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5 Radio Site Planning Radio Site Planning Radio Site Planning Radio Site Planning Proper site selection and planning before installing your ASWipLL devices will ensure a successful deployment of your ASWipLL system. Site planning includes the following considerations:
! Minimum obstructions (e.g. buildings) in the radio path between Base Station radio (i.e. BSR) and subscriber radios (i.e. SPR/IDR).
! Minimum incursions on Fresnel Zone (recommended minimum of 60%
clearance of first Fresnel Zone).
! Mount radios as high as possible to avoid obstructions in the wireless path.
! Check possibility of future obstructions such as plans to erect buildings and trees that may grow tall enough to obstruct the wireless path.
! Align antennas for maximizing received signal strength (RSS)
! Consider nearby sources of interference that could degrade performance of radio. Mount radios as far from sources of interference as possible
! Ensure Base Station radio and subscriber premises radio are within maximum coverage range of reception
! Maximum CAT-5 cable length connecting the outdoor radio to the indoor terminating equipment (i.e. switch/hub) is 100 meters
! Ensure that you have sufficient wiring conduit and cable ties to channel and protect the CAT 5 cable connecting the outdoor radio to the indoor hub/switch.
! Ensure required power mains outlet is available at the site. 02030311-07 Airspan Networks Inc. 5-1 Radio Site Planning Hardware Installation Guide 5.1. Minimal Radio Path Obstructions ASWipLL radios communicate by propagation of waves. Thus, ensure minimum obstructions (from, e.g. buildings and trees) in the radio path between Base Station radio (i.e. BSR) and subscriber radios (i.e. SPR/IDR). It is essential that the ASWipLL radios or antennas be installed in such a way that their radio paths have a clear path with each other. 5.2. Fresnel Zone Clearance There must be sufficient open space around the radio path to minimize interference with the radio beam. A minimum of 60% of the first Fresnel Zone of the path should be clear of obstructions. Despite a clear line-of-site, objects close enough to the transmission path may cause attenuation in signal strength and an increase in signal interference. Objects with reflective surfaces that seem relatively far away, but yet still encroaching on Fresnel Zone, may cause these interferences. Figure 5-1: At least 60% of first Fresznel Zone should be clear Fresnel Zones define the amount of clearance required from obstacles. These zones are composed of concentric ellipsoid areas surrounding the straight-line path 5-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Radio Site Planning between two antennas. Thus, the zone affects objects to the side of the path and those directly in the path. The first Fresnel Zone is the surface containing every point for which the distance from the transmitter to any reflection point on the surface point and then onto the receiver is one-half wavelength longer than the direct signal path. For calculating Fresnel Zone, refer to the ASWipLL System Description. 5.3. Multipath Fading Some of the transmitted signals may be reflected from a nearby building, by water under the signal path, or from any other reflectors. This reflected ("bounced") signal can then be received by the radio receiving the signal and superimposed on the main received signal, thereby degrading the signal strength. To avoid multipath fading from nearby buildings etc., Airspan recommends installing the outdoor radios at the rear end of the buildings instead of at the front. When you install at the rear end of the building, the front-end of the building blocks incoming signals from multipath reflections. Figure 5-2: Radios mounted at rear, blocking multipath reflection 02030311-07 Airspan Networks Inc. 5-3 Radio Site Planning Hardware Installation Guide 5.4. Spectrum Analysis for Locating Clear Frequencies Before setting up your wireless link between Base Station and subscribers, Airspan recommends (especially in unlicensed bands), analyzing the RF spectrum at the Base Station to select only clear frequency channels (i.e. without interferences) for building a frequency table for wireless communication between Base Station and subscriber. Prior to performing this test, you need to mount the radio/antenna in the desired installation spot. In general, you will be looking for frequencies with signal strengths of 85 dBm or greater. For using Airspans spectrum analyzer tool, refer to the WipConfig Users Guide. For evaluating link quality using the Spectrum Analyzer, see Appendix E, "Evaluating Link Quality". 5.5. Adjacent Base Station Radios For installations involving co-location of BSRs, it is important to assign frequencies of maximum spacing. This is to reduce possible radio interference between adjacently installed BSRs. In addition, a 1-meter separation must exist between adjacent BSRs. 5.6. Radio Antenna Alignment Once the subscriber unit (i.e. SPR/IDR) is installed and aimed in the general direction of the BSR, it is recommended to measure the received signal strength
(RSS) to determine the signal strength received from the BSR, and to precisely align the SPR/IDR for maximum signal strength. You need to orientate (up/down, left/right) the SPR/IDR until the maximum RSSI levels are achieved, and then secure the SPR/IDR. For short links you can expect an RSSI of 60 dBm or better. For longer links, an RSSI of 75 dBm is acceptable. Any RSSI of less than 80 dBm may be too weak for the radios to reliably communicate. 5-4 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Radio Site Planning Airspan offers various tools for measuring RSS (check with your Airspan representative regarding cost and supply):
! SPR:
! RSS LED adapter (see Part II, Chapter 17, "Antenna Alignment using RSS LED Adapter")
! WipConfig program (see Appendix E, "Evaluating Link Quality")
! IDR: built-in RSSI LEDs (see Part III, Chapter 24, " Antenna Alignment Using RSS LEDs") 5.7. Considerations when Using External Antennas Notes:
1) To avoid unnecessary RF cable loss, use short-length cables and with low attenuation. 2) Antennas should have a VSWR of less than 1:1.5. 3) Ensure BSR and SPR/IDR use the same antenna polarity. 4) When using an omni-directional antenna, choose a type providing a wide vertical beam width (of at least 8) to allow connection of closer CPEs. 5) Antenna must be DC grounded. 5.7.1. Cable Loss Airspans ASWipLL radios provide transmit power compensation for power attenuation caused by cable loss (in cable connecting to external antenna). Cable loss is the loss of radio transmit (Tx) power as heat, and directly proportional to cable length and quality, and operating frequency. 02030311-07 Airspan Networks Inc. 5-5 Radio Site Planning Hardware Installation Guide To adhere to EIRP limitations in the regulatory domain in which you are operating your ASWipLL system, when purchasing antenna cables take into consideration cable loss per cable length. EIRP is calculated using cable loss (i.e. EIRP = max. power output + antenna gain - cable loss). For example, FCC regulations state that when operating in unlicensed bands, the external antennas must provide an EIRP of less than or equal to 36 dBm to prevent interference with other radios. Thus, knowing this EIRP parameter, you can choose the cable that ensures adherence to this parameter value. The table below lists examples of cable loss per cable length. Table 5-1: Examples of cable loss per cable length Note: Airspan does not supply external antenna cables. It is the responsibility of the installer to provide the cable and ensure the cable characteristics (e.g. length and cable loss) enables adherence to EIRP regulations of the country or area in which the ASWipLL system is operating. 5-6 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Radio Site Planning 5.7.2. Omni-Directional Antennas In some scenarios, where capacity demand is relatively low, external omni-
directional antenna use at the Base Station may seem attractive. However, it is recommended to avoid using omni-directional antennas (if possible), due to the following disadvantages that these antennas pose compared to directional antennas:
! Higher sensitivity to external interferences.
! Higher sensitivity to multipath, resulting in the following:
! The root mean square (RMS) delay spread at the Base Station is substantially higher.
! Multipath interference at the CPE side (when using omni-directional antenna at the Base Station) is substantially higher. In fact, when using an omni-
directional antenna, the existence of clear Fresnel zone between BSR and SPR/IDR is insufficient to eliminate multipath interference, since multipath, in this case, can be caused by reflections originating from obstacles outside the Fresnel zone.
! Higher sensitivity to alignment. Since the omni-directional antenna gain is achieved by narrowing the vertical beam width, a relatively low deviation in the antenna alignment will result in severe signal attenuation. 02030311-07 Airspan Networks Inc. 5-7 Radio Site Planning Hardware Installation Guide 5.7.3. Operating in Band-C for FCC Markets Some operators (e.g. in the USA) have licenses for Band-C (710 716 MHz and 740
746 MHz). ASWipLL 700 provides an external antenna, allowing coverage in the entire 700 MHz band (698 to 746 MHz), including the licensed A and B bands used in USA. A maximum of four BSRs operating in Band-C are allowed at a Base Station (in accordance with FCC regulations). This regulation ensures minimum RF interference with other radio devices that may be operating in nearby frequencies. In the 1 Megasymbols per second (Msps) mode, the center frequencies are 711.5, 712.5, 713.5, 714.5, 741.5, 742.5, 743.5, and 744.5. Thus, the frequency allocation for four BSRs is 711.5, 741.5, 714.5, and 744.5. In the 1.33 Msps mode, the center frequencies are 712, 713, 714, 742, 743, and 744. Thus, the frequency allocation for four BSRs is 712, 742, 714, and 744. Figure 5-3: Frequency allocation in a four-sector Base Station Radio interference may occur between the BSRs operating in the upper frequency range (i.e. 742 MHz and 744 MHz) and the lower frequency range (i.e. 712 MHz and 714 MHz). To overcome this interference, a 1-meter vertical separation is recommended between the BSRs operating in the upper frequency and the BSRs operating in the lower frequency. 5-8 Airspan Networks Inc. 02030311-07 Part I Part I Part I Part I Base Station Installation Base Station Installation Base Station Installation Base Station Installation Part I describes the procedures for installing the ASWipLL devices located at the Base Station, and includes the following chapters:
! Chapter 6, Basic Design of Devices
! Chapter 7, Mounting the Devices
! Chapter 8, Network Cabling
! Chapter 9, Serial Cabling
! Chapter 10, Connecting Third-Party External Antennas
! Chapter 11, Power Cabling This page is intentionally left balnk. 6 Basic Design of Devices Basic Design of Devices Basic Design of Devices Basic Design of Devices This chapter describes the basic design of the ASWipLL devices that can be installed at the Base Station:
! BSR
! BSDU
! SDA-1/48V
! GPS
! BSPS 6.1. BSR The BSR is an encased outdoor radio providing access to the BSRs communication ports on its front panel. The BSRs bottom panel provides holes for mounting the BSR to, for example, a pole or wall. 6.1.1. Physical Dimensions The BSRs physical dimensions are described in the table below. Table 6-1: BSR physical dimensions Parameter Height Width Depth Weight Value 400 mm (15.74 inches) 317 mm (12.48 inches) 65.5 mm (2.58 inches) 4.7 kg Comment The BSRs physical dimensions exclude the mounting kit 02030311-07 Airspan Networks Inc. 6-1 Basic Design of Devices Hardware Installation Guide 6.1.2. Ports The BSR provides various ports on its front panel, as displayed below:
9-pin D-type port 15-pin D-type port Figure 6-1: BSR front panel (built-in antenna model) The table below describes the BSR ports. Table 6-2: BSR ports Interface Ethernet (10BaseT): with the BSDU (or SDA) Synchronization: of BSRs controlled by BSDU Power: supplied by BSDU (or SDA) Serial (RS-232) local initial configuration (using WipConfig tool) during installation For attaching third-party external antennas. BSR models for the 700 and 900 MHz bands provide two N-type ports. BSR models with built-in antennas do not provide N-type ports. Port 15-pin D-type 9-pin D-type N-type 6-2 Airspan Networks Inc. 02030311-07 7 Mounting the Devices This chapter describes the mounting procedures for the following devices:
BSR
BSDU
SDA-1/48V
BSPS 7.1. Pole-Mounting the BSR The BSR is typically mounted on a pole, however, it can be wall mounted as well. Pole mounting allows the BSR to be easily adjusted in the horizontal (azimuth) and vertical (elevation) planes for antenna alignment. Note: In the standard BSR kit, Airspan does not supply wall-mounting brackets. To order wall-mounting brackets, contact your Airspan representative. BSR wall mounting is identical to SPR wall mounting. Therefore, for a detailed description of wall mounting, see SPR wall mounting in Part II, Chapter 13, "Mounting the Devices". The BSR is mounted using the mounting holes located on the BSRs bottom panel
(see Figure 7-1) and the supplied pole-mounting brackets. The pole-mounting bracket is designed to support the BSR on a round pole of 45 mm in diameter. 02030311-07 Airspan Networks Inc. 7-1 Mounting the Devices Hardw are Installation Guide Mounting holes Figure 7-1: BSR bottom panel providing holes for mounting To prevent radio interference, each BSR requires a minimum of 1-metre separation between adjacent BSRs (see Figure 7-2). 1 Metre min. Figure 7-2: Minimum separation between mounted BSRs 7-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices A summary of the BSR pole-mounting procedure is displayed below. Locking Holes BSR mounting Bracket Pivot Hole Clamping Bracket Figure 7-3: Attaching BSR pole-mounting brackets U Bolt To pole mount the BSR:
1. Attach the mounting bracket to the BSR:
a. Align the mounting bracket with the BSR's mounting holes so that the mounting bracket's side with the built-in nut is aligned with the BSR's mounting holes furthest from the BSR's front panel, as shown in the figure below. 02030311-07 Airspan Networks Inc. 7-3 Mounting the Devices Hardw are Installation Guide b. Slide an M10 flat washer and M10 spring lock washer onto an M10 hex head screw (ensure spring lock washer is closest to the bolt's head). From the external side, insert the M10 hex head screw through the mounting bracket and BSR's mounting holes. Fasten the M10 hex head screw (one is provided with a built-in nut while the other requires you to insert an M10-hex nut into the BSR's mounting hole). Mounting bracket Mounting bracket with built-in nut BSR's mounting hole with built-in nut holder Figure 7-4: Mounting bracket connected to BSR 2. Attach the clamping bracket to the mounting bracket:
a. Slide an M6 spring lock washer onto an M6 hex head screw. Align the mounting bracket's and clamping bracket's pivot holes, such that the clamping bracket is aligned to the the inside of the mounting bracket. From the external side of the mounting bracket, insert the M6 hex head screw into the pivot holes and then fasten, but not tightly. (The clamping bracket provides a built-in nut.) 7-4 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices b. Choose an elevation hole on the mounting bracket and then align it with the corresponding hole on the clamping bracket. Slide an M6 spring lock washer onto an M6 hex head screw, and then from the external side of the mounting bracket, insert the M6 hex head screw through the elevation hole on the mounting bracket and into the clamping bracket's corresponding hole. Fasten but not tightly the M6 hex head screw (the clamping bracket provides built-
in nut). The elevation hole can later be changed according to desired antenna orientation in the elevation plane. Pivot hole Selected elevation hole Clamping bracket Figure 7-5: Clamping bracket attached to mounting bracket 3. Attach the U-bolt to the pole:
a. Place one U-bolt around the pole, and then insert the U-bolt screw side through the two corresponding holes (horizontally parrallel) on the clamping bracket. Slide an M8 flat washer and M8 spring lock washer onto each U-
bolt screw side (ensure that the flat washer is adjacent to the clamping bracket). Fasten each U-bolt side with the two M8 hex nuts. b. Attach the second U-bolt as described above. 02030311-07 Airspan Networks Inc. 7-5 Mounting the Devices Hardw are Installation Guide Pole Fastened by screws and washers U-bolt U-bolt Figure 7-6: Attaching BSR to pole using U-bolts 4. Perform final BSR orientation:
a. Adjust the vertical position of the BSR by choosing a final elevation hole as described in Step 2. Lock the BSR at the desired position by inserting the locking bolt in the desired position and fastening it tightly. Fasten tightly the bolt in the pivot hole. See Figure 7-8 for a description of the angles (in degrees) of each elevation hole. b. Adjust the horizontal position of the BSR by rotating the BSR about the pole, and then tightening the nuts of the U-bolts. BSR positioning is obtained in two planes by adjustment of the mounting bracket assembly a shown in Figure 7-7. 7-6 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices Figure 7-7: BSR orientation in vertical (top figure) and horizontal plane (lower figure) Note: A thread-locking compound is to be used to prevent the bolts working loose. A loop should be left in the cable for maintenance purposes and to prevent the cable weight being taken directly on the connector. The figure below displays the possible angles of elevation. As is shown, the BSR pole mounting bracket allows elevation between -18.5 to 26.3. Figure 7-8: Orientating BSR in the elevation plane (side view of BSR) 02030311-07 Airspan Networks Inc. 7-7 Mounting the Devices Hardw are Installation Guide Note: It is important to provide strain relief and drip loop for Cat-5 cables. Create a drip loop and strain relief using cable tie, to tie cable to pole, as displayed in the figure below. Drip loop and strain relief Cable tie Figure 7-9: Pole-mounted BSR with cable drip loop and strain relief 7-8 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices 7.2. Rack Mounting the BSDU The BSDU is designed for mounting in a standard 19-inch (48.3 cm) equipment rack or telco rack with 1 rack unit (1-U) of vertical rack space. The sides of the BSDU chassis provide integrated front-rail mounting brackets. Therefore, all that is required for mounting the BSDU is to attach the BSDU front-rail mounting brackets to the rack. The mounting brackets are secured to the rack's mounting rails using the supplied four M5 mounting screws and plastic cup washers. To rack-mount the BSDU:
1. Determine which rack rail holesleft and right sidewill be used for attaching the chassis. 2. Insert four nuts into the rack's rail holes you designated in Step 1. These nuts are housed in Tinnerman clips, which allow you to fasten them into the rail holes. To insert the Tinnerman clips, hold the clips, squeeze them, and then insert them into the rail hole. 3. Carefully insert the BSDU into the rack, aligning the BSDUs mounting bracket holes with the rack rail holes. 4. Insert the M5-mounting screws, with plastic washers, into the BSDU mounting bracket holes, on each side, as shown in Figure 7-10. In this way, the chassis is supported until you tighten the chassis screws. 5. Tighten the M5 mounting screws to fasten the chassis to the cabinet. 02030311-07 Airspan Networks Inc. 7-9 Mounting the Devices Hardw are Installation Guide Figure 7-10: BSDU rack mounting Note: When mounting multiple BSDUs in a cabinet, vertical spacingabove and belowis required for feeding cables to the rear. 1U-chassis Space for cable management Figure 7-11: BSDU and vertical space for cables 7.3. Mounting the SDA-1/48V The SDA-1/48V is simply placed on a desktop. In other words, no mounting is involved. 7-10 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices 7.4. Mounting the BSPS (Optional) The BSPS is supplied pre-mounted in a standard 19 x 11U rack, providing available space for additional equipment (i.e. BSDUs, which require 1U each). Thus, no mounting procedures are needed. 02030311-07 Airspan Networks Inc. 7-11 Mounting the Devices Hardw are Installation Guide This page is intentionally left blank. 7-12 Airspan Networks Inc. 02030311-07 8 Network Cabling Network Cabling Network Cabling Network Cabling Network cabling at the Base Station depends on the ASWipLL devices implemented at the Base Station to provide the BSR with connectivity to the providers backhaul and power source. These devices can be one of the following:
! SDA: Base Station providing AC power supply and consisting of a single BSR
! BSDU: Base Station consisting of multiple BSRs
! SDA-1/48V: Base Station providing DC power supply and consisting of a single BSR 02030311-07 Airspan Networks Inc. 8-1 Network Cabling Hardware Installation Guide 8.1. BSR Connected to an SDA An SDA is typically implemented at Base Stations that consist of only a single BSR. The SDA provides Ethernet interface between the BSR and the providers backhaul network. Notes:
1) The SDA is typically implemented at the subscribers site with the SPR. For a detailed description of installing the SDA, see Part 2, "CPE Installation SPR". 2) The SDA also supplies 48 VDC power to the BSR. 8.1.1. Connecting BSR to SDA The BSR outdoor radio is connected to the indoor SDA device by a standard CAT 5 cable. The following lists the BSR-to-SDA cable setup:
! Cable: straight-through CAT-5 (100 meters) 4 Pair outdoor type 24 AWG
! Connectors:
! BSR side: 15-pin D-type male (only 8 pins are used)
! SDA side: 15-pin D-type male (only 8 pins are used) Notes:
1) The maximum cable length between the BSR and SDA is 100 meters. 2) Airspan supplies unterminated CAT 5 cables for 15-pin D-type connectors. For a detailed description on crimping cables, see Appendix C, Cable Crimping". 8-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Network Cabling
! Connector pinouts:
Table 8-1: BSR-to-SDA cable connector pinouts Straight-through CAT-5 UTP PVC 4 Pair 24 AWG cables 15-pin D-type male BSR Pin Function Wire color Wire SDA pair Pin Function 15-pin D-type male 1 2 3 4 5 6
+48 VDC 48 RTN Tx+
Tx-
Rx+
Rx-
Blue / White Blue Orange /
White Orange Green /
White Green 1 2 3 1 2 3 4 5 6
+48 VDC 48 RTN Rx+
Rx-
Tx+
Tx-
Notes:
1) Only pins 1 to 6 are used. 2) The wire color-coding is ASWipLLs standard for wire color-coding (for a detailed description of ASWipLLs wire color-coding standard, see Appendix C,
"Cable Crimping"). However, if you implement your companys wire color-
coding scheme, ensure that the wires are paired and twisted according to the pin functions listed in Table 8-1 (e.g. Rx+ with Rx-). 02030311-07 Airspan Networks Inc. 8-3 Network Cabling Hardw are Installation Guide To connect the BSR to the SDA:
1. Connect the 15-pin D-type male connector, at one end of the CAT 5 cable, to the BSRs 15-pin D-type port, labeled DATA POWER SYNC. 2. Connect the 15-pin D-type male connector, at the other end of the CAT 5 cable, to the SDA. Figure 8-1: Connecting BSR to SDA 8-4 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Network Cabling 8.1.2. Connecting SDA to Providers Ethernet Network The SDA is typically implemented at the subscribers premises with the SPR. For a detailed description of connecting the SDA to the Ethernet network, see Part 2, Chapter 14, "Network Cabling". 8.2. BSR Connected to a BSDU Multiple BSRs at a Base Station interface with the the providers backhaul network through the BSDU. Each BSDU can support up to six BSRs, and each Base Station can support up to four BSDUs. Thus, at full configuration, 24 BSRs (i.e. 4 BSDUs multiplied by 6 BSRs) can be implemented at a Base Station. 8.2.1. Connecting BSR to BSDU The BSRs 15-pin D-type port is connected to one of the six BSDUs rear panel 15-
pin D-type ports (labeled BSR #). The BSR-to-BSDU cable setup is as follows:
! Cable: straight-through 10Base-T Ethernet 4 Pair Cat 5 outdoor type 24 AWG
(100 meters)
! Connectors:
! BSR side: 15-pin D-type male (only 8 pins are used)
! BSDU side: 15-pin D-type male (only 8 pins are used) Note: Airspan supplies unterminated CAT 5 cables for 15-Pin D-type connectors. For a detailed description on crimping cables, see Appendix C,
Cable Crimping". 02030311-07 Airspan Networks Inc. 8-5 15-pin D-type male Network Cabling Hardware Installation Guide
! Connector pinouts:
Table 8-2: BSR-to-BSDU cable connector pinouts Straight-through CAT-5 UTP PVC 4 Pair 24 AWG cables 15-pin D-type male BSR Pin Function Wire color Wire BSDU pair Pin Function 1 2 3 4 5 6 7 8
+48 VDC 48 RTN Tx+
Tx-
Rx+
Rx-
Sync.+
Sync.-
1 2 3 4 Blue / White Blue Orange /
White Orange Green /
White Green Brown /
White Brown 1 2 3 4 5 6 7 8
+48 VDC 48 RTN Rx+
Rx-
Tx+
Tx-
Sync.+
Sync.-
Notes:
1) Only pins 1 to 8 of the 15-pin D-type connector are used. 2) The wire color-coding described in the table is ASWipLLs standard for wire color-coding (for a detailed description of ASWipLLs wire color-coding standard, see Appendix C, "Cable Crimping"). However, if you implement your companys wire color-coding scheme, ensure that the wires are paired and twisted according to the pin functions listed in the table above to prevent electrical interference between the transmitter pins (e.g. Rx+ with Rx-). To connect the BSR to the BSDU (Figure 8-2):
1. Connect the 15-pin D-type male connector, at one end of the CAT 5 cable, to the BSRs 15-pin D-type port labeled DATA POWER SYNC. 2. Connect the 15-pin D-type male connector, at the other end of the CAT-5 cable, to one of the six BSDUs 15-pin D-type ports labeled BSR, located at the rear of the BSDU. 8-6 Airspan Networks Inc. 02030311-07 9 Serial Cabling Serial Cabling Serial Cabling Serial Cabling This chapter describes serial cabling for the following devices:
! BSR
! BSDU
! BSPS 02030311-07 Airspan Networks Inc. 9-1 Serial Cabling Hardware Installation Guide 9.1. Serial Cabling BSR to a PC The BSR provides an RS-232 port for serial interface with a PC. This serial interface allows you to perform local BSR configuration using WipConfig. Notes:
1) For serial configuration, the BSR must remain connected to the BSDU/SDA
(i.e. the BSRs 15-pin D-type port remains connected to the BSDUs/SDAs 15-
pin D-type port). 2) For a detailed explanation on performing BSR initial configuration, refer to WipConfig Users Guide or WipConfig PDA Users Guide. The following lists the BSR-to-PC serial cabling:
! Cable: crossover serial cable
! Connectors:
! BSR side: 9-pin D-type male
! PC side: 9-pin D-type female
! Connector pinouts:
Table 9-1: BSR-to-PC serial connector pinouts Crossover serial cable BSR Pin 9-pin D-type male Function Pin Function 9-pin D-type female PC 2 3 5 RS232 Rx RS232 Tx GND 3 2 5 Tx Rx GND Note: Pins not mentioned are not connected. 9-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Serial Cabling To connect the BSR to a PC for serial configuration (see Figure 9-1):
1. Connect the 9-pin D-type male connector, at one end of the serial cable, to the BSRs serial port, labeled Serial. 2. Connect the 9-pin D-type female connector, at the other end of the serial cable, to the PCs serial port. Figure 9-1: BSR-to-PC serial cabling (e.g. of BSR connected to SDA) 02030311-07 Airspan Networks Inc. 9-3 10 Connecting Third----Party Connecting Third Party Connecting Third Connecting Third Party Party External Antennas External Antennas External Antennas External Antennas This chapter describes the procedures for connecting third-party external radio and Global Positioning System (GPS) antennas to the BSR and BSDU respectively. The implementation of these antennas depends on the BSR model (with respect to radio antennas) and the need for synchronization of the ASWipLL system (with respect to GPS antennas). 10.1. Connecting Radio Antennas to BSR The BSR model without a built-in radio antenna provides an N-type port(s) for connecting a third-party external antenna(s). The BSR models for the 900 MHz and 700 MHz bands provide two N-type connectors for connecting two third-party external antennas. Two antennas provide dual-antenna diversity, whereby data is transmitted using only the main antenna, while data is received by the antenna (main or secondary) with the best radio frequency (RF) reception. Warning: It is the responsibility of the person installing the ASWipLL system to ensure that when using the outdoor antenna kits in the United States (or where FCC rules apply), that only those antennas certified with the product are used. The use of any antenna other than those certified with the product is expressly forbidden in accordance with FCC rules CFR47 part 15.204. The installer should configure the output power level of antennas according to country regulations and per antenna type. 02030311-07 Airspan Networks Inc. 10-1 Connecting Third-Party External Antennas Hardware Installation Guide Warning: For ASWipLL 700 (i.e. 700 MHz band), where four BSRs are installed at a Base Station, a 1-meter separation must be provided between the antennas of the BSRs operating in the lower frequencies (i.e. 711.5 and 714.5 for 1 Msps mode; and 712 and 714 for 1.33 Msps mode) and the antennas of the BSRs operating in the upper frequencies (i.e. 741.5 and 744.5 for 1 Msps mode; and 742 and 744 for 1.33 Msps mode). Warning: In accordance with FCC regulations, ensure that when operating in unlicensed bands, the external antennas provide a maximum EIRP of 36 dBm to prevent interference with other radios operating in the unlicensed band. The EIRP is defined as:
Max. Power Output + Antenna Gain + Cable Loss 36 dBm (EIRP) The following lists the BSR-to-third party external antenna cable setup:
! Cable (third party): RF coaxial
! Connector (third party): N-type male. The usage of N-type ports for models (i.e. in 700 MHz and 900 MHz bands) with two N-type ports:
! If you are using only one antenna, connect the antenna to the N-type port labeled Primary.
! If you are using two antennas, connect the second antenna to the N-type port labeled Secondary. Warnings:
1) Before connecting the external antenna, ensure that the BSR is NOT connected to the power source. 2) Before powering on the BSR, ensure that some type of equipment such as an antenna or an RF attenuator is connected to the N-type port. This eliminates the risk of damaging the BSR device. 10-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Connecting Third-Party External Antennas To connect the BSR to a third-party external antenna:
Connect the third-party N-type male connector, at the end of the RF cable, to the N-type port located on the BSRs front panel, as displayed in Figure 10-1. Figure 10-1: Attaching third-party external antenna Notes:
1) For crimping RF coaxial cables to N-type connectors, see Appendix C, Cable Crimping. 2) Ensure that the third-party antenna cable is of sufficient quality to reduce or eliminate loss when operating in the required frequency band. 3) For a description of third-party antennas offered by Airspan for BSRs operating in the 700 MHz and 900 MHz bands, see Appendix G, "Third-Party Antenna Specifications". 02030311-07 Airspan Networks Inc. 10-3 Part II Part II Part II Part II CPE Installation:
CPE Installation:
CPE Installation:
CPE Installation:
Subscriber Premises Radio Subscriber Premises Radio Subscriber Premises Radio Subscriber Premises Radio
(SPR)
(SPR)
(SPR)
(SPR) Part II describes the procedures for installing the ASWipLL equipment located at the subscribers premises when implementing an SPR. Part II includes the following chapters:
! Chapter 12, "Basic Design of Devices"
! Chapter 13, "Mounting the Devices"
! Chapter 14, "Network Cabling"
! Chapter 15, "Serial Cabling"
! Chapter 16, "Connecting Third-Party External Antennas"
! Chapter 17, "Antenna Alignment using RSS LED Adapter"
! Chapter 18, "Power Cabling"
This page is intentionally left blank. 12 Basic Design of Devices Basic Design of Devices Basic Design of Devices Basic Design of Devices This chapter describes the basic design of the ASWipLL devices installed at a subscriber site when an SPR is implemented:
! SPR
! SDA
! RSS LED Adapter 02030311-07 Airspan Networks Inc. 12-1 Basic Design of Devices Hardware Installation Guide 12.1. SPR This section describes the SPRs basic design. 12.1.1. Physical Dimensions The SPRs physical dimensions are described in the following table. Table 12-1: SPR physical dimensions SPR model Standard Gain Antenna High Gain Antenna 311 mm (12.24 inches) 224 mm (8.82 inches) 65.5 mm (2.58 inches) 2.5 kg 400 mm (15.74 inches) 317 mm (12.48 inches) 65.5 mm (2.58 inches) 4.7 kg Comment The SPRs physical dimensions exclude the mounting kit. SPR models with an N-type receptacle for attaching a third-party external antenna are also available. Parameter Height Width Depth Weight 12-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Basic Design of Devices 12.1.2. Ports The SPR is an encased outdoor radio providing access to the SPRs sole communication port (15-pin D-type) at the front panel (see figure below). The SPRs bottom panel provides holes for mounting the SPR to, for example, a pole or wall. 15-pin D-type port Figure 12-1: SPR (with built-in antennal) Notes:
1) SPRs without built-in antennas provide an N-type port for connecting a third-party external antenna. 2) Previous SPR models also provide a 9-pin D-type port for serial interface. 02030311-07 Airspan Networks Inc. 12-3 13 Mounting the Devices Mounting the Devices Mounting the Devices Mounting the Devices This chapter describes the procedures for mounting the following devices:
! SPR
! SDA 13.1. Wall Mounting the SPR The SPR is typically mounted on a wall. However, the SPR can also be pole-
mounted. SPR pole mounting is identical to BSR pole mounting, thus, for a detailed description on pole mounting, see Chapter 7, "Mounting Devices". Note: The standard SPR kit includes wall-mounting brackets. For ordering pole-mounting brackets (supply and costs), please contact your Airspan representative. 02030311-07 Airspan Networks Inc. 13-1 Mounting the Devices Hardware Installation Guide The SPR is mounted using the mounting holes located on the SPRs bottom panel
(see Figure 13-1), and the wall-mounting brackets (provided). Mounting holes Figure 13-1: SPR bottom panel providing holes for mounting A minimum of 3-meter separation is required between mounted SPRs and existing customer radio equipment when not transmitting on the same sector (see Figure 13-2). 3.0 metres Figure 13-2: SPR separation when not transmitting on the same sector 13-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices A 1-meter separation is required between SPRs when on the same sector and transmitting to the same BSR without requiring shielding (see Figure 13-3). 1.0 metre Figure 13-3: SPR separation when transmitting on the same sector to the same BSR SPR wall mounting is performed in two stages:
! Attaching the mounting bracket to the SPRs mounting holes.
! Attaching the mounting bracket (attached to the SPR) to the wall. To wall mount the SPR:
1. Position the mounting bracket on the mounting surface (e.g. wall), and then use a pencil to mark the position of the four mounting holes. 2. Drill holes for each hole that you marked in the step above. 3. Insert wall anchors (not supplied) into each of the drilled holes. 4. Align the mounting brackets four holes with the wall anchors, and then insert a screw (not supplied) through the mounting bracket holes into each wall anchor, and tighten. Note: Airspan does not provide screws for attaching the mounting bracket to the wall. The screw size depends on the structure of the building to which the bracket is to be attached. When selecting screw sizes, consideration must be given to the weight of the SPR and load that may be induced in windy conditions. 02030311-07 Airspan Networks Inc. 13-3 Mounting the Devices Hardware Installation Guide The figure below displays relevant dimensions of the mounting bracket. Note the two different sized fixing holes. Figure 13-4: Attaching mounting bracket to wall 13-4 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices Below is a diagram illustrating the fixing dimensions of the mounting bracket. Ensure that the distance between the hole centers are 120 mm and 60 mm. Figure 13-5: SPR mounting bracket dimensions for the four fixing holes 02030311-07 Airspan Networks Inc. 13-5 Mounting the Devices Hardware Installation Guide 5. Attach the SPR to the mounting bracket by performing the following:
a. Slide an M10 spring lock washer and then an M10 plain washer onto each M10 hex head screw (ensure lock washer is nearest to head of screw bolt). b. Align the mounting brackets holes with the BSRs mounting holes as displayed below. (The mounting bracket side that provides a groove for inserting a nut must be aligned with the BSRs mounting hole that is nearest to the BSRs rear panel.) c. From the external sides, insert the M10 hex head screws through the mounting brackets holes and BSRs mounting holes. Loosely fasten with the M10 hex nuts. Figure 13-6: Attaching SPR to mounting bracket 13-6 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Mounting the Devices 6. Adjust the horizontal positioning of the SPR, and then tighten the two M10 hex head screws with the M10 hex nuts. Rotation is restricted in the horizontal plane only. The permissible rotation is shown in Figure 13-7. Figure 13-7: Horizontal rotation of the SPR (top view) Note: A third-party thread-locking compound must be applied to the M10 hex head screws to prevent the bolts working loose. 02030311-07 Airspan Networks Inc. 13-7 15 Serial Cabling Serial Cabling Serial Cabling Serial Cabling The SPRs 15-pin D-type port provides serial interface with a PC for configuring the SPR through an RS-232 communication mode. The 15-pin D-type port uses three pins for serial interface with the PC, and six pins for interfacing with the SDA (with which the SPR is connected). A Y-cable (splitter) is used to connect the SPRs 15-
pin D-type port to both the PC and the SDA. Note: For performing SPR initial configuration, refer to the ASWipLL WipConfig Users Guide. The SPR-to-PC and SDA cable connections for SPR serial configuration are as follows:
! Connectors:
! SPR side: 15-pin D-type male (only 6 pins used)
! PC side: 9-pin D-type (RS-232)
! SDA side: 15-pin D-type male
! Cable: straight-through Y-cable 02030311-07 Airspan Networks Inc. 15-1 Serial Cabling Hardware Installation Guide Figure 15-1: Y-cable for serial connection
! Connector pinouts:
Table 15-1: Y-cable connector pinouts Straight-through Y-cable SPR SDA Pin Function Pin Function 15-pin D-type male 15-pin D-type male 1 2 3 4 5 6 Pin 12 14 15
+48 VDC 48 RTN Ethernet Tx+
Ethernet Tx-
Ethernet Rx+
Ethernet Rx-
SPR Function GND RS232 Rx RS232 Tx 1 2 3 4 5 6
+48 VDC 48 RTN Rx+
Rx-
Tx+
Tx-
PC Pin Function 9-pin D-type female 5 3 2 GND Rx Tx 15-2 Airspan Networks Inc. 02030311-07 Hardware Installation Guide Serial Cabling The Y-cable connector pin assignments are displayed schematically in Figure 15-2. Figure 15-2: Y-cable connector pin assignment To connect the SPR to a PC for serial configuration (see Figure 15-3):
1. Connect the 15-pin D-type male connector, at the one end of the Y-cable, to the SPR. 2. Connect the 15-pin D-type male connector, at the other end of the Y-cable, to the SDA. 3. Connect the 9-pin D-type female (RS232) connector, at the other end of the Y-
cable, to the PCs serial port. 02030311-07 Airspan Networks Inc. 15-3 Serial Cabling Hardw are Installation Guide Figure 15-3: SPR serial cable connections using a Y-cable Notes: For SPR serial configuration, the SPR remains connected to the SDA. 15-4 Airspan Networks Inc. 02030311-07 16 Connecting Third----Party Connecting Third Party Connecting Third Connecting Third Party Party External Antennas External Antennas External Antennas External Antennas The SPR model without a built-in antenna provides an N-type port for connecting a third-party external antenna. The addition of an external antenna allows greater RF sector coverage than the standard SPR built-in antenna models. The following lists the SPR-to-third party external antenna cable setup:
! Cable: RF coaxial
! Connector: N-type male Warning: Before connecting the external antenna, ensure that the SPR is NOT connected to the power source. Warning: Before powering on the SPR, ensure that some type of equipment such as an antenna or an RF attenuator is connected to the N-type receptacle. This eliminates the risk of burning the SPR device. Warning: It is the responsibility of the person installing the ASWipLL system to ensure that when using the outdoor antenna kits in the United States (or where FCC rules apply), that only those antennas certified with the product are used. The use of any antenna other than those certified with the product is expressly forbidden in accordance with FCC rules CFR47 part 15.204. The installer should configure the output power level of antennas according to country regulations and per antenna type. Warning: In accordance with FCC regulations, ensure that for external antennas, the maximum EIRP is 36 dBm. The EIRP is defined as:
Max. Power Output + Antenna Gain + Cable Loss 36 dBm (EIRP) 02030311-07 Airspan Networks Inc. 16-1 Connecting Third-Party External Antennas Hardw are Installation Guide To connect the SPR to a third-party external antenna:
Connect an N-type male connector of the third-party antenna to the N-type port located on the SPRs front panel, as displayed in Figure 16-1. Figure 16-1: SPR model with N-type connector for attaching an external antenna Notes:
1) For crimping RF coaxial cables to N-type connectors, see Appendix C, Cable Crimping". 2) For a description of third-party antennas offered by Airspan for SPRs operating in the 700 MHz band, see Appendix G, "Third-Party Antenna Specifications. 16-2 Airspan Networks Inc. 02030311-07
This product uses the FCC Data API but is not endorsed or certified by the FCC