
10 Lightning Protection The following diagrams (Figure 116 & Figure 117) show this zoning pictorially: Equipment mounted in Zone A should be capable of carrying the full lightning current. Mounting of the ODU in Zone A is not recommended. Mounting in Zone A should only be carried out observing the rules governing installations in Zone A Failure to do so may put structures, equipment and life at risk. NOTE: Local regulations may also require the fitting of the 8 AWG ground wire referred below.
10 Lightning Protection Figure 117 - Showing how the use of a Finial enables the ODU to be mounted inside Zone B Table 37 - Protection Requirements Component Zone A Zone B Earth ODU Mandatory Mandatory Screen Cable Mandatory Mandatory Lightning Protection Unit at ODU – PTP-LPU Mandatory Mandatory Earth Cable at Building Entry Mandatory Mandatory Lightning Protection Unit at Building Entry – PTP-LPU Mandatory Mandatory 210
10 Lightning Protection 10.2 Detailed Installation The PTP LPU can be installed in one of the following configurations: x Option 1: Back-to-Back with the ODU using the supplied brackets delivered part of the installation of a link. This is the configuration recommended by Motorola. x Option 2: using the U-Bolt bracket supplied with the PTP LPU Kit. Typical examples of these two configurations are shown in Figure 118 and Figure 119. NOTE: Grounding Points are shown unprotected for clarity.
10 Lightning Protection Figure 119 - PTP-LPU - Installation Option 2 (Using U-Bolt) A second Lightning protection Unit should be mounted at the building entry point and must be grounded. The PTP-LPU Kit is supplied with a 600mm ODU to PTP-LPU cable pre-fitted with glands. Figure 120 shows all the components that are supplied with the Motorola Kit 2907.
10 Lightning Protection Figure 120 - PTP LPU Full Kit The cable between the two lightning protection units (top and bottom) should be of the type recommended by Motorola (Section 3.3.5 “Cables and connectors”) and terminated as shown in Figure 38.
10 Lightning Protection 10.3 Installation Wiring Figure 121 shows the correct installation wiring for a PTP 600 with lightning protection.
10 Lightning Protection 10.4 LPU Recommended Configurations This section contains diagrams to show how the components of PTP 600 sites are installed and connected.
10 Lightning Protection 10.4.1 Typical Mast or Tower Installation Figure 122 shows a typical PTP 600 Series Mast or Tower installation using PTP-LPU Surge protection for a configuration without a GPS Sync box or E1/T1 ports.
10 Lightning Protection 10.4.2 Typical Wall Installation Figure 123 shows a typical PTP 600 Series Wall installation using PTP-LPU Surge protection for a configuration without a GPS Sync box or E1/T1 ports.
10 Lightning Protection 10.4.3 Mast or Tower Installation with E1/T1 Figure 124 shows a typical PTP 600 Series Mast or Tower installation using PTP-LPU Surge protection for a configuration that includes E1/T1 ports.
10 Lightning Protection 10.4.4 Wall Installation with E1/T1 Figure 125 shows a PTP 600 Series Wall installation using PTP-LPU Surge protection for a configuration that includes E1/T1 ports.
10 Lightning Protection 10.4.5 Mast or Tower Installation with GPS Sync Box Figure 126 shows a PTP 600 Series Mast or Tower installation using PTP-LPU Surge protection for a configuration that includes a GPS Sync box.
10 Lightning Protection 10.4.6 Wall Installation with GPS Sync Box Figure 127 shows a PTP 600 Series Wall installation using PTP-LPU Surge protection for a configuration that includes a GPS Sync box.
10 Lightning Protection 10.4.7 Mast or Tower Installation with GPS Sync Box and E1/T1 Figure 128 shows a PTP 600 Series Mast or Tower installation using PTP-LPU Surge protection for a configuration that includes a GPS Sync box and E1/T1 ports.
10 Lightning Protection 10.4.8 Wall Installation with GPS Sync Box and E1/T1 Figure 129 shows a PTP 600 Series Wall installation using PTP-LPU Surge protection for a configuration that includes a GPS Sync box and E1/T1 ports.
11 Troubleshooting (Fault Finding) 11 Troubleshooting (Fault Finding) Perform troubleshooting (fault finding) procedures either on a newly installed link, or on an operational link if communication is lost: 1. Test the hardware at one end of the link, as described in Section 11.1 “Test Link End Hardware”. 2. Test the hardware at the other end of the link, as described in Section 11.1 “Test Link End Hardware”. 3. Test the radio link, as described in Section 11.2 ”Test Radio Link”. 11.
11 Troubleshooting (Fault Finding) Figure 130 – Link End Hardware Test Flowchart Start Is the green No No Is the power power LED LED Power LED is on solid? flashing? Off (11.1.1) Yes Yes Power LED Flashes (11.1.2) No Did the Ethernet LED did Ethernet not Flash 10 Times LED flash 10 (11.1.3) Yes Is Ethernet No No Is there any activity now Ethernet normal? activity? No Ethernet Activity (11.1.4) Yes Yes Irregular Ethernet Is Ethernet No Activity (11.1.
11 Troubleshooting (Fault Finding) 11.1.1 Power LED is Off If the green Power LED does not light up at all, perform the following tests: 1. Remove the power lead from the PIDU and test that the power source (mains or 56 V battery) is working. 2. If the main or battery power supply is working, open the flap on the left hand side of the PIDU and remove the RJ45 ODU cable from the PIDU. 3. If the Power LED does not illuminate when the RJ45 ODU cable is removed: i.
11 Troubleshooting (Fault Finding) 11.1.2 Power LED is Flashing If the green Power LED flashes, perform the following tests on the RJ45 cable that connects the PIDU to the LPU or ODU: 1. Check that pins 4&5 and 7&8 are not crossed with pins 1&2 and 3&6. 2. Check that the resistance between pins 1&8 is greater than 100K ohms. 3. If either test fails, replace or repair the RJ45 cable. 11.1.
11 Troubleshooting (Fault Finding) Figure 131 - PTP LPU Test Points 3. If either test fails, replace or repair the RJ45 cable. 11.1.4 No Ethernet Activity If the Ethernet LED did flash 10 times but then went off, check that the RJ45 connection from the LAN port of the PIDU to the PC is working. If the PC connection is working, perform the following tests on the RJ45 cable that connects the PIDU to the LPU or ODU: 1. Check that the wiring to pins 1&2 and 4&6 is correct.
11 Troubleshooting (Fault Finding) 11.1.5 Irregular Ethernet Activity The yellow Ethernet LED should blink randomly as normal traffic passes through. If the Ethernet LED flashes irregularly, for example there is a short flash followed by a long flash, this indicates that the ODU has booted in recovery mode. The causes may be installation wiring or a corrupt ODU software load. For more information, see Section 9 “Recovery Mode”. 11.1.
11 Troubleshooting (Fault Finding) Table 38 - Resistance Table Referenced To The RJ45 at the PIDU+ Resistances should fall within + or -10% of the stated values. CAT-5 Length (Meters) Resistance between pins 1&2, 3&6 , 4&5 and pins 7&8 (ohms) Resistance between pins 1&3 (ohms) Resistance between pins 4&7 (ohms) 0 0.8 1.0 1.6 10 2.7 2.7 3.3 20 4.6 4.4 5.0 30 6.5 6.1 6.7 40 8.3 7.8 8.4 50 10.2 9.5 10.1 60 12.1 11.2 11.8 70 14.0 12.9 13.5 80 15.8 14.6 15.2 90 17.7 16.
11 Troubleshooting (Fault Finding) 11.2 Test Radio Link 11.2.1 No Activity If there is no communication over the radio link and the unit at the other end of the link can be managed on its local network, the following procedure should be adopted: If there is no wireless activity then the configuration should be checked.
12 Wind Loading 12 Wind Loading 12.1 General Antennas and electronic equipment mounted on towers or pole mounted on 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. 12.
12 Wind Loading NOTE: When the connectorized version of 600 Series bridge is used with external antennas, the figures from the antenna manufacturer for lateral force should be included to calculate to total loading on the mounting structure. 12.3 Capabilities of the PTP 600 Series Bridges The structure and mounting brackets of the PTP Series systems are capable of withstanding wind speeds up to 151mph (242 kph).
13 Connectorized PTP 600 Series Bridge 13 Connectorized PTP 600 Series Bridge 13.1 Scope This section details the changes and additional features relevant to the connectorized version of the PTP 600 Series products.. 13.2 Product Description 13.2.1 Hardware The Connectorized PTP 600 Series Bridge is a variant designed to provide the system integrator and installer with the ability to provide extra capability to cope with very difficult radio links compared to the PTP 600 Series Integrated model.
13 Connectorized PTP 600 Series Bridge 13.3 Software/Features This section only describes the areas where functionality is modified for the connectorized variant. For details of the functionality that is common to the integrated and connectorized variants, see Section 8 “Web Page Reference”. 13.3.1 Status Page The link loss calculation presented on the Status Page of the management interface has to be modified to allow for the increased antenna gains at each end of the link.
13 Connectorized PTP 600 Series Bridge 13.3.2 Configuration Pages The Configuration web page for the connectorized variant is shown in Figure 134. The parameters Antenna Gain, Cable Loss and EIRP are specific to the connectorized variant.
13 Connectorized PTP 600 Series Bridge 13.3.3 Installation Pages The installer is prompted to enter the Antenna Gain and Cable Loss (Connectorized PTP 600 Series Bridge to antenna) at each end of the link. The Installation Pages for the connectorized version are shown as Figure 135 to Figure 137. Figure 135 - Connectorized PTP 600 Series Bridge ‘Installation Wizard’ Page Antenna Gain: Gain of the antenna you are connecting to the unit, see Section 13.6.2 “Antenna Choices”.
13 Connectorized PTP 600 Series Bridge Spectrum Management Control: Is used to configure the 600 Series Bridge Spectrum Management features, see Section 8.3.7 “Spectrum Management” for more details. iDFS is the abbreviation for intelligent Dynamic Frequency Selection, which continually monitors the spectrum looking for the channel with the lowest level of on channel and co-channel interference. Fixed frequency mode allows the installer to fix the Transmit and receive frequencies on the units.
13 Connectorized PTP 600 Series Bridge EIRP: The Confirm Installation Page displays the EIRP (Effective Isotropic Radiated Power), which describes the strength of the radio signal leaving the wireless unit. This allows the operator to verify that their link configuration (Max Transmit Power, Antenna Gain and Cable Loss) do not cause the link to exceed any applicable regulatory limit.
13 Connectorized PTP 600 Series Bridge 13.4 Deployment Considerations The majority of radio links can be successfully deployed with the 600 Series. It should only be necessary to use external antennas where the LINKPlanner indicates marginal performance for a specific link – for example when the link is heavily obscured by dense woodland on an NLOS link or extremely long LOS links (>80km or >50 miles) over water.
13 Connectorized PTP 600 Series Bridge 13.6.1 Cable Losses (FCC Regions Only) The FCC approval for the product is based on tests with a cable loss between the units of not less than 1.2dB at 5.8GHz. The use of lower cable losses would result in the installation being outside the FCC rules. As an indication, 1.2dB of cable loss corresponds to the following cable lengths excluding connector losses (source: Times Microwave). Table 41 - Cable Losses per Length Length for 1.2dB Cable Loss at 5.
13 Connectorized PTP 600 Series Bridge 13.6.3 FCC Antenna Restrictions on the PTP 58600 In FCC regions, external antennas from the list in Table 42 can be used with the Connectorized version of the PTP 600 Series Bridge. These are approved by the FCC for use with the product and are constrained by the following limit for Single/Dual Polarization Parabolic Dish Antennas: up to 37.7 dBi per polarization or antenna.
13 Connectorized PTP 600 Series Bridge Gain (dBi) Flat Plate Parabolic Dish Manufacturer Antenna Type Andrew Andrew 3-foot Parabolic, P3F-52 (33.4dBi) 33.4 Y Andrew Andrew 3-foot Dual-Pol Parabolic, PX3F-52 (33.4dBi) 33.4 Y Andrew Andrew 4-foot Parabolic, P4F-52 (34.9dBi) 34.9 Y Andrew Andrew 4-foot Dual-Pol Parabolic, PX4F-52 (34.9dBi) 34.9 Y Andrew Andrew 6-foot Parabolic, P6F-52 (37.6dBi) 37.6 Y Andrew Andrew 6-foot Dual-Pol Parabolic, PX6F-52 (37.6dBi) 37.
13 Connectorized PTP 600 Series Bridge Gain (dBi) Flat Plate Parabolic Dish Manufacturer Antenna Type Gabriel Gabriel 2-foot Standard Dual QuickFire Parabolic, QFD2-52-N 28.4 Y Gabriel Gabriel 2.5-foot Standard Dual QuickFire Parabolic, QFD2.5-52-N 31.1 Y Gabriel Gabriel 2-foot Standard Dual QuickFire Parabolic, QFD2-52-N-RK 28.4 Y Gabriel Gabriel 4-foot Standard Dual QuickFire Parabolic, QFD4-52-N 34.7 Y Gabriel Gabriel 4-foot Standard Dual QuickFire Parabolic, QFD4-52-N-RK 34.
13 Connectorized PTP 600 Series Bridge Gain (dBi) Flat Plate Parabolic Dish Manufacturer Antenna Type RFS RFS 4-foot Parabolic, SPF4-52AN or SPFX4-52AN(33.9dBi) 33.9 Y RFS RFS 6-foot Parabolic, SPF6-52AN or SPFX6-52AN (37.4dBi) 37.4 Y RFS RFS 2-foot HP Parabolic, SDF2-52AN or SDFX2-52AN (31.4dBi) 31.4 Y RFS RFS 4-foot HP Parabolic, SDF4-52AN or SDFX4-52AN (33.9dBi) 33.9 Y RFS RFS 6-foot HP Parabolic, SDF6-52AN or SDFX6-52AN (37.4dBi) 37.
13 Connectorized PTP 600 Series Bridge 13.6.4 FCC Antenna Restrictions on the PTP 54600 In FCC regions, external antennas from the list in Table 43 can be used with the Connectorized version of the PTP 54600. These are approved by the FCC for use with the product and are constrained by the following limit for Single/Dual Polarization Parabolic Dish Antennas: up to 34.9 dBi (33.4 dBi for 5 MHz bandwidth) per polarization or antenna.
13 Connectorized PTP 600 Series Bridge Gain (dBi) Parabolic Dish Gabriel 2-foot Standard QuickFire Parabolic, QF2-52-N-RK 28.5 Y Gabriel Gabriel 2.5-foot Standard QuickFire Parabolic, QF2.5-52-N 31.2 Y Gabriel Gabriel 4-foot Standard QuickFire Parabolic, QF4-52-N 34.8 Y Gabriel Gabriel 4-foot Standard QuickFire Parabolic, QF4-52-N-RK 34.8 Y Gabriel Gabriel 2-foot Standard Dual QuickFire Parabolic, QFD2-52-N 28.4 Y Gabriel Gabriel 2.5-foot Standard Dual QuickFire Parabolic, QFD2.
13 Connectorized PTP 600 Series Bridge Gain (dBi) Parabolic Dish RFS 3-foot Parabolic, SPF3-52AN or SPFX3-52AN(31.4dBi) 31.4 Y RFS RFS 4-foot Parabolic, SPF4-52AN or SPFX4-52AN(33.9dBi) 33.9 Y RFS RFS 2-foot HP Parabolic, SDF2-52AN or SDFX2-52AN (31.4dBi) 31.4 Y RFS RFS 4-foot HP Parabolic, SDF4-52AN or SDFX4-52AN (33.9dBi) 33.
13 Connectorized PTP 600 Series Bridge 13.7 Installation The section covers the generic installation instructions for the Connectorized versions of the PTP 600 Series point-to-point wireless Ethernet bridges. The actual installation procedure will depend on antenna choice, cable choice, required antenna separation etc. 13.7.1 Antenna Choice Section 13.6.3 “FCC Antenna Restrictions on the PTP 58600” and Section 13.6.
13 Connectorized PTP 600 Series Bridge 13.7.4 Miscellaneous supplies The following miscellaneous supplies will be required: x Cable ties, cable cleats – for securing cables x Self-amalgamating tape – to weatherproof the RF connectors x PVC tape – for additional protection of the RF connectors and securing cables 13.7.5 Mounting the Connectorized 600 Series Bridge A Connectorized 600 Series bridge is shipped with the same bracket as supplied with an Integrated unit.
13 Connectorized PTP 600 Series Bridge 13.7.7 Alignment Process When aligning antennas deployed with a Connectorized 600 Series bridge unit it may not be possible to hear the alignment tone emanating from the unit. In this case it may be necessary for a second installer to assist in the operation. Alternatively, it may be possible to extend the tube on the supplied stethoscope to give a longer reach.
13 Connectorized PTP 600 Series Bridge Step 10: Align the second antenna using the tones as described in Section 7.7.11 “Aligning the PTP 600 Series Bridge ODUs”. Step 11: Re-connect the second antenna to the Connectorized 600 Series bridge (Note: you will notice the tone pitch increase as you re-connect the second antenna due to the additional received signal). Step 12: Use the relevant status web pages to check that you are getting the results you expect from your link planning.
13 Connectorized PTP 600 Series Bridge 13.7.12 Antenna Connection Weatherproofing Where a cable connects to an antenna or unit from above, a drip loop should be left to ensure that water is not constantly channeled towards the connector. Figure 138 - Forming a Drip Loop All joints should be weatherproofed using self-amalgamating tape.
13 Connectorized PTP 600 Series Bridge 13.8 Additional Lightning Protection The following guidelines should be applied in addition to those described in Section 10 ”Lightning Protection”. 13.8.1 ODU Mounted Outdoors Where the ODU is mounted outdoors and is mounted some distance from the antenna, it is advisable to add additional grounding by utilizing Andrew Assemblies (such as Andrew Type 223158 www.andrew.com) as shown in Figure 140.
13 Connectorized PTP 600 Series Bridge 13.8.2 ODU Mounted Indoors Where the ODU is mounted indoors, lightning arrestors should be deployed where the antenna cables enter the building as shown in Figure 141. Figure 141 - Lightning Arrestor Mounting The lighting arrestors should be ground bonded to the building ground at the point of entry. Motorola recommends Polyphaser LSXL-ME or LSXL lighting arrestors. These should be assembled as show in Figure 142.
14 TDD Synchronization Configuration and Installation Guide 14 TDD Synchronization Configuration and Installation Guide 14.1 Introduction When planning a network of links, a key consideration is the interference that exists between the links. TDD synchronization is a feature which eliminates two specific interference mechanisms, namely interference between Master and Master and interference between Slave and Slave.
14 TDD Synchronization Configuration and Installation Guide 14.1.1 Installing the Recommended GPS Synchronization Kit The recommended GPS Sync installation kit includes the following: x GPS Sync Unit from MemoryLink (see Figure 143), with three attached terminated Ethernet and Sync cables and cable glands (2) which connect directly to a PTP 600 Series ODU. x Mounting bracket and mounting bracket bolts x Outdoor rated UV resistant cable tie x GPS Sync Unit User Manual.
14 TDD Synchronization Configuration and Installation Guide Figure 144 shows the inside of the GPS Sync Unit and Figure 145 is a diagram that shows how to connect the GPS Sync Unit to the ODU and the Lightning protection unit.
14 TDD Synchronization Configuration and Installation Guide Figure 145 - TDD Sync - PTP600 Deployment Diagram NOTE: Installation details of the GPS Sync Unit are described in the GPS Sync Unit User Manual. Figure 146 shows an example of mast installation using lightning protection and a GPS Sync Unit.
14 TDD Synchronization Configuration and Installation Guide Figure 146- GPS Synchronization Unit Complete Installation 260
14 TDD Synchronization Configuration and Installation Guide 14.2 TDD Synchronization Configuration TDD synchronization is enabled and configured using the install wizard during the installation process of the link. TDD synchronisation is not available in regions where radar avoidance is enabled. 14.2.1 TDD Synchronization Enable Figure 147 shows how to enable TDD Synchronization.
14 TDD Synchronization Configuration and Installation Guide 14.2.2 TDD Synchronization Configuration - Standard Mode When TDD Synchronization is enabled, there is an extra installation screen (“TDD Synchronization”) as shown in Figure 148. Figure 148 - Configuring TDD Synchronization – Screen 1 The TDD Synchronization screen provides the following controls: Expert Mode: Select “Yes” to use “Expert Mode”.
14 TDD Synchronization Configuration and Installation Guide Bandwidths in Network: It is very likely that there will be several different channel bandwidths in a given network. Table 44 gives a list of bandwidth combinations that permit synchronization without gross loss of efficiency. Depending on the channel bandwidth size, only subsets of Table 44 will be shown in the configuration wizard screen.
14 TDD Synchronization Configuration and Installation Guide Configure Link Range: Choose “yes” to enter the range of the link in control below: Note that Link Range MUST be less or equal to “Longest Link in Network”. In some networks, throughput can be increased by entering the exact range of each link in the wizard. TDD Holdover Mode: Two values: “Strict” and “Best Effort”. If a PTP 600 master ODU is configured for a TDD Holdover Mode set to “Strict”, then it will not transmit when synchronization is lost.
14 TDD Synchronization Configuration and Installation Guide 14.2.3 TDD Synchronization Configuration – Expert Mode When “Expert Mode” is selected, the user is required to configure the parameters shown in Figure 150. As mentioned previously, this is outside the scope of this document. However, this mode can be used as informative to ensure that the values of the parameters are the same for all the links in the network.
14 TDD Synchronization Configuration and Installation Guide 14.2.4 Confirm Settings and Reboot ODU When all the parameters have been entered, then the user can commit the values to the unit and reboot. Figure 151 shows the list of the installation parameters. Figure 151 - Confirm TDD Synchronization Configuration Parameters Following the reboot and provided the GPS has synchronized, an additional control is displayed in the Status Page as shown in Figure 152 (Sync) or Figure 153 (Not Sync).
14 TDD Synchronization Configuration and Installation Guide Figure 152 - Status Page - TDD Enabled and Synchronized Figure 153 - Status Page - TDD Enabled and Not Synchronized 267
14 TDD Synchronization Configuration and Installation Guide 14.2.5 Disarm ODU Following TDD Sync Configuration Figure 154 - Disarm Following TDD Synchronization CAUTION: In a synchronized network, links MUST be configured separately before bringing the whole network up.
15 E1/T1 Installation Guide 15 E1/T1 Installation Guide 15.1 Preparing the PTP 600 Series Bridge E1/T1 Cable NOTE: The maximum cable length between the ODU and the customers terminating equipment is 200m (656 feet) for E1/T1. The E1/T1 cable should be assembled as described in Section 3.3.5 “Cables and connectors”. This procedure applies to the ODU termination. The above procedure should be repeated for the customer equipment end of the cable when the cable is terminated with a RJ45.
15 E1/T1 Installation Guide 15.2 Making the Connection at the ODU Looking at the back of the unit with the cable entry at the bottom, the PTP 600 Series Bridge E1/T1 connection is the first hole on the left (Figure 156) and is labeled E1/T1. Figure 156 - PIDU Plus and E1-T1 Connexion The following procedure describes how connection is made at the ODU. It is often easier to carry out this procedure on the ground or a suitable surface prior to mounting the ODU.
15 E1/T1 Installation Guide Figure 157 - Disconnecting the ODU Step 1: Assemble the cable as described in above Step 3: Screw in the body of the weather proofing gland and tighten Step 2: Insert the RJ45 connector making sure that the locking tab snaps home Step 4: Screw on the clamping nut and tighten Should it be necessary to disconnect the E1/T1 cable at the ODU this can be achieved by removing the weatherproofing gland and depressing the RJ45 locking tab with a small screwdriver as shown in the opp
15 E1/T1 Installation Guide CAUTION: Do not over tighten the glands as the internal seal and structure may be damaged. See Figure 40 for an example of an over tightened cable gland. 15.3 Routing the Cable After connecting the cable to the ODU it can be routed and secured using standard cable routing and securing techniques. When the cable is in place it can then be cut to the desired length. 15.
15 E1/T1 Installation Guide Figure 159 - Diagrammatically Showing the E1-T1 Connections 273
15 E1/T1 Installation Guide Figure 160 - Two E1-T1-120 Ohms signal Balanced to PTP600 Interface 274
15 E1/T1 Installation Guide 15.6 Lightning Protection and E1/T1 15.6.1 Overview Section 10 “Lightning Protection” contains the requirements for the Motorola PTP 600 Series deployment. For E1/T1, an extra Earthing cable is supplied to connect the other PTP-LPU to the ODU ground. This section details the additional requirements for the deployment of E1/T1. 15.6.2 Recommended Additional Components for E1/T1 Installation. For a description of Zone A and Zone B refer to Section 10 “Lightning Protection”.
15 E1/T1 Installation Guide 15.7 Testing the E1/T1 Installation If you have opted to fit a Lightning Protection Unit, it should be tested as described in Section 10.3 “Installation”. Test the telecoms links by performing loopback connections as described in Section 8.3.1.6 “Telecoms Configuration Page”. 15.7.1 Pre-Power Testing Before connecting your E1/T1 source, check the following resistances: Check the cable resistance between pins 3 & 6 (Green/White & Green) and 7 & 8 (Brown/White & Brown).
16 Data Rate Calculations 16 Data Rate Calculations The data rate capacity of a PTP link is defined as the maximum end-to-end ethernet throughput that it can support. Use the tables and graph in this section to calculate the data rate capacity that can be provided by alternative PTP 600 configurations. It is assumed that ethernet frames are 1500 octet. Data rate capacity is determined by the following factors: 16.
16 Data Rate Calculations NOTE: There is a small difference between the rates for IP and TDM because there is fragmentation in TDM (for low priority traffic) which causes the throughput to be reduced buy approximately 1% compared to the IP mode. 16.1.2 Example Suppose that the link characteristics are: x Product variant = PTP 600 Lite x Link Symmetry = 1:1 x Link Mode Optimization = TDM x Modulation Mode = 64QAM 0.
16 Data Rate Calculations 16.2 Data Throughput Capacity Table 47, Table 48, Table 49, Table 50 and Table 51 show the data throughput rates (Mbits/s) that are achieved when two PTP 600 Full ODUs are linked and the link distance (range) is 0 km. Use the curves in Section 16.3 to adjust these figures to allow for link range. NOTE: When using these tables, be aware of the following points: x PTP 600 Lite data rates are half the PTP 600 Full rates given in this section. x Modulation Mode “256QAM 0.
16 Data Rate Calculations Table 47 – Data Throughput for PTP 600 Full, Link Symmetry = 1:1, Link Optimization = IP (Mbit/s) Modulation Mode 256QAM 0.81 dual 64QAM 0.92 dual 64QAM 0.75 dual 16QAM 0.87 dual 16QAM 0.63 dual 256QAM 0.81 single 64QAM 0.92 single 64QAM 0.75 single 16QAM 0.87 single 16QAM 0.63 single QPSK 0.87 single QPSK 0.63 single BPSK 0.63 single Modulation Mode 256QAM 0.81 dual 64QAM 0.92 dual 64QAM 0.75 dual 16QAM 0.87 dual 16QAM 0.63 dual 256QAM 0.81 single 64QAM 0.92 single 64QAM 0.
16 Data Rate Calculations Table 48 – Data Throughput for PTP 600 Full, Link Symmetry = 1:1, Link Optimization = TDM (Mbit/s) Modulation Mode 256QAM 0.81 dual 64QAM 0.92 dual 64QAM 0.75 dual 16QAM 0.87 dual 16QAM 0.63 dual 256QAM 0.81 single 64QAM 0.92 single 64QAM 0.75 single 16QAM 0.87 single 16QAM 0.63 single QPSK 0.87 single QPSK 0.63 single BPSK 0.63 single Modulation Mode 256QAM 0.81 dual 64QAM 0.92 dual 64QAM 0.75 dual 16QAM 0.87 dual 16QAM 0.63 dual 256QAM 0.81 single 64QAM 0.92 single 64QAM 0.
16 Data Rate Calculations Table 49 – Data Throughput for PTP 600 Full, Link Symmetry = 2:1, Link Optimization = IP (Mbit/s) (This combination is not available with Channel Bandwidth 5 MHz) Modulation Mode 256QAM 0.81 dual 64QAM 0.92 dual 64QAM 0.75 dual 16QAM 0.87 dual 16QAM 0.63 dual 256QAM 0.81 single 64QAM 0.92 single 64QAM 0.75 single 16QAM 0.87 single 16QAM 0.63 single QPSK 0.87 single QPSK 0.63 single BPSK 0.63 single Tx 198.58 167.31 136.73 106.37 76.47 99.29 83.66 68.36 53.18 38.23 26.59 19.11 9.
16 Data Rate Calculations Table 51 – Data Throughput for PTP 600 Full, Link Symmetry = Adaptive Link Optimization = IP (Mbit/s) (This combination is not available with Channel Bandwidth 5 MHz) Modulation Mode 256QAM 0.81 dual 64QAM 0.92 dual 64QAM 0.75 dual 16QAM 0.87 dual 16QAM 0.63 dual 256QAM 0.81 single 64QAM 0.92 single 64QAM 0.75 single 16QAM 0.87 single 16QAM 0.63 single QPSK 0.87 single QPSK 0.63 single BPSK 0.63 single Tx 236.95 199.63 163.14 126.91 91.24 118.47 99.82 81.57 63.46 45.62 31.73 22.
16 Data Rate Calculations 16.3 Range Adjustment Curves Use these curves to look up the link Range and find the Throughput Factor that must be applied to adjust the 0 km data throughput rates for the required combination of Channel Bandwidth, Link Symmetry, Link Optimization, DFS and Link Range (km).
16 Data Rate Calculations Figure 161 – PTP 600 Range Adjustment for Data Rates, Curve A Channel Bandwidth = 30 MHz, Link Symmetry = 1:1, Link Optimization = IP.
16 Data Rate Calculations Figure 162 – PTP 600 Range Adjustment for Data Rates, Curve B Channel Bandwidth = 30 MHz, Link Symmetry = 1:1, Link Optimization = TDM.
16 Data Rate Calculations Figure 163 – PTP 600 Range Adjustment for Data Rates, Curve C Channel Bandwidth = 30 MHz, Link Symmetry = 2:1, Link Optimization = IP. Channel Bandwidth = 20 or 15 MHz, Link Symmetry = 2:1, Link Optimization = TDM, DFS = FCC or ETSI.
16 Data Rate Calculations Figure 164 – PTP 600 Range Adjustment for Data Rates, Curve D Channel Bandwidth = 30 MHz, Link Symmetry = 2:1, Link Optimization = TDM.
16 Data Rate Calculations Figure 165 – PTP 600 Range Adjustment for Data Rates, Curve E Channel Bandwidth = 30 MHz, Link Symmetry = Adaptive, Link Optimization = IP.
16 Data Rate Calculations Figure 166 – PTP 600 Range Adjustment for Data Rates, Curve F Channel Bandwidth = 20 or 15 MHz, Link Symmetry = 1:1 or 2:1, Link Optimization = IP.
16 Data Rate Calculations Figure 167 – PTP 600 Range Adjustment for Data Rates, Curve G Channel Bandwidth = 20 or 15 MHz, Link Symmetry = 1:1, Link Optimization = TDM.
16 Data Rate Calculations Figure 168 – PTP 600 Range Adjustment for Data Rates, Curve H Channel Bandwidth = 20 or 15 MHz, Link Symmetry = 2:1, Link Optimization = TDM, DFS = None.
16 Data Rate Calculations Figure 169 – PTP 600 Range Adjustment for Data Rates, Curve I Channel Bandwidth = 20 or 15 MHz, Link Symmetry = Adaptive, Link Optimization = IP.
16 Data Rate Calculations Figure 170 – PTP 600 Range Adjustment for Data Rates, Curve J Channel Bandwidth = 10 MHz, Link Symmetry = 1:1, Link Optimization = IP.
16 Data Rate Calculations Figure 171 – PTP 600 Range Adjustment for Data Rates, Curve K Channel Bandwidth = 10 MHz, Link Symmetry = 1:1, Link Optimization = TDM.
16 Data Rate Calculations Figure 172 – PTP 600 Range Adjustment for Data Rates, Curve L Channel Bandwidth = 10 MHz, Link Symmetry = 2:1 or Adaptive.
16 Data Rate Calculations Figure 173 – PTP 600 Range Adjustment for Data Rates, Curve M Channel Bandwidth = 5 MHz, Link Symmetry = 1:1.
17 AES Encryption Upgrade 17 AES Encryption Upgrade The Motorola PTP 600 Series bridges support link encryption using the NIST approved Advanced Encryption Standard, HFIPS-197 H. This standard specifies AES (Rijndael) as a UT FIPS-approved symmetric encryption algorithm that may be used by U.S. Government organizations (and others) to protect sensitive information. Link Encryption is not available in the standard PTP 600 Series system.
17 AES Encryption Upgrade Figure 174 – AES Software License Key Data Entry Configuring link encryption will necessitate a 600 Series bridge service outage. Therefore it is recommended that the configuration process be scheduled during an appropriate period of low link utilization. Motorola recommends the following process for entering new license keys and minimizing service outage: 1. Open two browsers, one for each end of the link 2.
17 AES Encryption Upgrade 4. When both license keys have been successfully validated confirm the reboot for both ends of the link. The software is designed to allow five seconds so that a user can command both ends of the link to reset before the wireless link drops. 5. The link will automatically re-establish. 17.1.2 Encryption Mode and Key Entering the license keys only does not initialize AES link encryption. Link encryption can only be enabled via the Configuration or Installation Wizard pages.
17 AES Encryption Upgrade Motorola recommends the following process for entering AES link encryption configuration: 1. Open two browsers, one for each end of the link 2. Navigate to the ‘Configuration’ data entry page for each end of the link 3. At both ends of the link select the ‘AES (Rijndael)’ Encryption Algorithm required. 4. At both ends of the link enter ether an 128-bit or 256-bit encryption key. Note the key consists of 32/64 case insensitive hexadecimal characters.
17 AES Encryption Upgrade 17.2 Wireless Link Encryption FAQ 17.2.1 Encryption data entry fields are not available Check that the correct license key has been inserted into the unit. The current license key is displayed on the ‘License Key’ data entry page. 17.2.
18 Remote Software Upgrade by TFTP 18 Remote Software Upgrade by TFTP The ODU software can be upgraded remotely using Trivial FTP (TFTP) triggered by SNMP. To perform a remote software upgrade, follow this procedure: 1. Set the following tFTP attributes: tFTPServerIPAddress: The IP address of the TFTP server from which the TFTP software upgrade file Name will be retrieved. For example, to set the TFTP server IP address for unit 10.10.10.10 to 10.10.10.1: snmpset_d.exe -v 2c -c public 10.10.10.10 .iso.3.6.
18 Remote Software Upgrade by TFTP 2. Monitor the values of the following tFTP attributes: tFTPSoftwareUpgradeStatus: The current status of the TFTP software upgrade process. Values: o idle(0) o uploadinprogress(1) o uploadsuccessfulprogrammingFLASH(2) o upgradesuccessfulreboottorunthenewsoftwareimage(3) o upgradefailed(4). Example: snmpget_d.exe -v 2c -c public 10.10.10.10 .iso.3.6.1.4.1.17713.1.9.9.
19 Legal and Regulatory Notices 19 Legal and Regulatory Notices 19.1 Important Note on Modifications 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. 19.
19 Legal and Regulatory Notices 19.4 National and Regional Regulatory Notices – PTP 58600 variant 19.4.1 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.
19 Legal and Regulatory Notices FCC IDs and Industry Canada Certification Numbers are listed below: 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. 19.4.
19 Legal and Regulatory Notices European Union (EU) Waste of Electrical and Electronic Equipment (WEEE) directive The European Union's WEEE directive requires that products sold into EU countries must have the crossed out trash bin label on the product (or the package in some cases). As defined by the WEEE directive, this cross-out trash bin label means that customers and end-users in EU countries should not dispose of electronic and electrical equipment or accessories in household waste.
19 Legal and Regulatory Notices 19.5 National and Regional Regulatory Notices – PTP 54600 Variant 19.5.1 U.S. Federal Communication Commission (FCC) and Industry Canada (IC) Notification This device complies with part 15.407 of the US FCC Rules and Regulations and with RSS210 Issue 7 of Industry Canada.
19 Legal and Regulatory Notices 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. 19.5.
19 Legal and Regulatory Notices 19.6 National and Regional Regulatory Notices – PTP 25600 Variant 19.6.1 U.S. Federal Communication Commission (FCC) Notification This device complies with Part 27 of the US FCC Rules and Regulations. Use of this product is limited to operators holding Licenses for the specific operating channels. This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15E of the US FCC Rules.
19 Legal and Regulatory Notices 19.8 Legal Notices 19.8.1 Motorola Inc. End User License Agreement In connection with Motorola’s delivery of certain proprietary software or products containing embedded or pre-loaded proprietary software, or both, Motorola 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”).
19 Legal and Regulatory Notices 19.8.1.3 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. 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.
19 Legal and Regulatory Notices 19.8.1.4 Title; 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 Motorola and its licensors.
19 Legal and Regulatory Notices 19.8.1.6 Right to Use Motorola’s Name Except as required in 19.8.1.3 above, you will not, during the term of this Agreement or thereafter, use any trademark of Motorola, or any word or symbol likely to be confused with any Motorola trademark, either alone or in any combination with another word or words. 19.8.1.
19 Legal and Regulatory Notices 19.8.1.10 Disclaimer MOTOROLA DISCLAIMS ALL WARRANTIES OF ANY KIND, WHETHER EXPRESS, IMPLIED, STATUTORY, OR IN ANY COMMUNICATION WITH YOU. MOTOROLA 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.
19 Legal and Regulatory Notices 19.8.1.12 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.
19 Legal and Regulatory Notices 19.8.1.16 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. 19.8.1.17 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 Motorola may modify this Agreement as necessary to comply with applicable laws. 19.8.1.
19 Legal and Regulatory Notices UCD SNMP. Copyright 1989, 1991, 1992 by Carnegie Mellon University, Derivative Work – 1996, 1998-2000, Copyright 1996, 1998-2000 The regents of the University of California All Rights reserved.
19 Legal and Regulatory Notices Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. The name of the author may not be used to endorse or promote products derived from this software without specific prior written permission.
19 Legal and Regulatory Notices 19.8.
20 Specifications 20 Specifications 20.1 System Specifications 20.1.1 Wireless PTP 25600 Variant Radio Technology Specification Lower: 2.496-2.568 GHz RF Band Middle: 2.572-2.614 GHz Upper: 2.618-2.690 GHz Channel Selection Manual selection. Dynamic Frequency Control N/A Channel size 5, 10, 15 and 30 MHz Manual Power Control Maximum power can be controlled lower than the power limits shown above in order to control interference to other users of the band.
20 Specifications 20.1.2 Wireless PTP 45600 Variant Radio Technology Specification RF Band 4.400-4.600 GHz Channel Selection Manual selection. Dynamic Frequency Control By intelligent Dynamic Frequency Selection (i-DFS) or manual intervention; automatic selection on start-up and continual adaptation to avoid interference.
20 Specifications 20.1.3 Wireless PTP 48600 Variant Radio Technology Specification RF Band 4.710-5.000 GHz Channel Selection Manual selection. Dynamic Frequency Control By intelligent Dynamic Frequency Selection (i-DFS) or manual intervention; automatic selection on start-up and continual adaptation to avoid interference.
20 Specifications 20.1.4 Wireless PTP 49600 Variant Radio Technology Specification RF Band 4.900-4.990 GHz Channel Selection Manual selection. Dynamic Frequency Control By intelligent Dynamic Frequency Selection (i-DFS) or manual intervention; automatic selection on start-up and continual adaptation to avoid interference.
20 Specifications 20.1.5 Wireless PTP 54600 Variant Radio Technology Specification RF Band 5.470-5.725 GHz By dynamic frequency control and manual intervention Channel Selection Automatic detection on start-up and continual adaptation to avoid interference. Dynamic Frequency Control Initial capture 10-15 sec. Out of service on interference 100 ms.
20 Specifications 20.1.6 Wireless PTP 58600 Variant Radio Technology Specification RF Band 5.725-5.850 GHz By dynamic frequency control and manual intervention Channel Selection Automatic detection on start-up and continual adaptation to avoid interference. Dynamic Frequency Control Initial capture 10-15 sec. Out of service on interference 100 ms.
20 Specifications 20.1.7 Wireless PTP 59600 Variant Radio Technology Specification RF Band 5.825-5.925GHz By dynamic frequency control and manual intervention Channel Selection Automatic detection on start-up and continual adaptation to avoid interference. Dynamic Frequency Control Initial capture 10-15 sec. Out of service on interference 100 ms.
20 Specifications 20.1.8 Management Management Specification Power status Status Indication Ethernet Link Status Data activity Web server and browser for setup Installation Audio tone feedback during installation , plus graphical installation tool suitable for laptop and PDA computing devices Web server for con rmation Radio Performance and Management Via web server and browser, SNMP Alarms Via con gurable email alerts, SNMP 20.1.
20 Specifications 20.1.10 Physical Integrated Specification Dimensions Width 14.5” (370mm), Height 14.5” (370mm), Depth 3.75” (95mm) Weight 12.1 lbs (5.5 Kg) including bracket Connectorized Specification Dimensions Width 12” (305mm), Height 12” (305mm), Depth 4.01” (105mm) Weight 9.1 lbs (4.3 Kg) including bracket 20.1.11 Powering Power Supply Separate power supply unit (included) Dimensions Width 9.75” (250mm), Height 1.5” (40mm), Depth 3” (80mm) Weight 1.9 lbs (0.
20 Specifications 20.2 20.3 Safety Compliance Region Specification USA UL 60950 Canada CSA C22.2 No.60950 International CB certified & certificate to IEC 60950 EMC Emissions Compliance 20.3.1 PTP 25600 Variant Region Specification USA FCC Part 15 (Class B) 20.3.2 PTP 45600 Variant Region Specification USA - Military 20.3.3 PTP 48600 Variant Region Specification USA - Military 20.3.
20 Specifications 20.3.5 PTP 54600 Variant Region Specification USA FCC Part 15 Class B Canada CSA Std C108.8, 1993 Class B Europe EN55022 CISPR 22 20.3.6 PTP 58600 Variant Region Specification USA FCC Part 15 Class B Canada CSA Std C108.
20 Specifications 20.4 EMC Immunity Compliance Top-level Specification ETSI 301-489. Specification Comment EN 55082-1 Generic EMC and EMI requirements for Europe EN 61000-4-2: 1995 Electro Static Discharge (ESD), Class 2, 8 kV air, 4 kV contact discharge Testing will be carried to ensure immunity to 15kV air and 8kV contact EN 61000-4-3: 1995 ENV50140: 1993 (radiated immunity) 3 V/m EN 61000-4-4: 1995 (Bursts/Transients), Class 4, 4 kV level (power lines AC & DC) Signal lines @ 0.
20 Specifications 20.5 Radio Certifications 20.5.1 PTP 25600 Variant Region Specification (Type Approvals) USA FCC Part 27 20.5.2 PTP 45600 Variant Region Specification (Type Approvals) USA FCC Part 27, NTIA Red Book, TBC 20.5.3 PTP 48600 Variant Region Specification (Type Approvals) USA FCC Part 27, NTIA Red Book, TBC 20.5.4 PTP 49600 Variant Region Specification (Type Approvals) USA FCC Part 90 Canada RSS-111 20.5.
20 Specifications 20.5.6 PTP 58600 Variant Region Specification (Type Approvals) USA FCC Part 15.247 CANADA RSS 210 Issue 7, Annex 8 UK IR 2007 Eire ComReg 02/71R1 EU EN302 502 v 1.2.
20 Specifications 20.6 Environmental Specifications Category Specification ODU: -40°F (-40°C) to 140°F (+60°C) Temperature PIDU Plus (indoor deployment): 32°F (0°C) to 104oF (+40°C) PIDU Plus (outdoor deployment within weatherproofed cabinet): -40°F (-40°C) to 140°F (+60°C) 20.7 Wind Loading 150mph Max (242kph). See Section 12 “Wind Loading” for a full description.
20 Specifications Table 53 - Telecoms Connection Pin Out Telecoms Connector Pinout Signal Name Pin 1 E1T1A_TX- Pin 2 E1T1A_TX+ Pin 3 E1T1A_RX- Pin 4 E1T1B_TX- Pin 5 E1T1B_TX+ Pin 6 E1T1A_RX+ Pin 7 E1T1B_RX- Pin 8 E1T1B_RX+ 337
21 FAQs 21 FAQs Can I source and use my own PoE adaptor with the 600 Series bridge? No. The 600 Series bridge uses a non-standard PoE configuration. Failure to use the Motorola supplied Power Indoor Unit could result in equipment damage and will invalidate the safety certification and may cause a safety hazard. Why has Motorola launched the 600 Series bridge? The 600 Series bridge is the first product to feature Multiple-Input Multiple-Output (MIMO).
21 FAQs Why does the 600 Series bridge operate in the 5GHz band? The 5 GHz band offers the dual benefits of high data throughput and good radio propagation characteristics. The wide band of spectrum available is subdivided into several channels such that multiple systems can operate in the vicinity without causing interference to one another. Is the 600 Series bridge an 802.11a device? No, although similar, the 600 Series bridge uses different encoding and radio transmission systems from 802.11a.
22 Glossary 22 Glossary ARP Address Resolution Protocol NLOS non-Line-of-Sight ARQ Automatic Repeat reQuest ODU Outdoor Unit BPSK Binary Phase Shift Keying OFDM Orthogonal Frequency Division DC Direct Current Multiplex PC IBM Compatible Personal Computer European Telecommunications PIDU + Power Indoor Unit Plus Standards Institute PING Packet Internet Groper FAQ Frequently Asked Question POE Power over Ethernet GPS Global Positioning System PSU Power Supply Unit HP Hypertext
23 Index 23 Index Alarm 121, 122, 123 Alignment Mounting 114, 251 Antenna Architecture Cable Loss Networking Password 195 46 Path Loss 83 Planning 108, 249, 252 channels 58, 183 Channels 172, 177, 179 Clock 197 radio 2, 6 Reboot 331, 333 Configuration45, 131, 137, 151, 153, 156, 163, 176, 200, 204, 236 49, 82 Properties Radio 191 Compliance 81 234, 237, 241, 249, 251 237, 241 Cables 44, 101, 111 231, 334 198, 200, 207 Recovery 199 Regulatory 240 Repair 35 Connecting
23 Index Unit A1, Linhay Business Park Eastern Road, Ashburton Devon, TQ 13 7UP, UK Telephone Support: +1 877 515-0400 (Worldwide) +44 808 234 4640 (UK) www.motorola.com/ptp 342 MOTOROLA, the stylized M Logo and all other trademarks indicated as such herein are trademarks of Motorola, Inc. ® Reg. US Pat & Tm. Office. All other product or service names are the property of their respective owners. © 2007 Motorola, Inc. All rights reserved.