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InCell ™ Fiber Optic Distributed Antenna System Installation and Users Guide Copyright Andrew Corporation Version 1.1 October 2000 Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Proprietary Information This document is the property of Andrew Corporation. The information contained herein is proprietary to Andrew, and no part of this document may be reproduced or transmitted in any form or by any means, electronic or mechanical, for any purpose, without the express written permission of Andrew. Disclaimer Andrew reserves the right to make changes, without notice, to the specifications and materials contained herein. While we have worked diligently to insure every element presented is correct, we shall not be responsible for errors. For the latest product information and technical specifications, please see the contact information below. Copyright Andrew Corporation, October 2000, Printed in USA, All rights reserved. FCC Notice This equipment complies with Part 24 of the FCC rules. Any changes or modifications not expressly approved by the manufacturer could void the user’s authority to operate the equipment. Warning In order to comply with FCC rules for rf exposure, the following must be observed: 1. The antenna for this device must have a gain of no more than 21 dBi. 2. The antenna must be installed such that a minimum separation distance of 20 cm. is maintained between the antenna and any persons. Trademarks InCell™ is a trademark of Andrew Corporation. All other trademarks belong to their respective owner. Contact Information For more information about Andrew’s capabilities to extend RF signals coverage into structures, including office buildings, shopping complexes, warehouses, tunnels, and mines, please contact us using the information below: Andrew Corporation 2601 Telecom Parkway Richardson, Texas 75082 Attention: Mr. Matt Melester E-mail:matt.melester@andrew.com Fax: (972) 952-0018 Voice: (972) 952-9745 - ii - Table of Contents Andrew Corporation................................................................................................................. 1 Andrew In-Building Wireless Experience................................................................................ 1 InCell™ Fiber Optic Distributed Antenna System Description.............................................. 1 Central Distribution Unit (CDU) ...........................................................................................1 CDU FRONT PANEL .........................1 Remote Antenna Unit (RAU) ................................................................................................2 CDU to RAU Interface Cables ..............................................................................................4 Composite Fiber Optic & Power Cables ................................................................................4 Standard Duplex Fiber Optic Cables......................................................................................4 Indoor Antennas....................................................................................................................5 In-Building Implementations Using the Andrew InCell™ System ......................................... 7 Scalable System Architecture ................................................................................................7 The Signal Distribution Unit............................................................................................8 The Interconnecting Cable...................................................................................................11 The Installation Parameters ...........................................................................................13 Sample Implementation.......................................................................................................16 InCell™ Specifications............................................................................................................ 17 Technical Performance........................................................................................................17 Interface Specifications .......................................................................................................18 Electrical Specifications ......................................................................................................19 Environmental and Mechanical Specifications.....................................................................20 MTBF ...........................................................................................................................20 MTTR ...........................................................................................................................20 Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide InCell™ Network Monitoring System ................................................................................... 21 Pilot Tone Generation .........................................................................................................21 RAU Indicators ...................................................................................................................21 CDU Front Panel Indicators ................................................................................................21 Alarm Functions..................................................................................................................22 Remote Monitoring Functions .............................................................................................22 InCell™ Operation, Maintenance and Support .................................................................... 24 Operation ............................................................................................................................24 Regular Maintenance...........................................................................................................24 Fault Repair ........................................................................................................................24 Support ...............................................................................................................................24 Spare Policy ........................................................................................................................24 - ii - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide List of Tables Table 1. Table 2. Table 3. Table 4. Table 5. InCell™ Performance Specification............................................................................17 BTS Interface Specifications ......................................................................................18 Antenna Interface Specifications ................................................................................19 Electrical Specifications .............................................................................................19 InCell™ Environmental and Mechanical Specification ...............................................20 List of Figures Figure 1. InCell™ ......................................................................................................................1 Figure 2. InCell™ Form Factors ................................................................................................1 Figure 3. Andrew Dual Band Patch Antenna ..............................................................................5 Figure 4. Andrew Dual Band Omni Antenna...............................................................................5 Figure 5. Simplified InCell™ Block Diagram ............................................................................7 Figure 6. InCell™ Central Distribution Unit ..............................................................................1 Figure 8. Remote Antenna Unit..................................................................................................8 Figure 9. System expandability to 48 RAUs ...............................................................................9 Figure 10. System Expandability to more than 48 RAUs ..........................................................10 Figure 11. Cross Section of Andrew Composite Fiber/Copper Cable........................................11 Figure 12. Remote and Local Power Connections on the RAU.................................................12 Figure 13. Typical System Configuration Using Off-Air Interface............................................16 Figure 15. Remote Alarm Capability ........................................................................................23 Figure 16. Daisy Chaining CDU’s for Remote Monitoring.......................................................23 - iii - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Andrew Corporation Andrew Corporation is a global designer, manufacturer, and supplier of communications equipment, services, and systems. Andrew products and expertise are found in communications systems throughout the world, including wireless and distributed communications, land mobile radio, cellular and personal communications, broadcast, radar, and navigation. The Andrew "Flash" trademark seen on the cover can also be seen in every corner of the world on broadcast towers and microwave antennas, HELIAX® and RADIAX® cables, communications and computer networking equipment. The mark of Andrew for more than 60 years, it is the benchmark of quality wherever it appears. It is a symbol of commitment to customer satisfaction from the 4,500-plus employees of Andrew Corporation. We are listed on the NASDAQ stock exchange under symbol “ANDW.” To learn more about us, please visit our web site at www.andrew.com. Andrew In-Building Wireless Experience The Andrew Corporation Distributed Communications Systems (DCS) group has over 15 years experience designing, installing, and managing large complex RF distribution systems for metropolitan railways, building owners, and public mobile radio and telephone operators throughout the world. For clients who do not need turnkey solutions, we offer product sales or product sales with engineering support services. Andrew offers a range of products to meet requirements of the in-building market. In the early 1980’s Andrew developed leaky cables as an adjunct to our coaxial cable business. This product quickly led us to pursuing and executing wireless RF coverage in confined spaces such as metros, road tunnels, and buildings. Through these projects, our Distributed Communications Systems division acquired critical experience in project management and RF engineering of these systems. -1- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide InCell™ Fiber Optic Distributed Antenna System Description The subsystem consists of one or more Central Distribution Units (CDU) feeding multiple Remote Antenna Units (RAU). Figure 1. InCell™ This unit can drive up to 6 RAU’s. Additional CDU’s can be driven using one or more of our Signal Distribution Units (SDU). The required signal distribution is built into the backplane of the chassis minimizing the need for interconnecting cables. Our design is intrinsically optimized for new technologies operating at higher bandwidths. Unlike other competing products, this product is designed for multi-operator, multi-service capabilities with higher output levels and lower system sensitivities. This equates to greater coverage range per antenna unit and hence lower implementation costs. When complete, this product will be available in both single-band units, i.e., US Cellular, GSM 900, US PCS-1900, and DCS-1800, and dual band units in which both low and high band services are supported within the same unit using the same fiber pair. Figure 2. InCell™ Form Factors -1- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide e V ie w C D U S id RAU Front View RAU Front View RAU Front View RAU Front View RAU Front View RAU Front View -2- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Central Distribution Unit (CDU) The Central Distribution Unit (CDU) is the core module that can drive up to six Remote Antenna Units (RAU. The CDU separates the down and uplink RF signals and converts these to optics for transmission over a 2-core single-mode fiber cable to one of six RAU’s. The CDU (shown at Figure 3) is housed in a standard 1U, 19-inch rack mount unit and provides 6 sets of duplex optical fiber links to the remote antenna units. Figure 3. InCell™ Central Distribution Unit The figure below provides a detailed view of the CDU front panel, showing the six remote antenna interface ports. Each of the six ports is identical and provides DC power for the remote antenna as well as a downlink interface and an uplink interface with the remote antenna unit. CDU FRONT PANEL -1- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide The rear view of the CDU shows the RF input/output connector as well as the power connection and the on/off switch. The RF connections are Type N. CDU REAR PANEL e View CDU Sid Remote Antenna Unit (RAU) The RAU converts the signal back to RF and provides a single duplex downlink and uplink output port; and the dual band unit combines the two services to a single RF connector. The third order intercept point is high (33dBm typical), and the output can go directly to a multiband antenna or be split to drive multiple antennas. -2- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide RAU Front View RAU Rear View CDU Status Indicators RAU Status Indicators Alarm Output Remote Monitoring Option -3- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide CDU to RAU Interface Cables Composite Fiber Optic & Power Cables Standard Duplex Fiber Optic Cables -4- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Indoor Antennas Andrew is developing several new low profile in-building antennas like the examples in Figure 4 and Figure 5. These dual band antennas are based on a product originally designed by our automotive accessory division. We anticipate releasing other antenna products in the next calendar year. Figure 4. Andrew Dual Band Patch Antenna Figure 5. Andrew Dual Band Omni Antenna -5- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Outdoor Donor Antennas Lightning Arrestors Bi-Directional Amplifiers Coaxial Cables and Jumpers Distributed Antenna System Planning InCell Distributed Antenna System Bill of Material -6- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide In-Building Implementations Using the Andrew InCell™ System Scalable System Architecture The InCell™ distributed antenna system is a scalable system that can be configured to support up to 384 antenna locations using three building block modules. 6-Channel Central Distribution Unit Composite Fiber/Copper Cable Fiber Optic Transmitter Single Mode Fiber -- Downlink Fiber Optic Receiver Remote Antenna Unit #1 Fiber Optic Receiver Fiber Optic Transmitter Single Mode Fiber -- Uplink RF, Test Signal & Power Distribution 18 AWG Copper Wire Power Remote Antenna Unit #6 Fiber Optic Transmitter Fiber Optic Receiver Single Mode Fiber -- Downlink Fiber Optic Transmitter Fiber Optic Receiver Single Mode Fiber -- Uplink Power Local Power Supply (Wall Transformer) Figure 6. Simplified InCell™ Block Diagram -7- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide The RAU is (shown at Figure 7) weighs only 0.6 pounds and is 38 mm (length) x 127 mm (width) x 165 mm (height). This compact size makes it suitable for close mounting to the antenna. Figure 7. Remote Antenna Unit The Signal Distribution Unit The third building block module is the Signal Distribution Unit (SDU). This is a 1U rack mount unit housing a standard 8-way power divider that is placed in front of the CDU to drive eight CDU’s from one service input. Using an architecture of one SDU and eight CDU’s, 48 antenna locations can be served (see Figure 8). Using an architecture of nine SDU’s dividing the service signal to 64 CDU’s, 384 antenna locations can be served (see Figure 9). These approaches are best housed coherently in 19-inch equipment racks as depicted in Figures 25 and 26. -8- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide RF REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM RF RF RF RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF RF RF RF RF IN D00-45 Figure 8. System expandability to 48 RAUs -9- Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC REMOTE ALARM RF RF RF RF RF RF RF RF RF RF RF RF RF RF RF RF RF RF RF IN REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM RF RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC REMOTE ALARM RF RF RF RF RF RF RF RF D00-46 Figure 9. System Expandability to more than 48 RAUs - 10 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide The Interconnecting Cable Any single mode 2-core fiber cable can be used to drive the RAU a distance of 20Km from the CDU. In this configuration, power to the RAU is supplied from an external 12-28VDC source or an Andrew supplied universal (110/240VAC, 50/60Hz) wall transformer (wall wart). An Andrew manufactured composite cable is also available. This cable (shown at Figure 10) combines 2-core fiber and 2-conductor copper elements in a single jacket. Using this cable, power to the RAU is supplied by the CDU over the copper conductors eliminating the need for a separate RAU power supply. Although the composite cable greatly simplifies the installation process, the CDU-RAU separation is limited to 1.5Km. The limitation is the DC voltage drop from the CDU to the RAU over the copper conductors. 0.210" TM Microcable Natural Rip Cord Insulated Copper (Red) Insulated Copper (Black) TM Microcable (Blue) Outer Jacket D00-37 Figure 10. Cross Section of Andrew Composite Fiber/Copper Cable The Andrew composite cable is rugged, flexible and has an outside diameter of 0.21”, making it easy to install. One optical fiber provides the downlink signal between the CDU and the RAU; the second optical fiber provides the uplink signal between the RAU and the CDU. These cables use industry standard SC type connectors to interface with the RAU and CDU. The two copper lines are used to provide DC power and ground signals to the RAU so that no additional power planning is required. System installers are not required to install AC power, conduit and transformers at each remote antenna location. With the CDU in the center of a system, remote antennas could be spaced as far as 3 km apart using the composite cable. Andrew provides plenum rated and riser rated composite cables for in-building installation as fully tested cable assemblies and as bulk cable. The cables meet demanding building codes for safety. Tested cable assemblies are available in lengths of 50, 100, 150 and 200 meters, with optical and power connectors installed. Bulk composite cable is also available on spools and - 11 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide requires system installers to add crimp-on connectors for the copper lines and add SC type connectors to the fiber cables. Refer to Andrew Catalog 38, pages 642-645, for full specifications of the plenum and riser rated cables. Andrew cable assemblies also come with a pulling hook and harness to make the cables easier to install. If the in-building location for each of the remote antenna units is pre-planned and the distances are all known, then composite cables with connectorized ends and installation-ready wraps can be ordered to specific lengths. The other option is to buy reels of composite cable and then connectorize them in field. The connectors for the copper wires are fairly easy to crimp on, but the SC-connectors take a few minutes and require the use of a non-fusion based splicing device and well trained technicians to insure that reliable, low loss splices are made. Single mode fiber optic cable is used in the InCell™ products because of its wide bandwidth and loss attenuation characteristics. Single mode fiber optic cable has the lowest attenuation of all fiber optic cable types and is typically lower in cost than multimode fiber cable. Single mode fiber is used in communications systems where high data rates and wide bandwidths are required. Wideband fiber optic line provides for unlimited future growth. Typical single mode cable loss is 0.4 dB per km. The loss of two SC connectors is typically 0.5 dB. The SC type connector is the most popular connector type for the fiber-optic cables. The SC connector is the recommended connector in the EIA/TIA-568A building wiring standard. It provides a very reliable, low loss connection at a reasonable cost. The SC type connector is easy to install and provides positive feedback when correctly seated. SC connectors have good lock, pull and wiggle characteristics, ensuring that they will stay in place when installed and that they are immune to tension or lateral pressure on the fiber cable. Figure 11 shows the RAU fiber and power connections. U/L D/L PWR Rem POWER Loc D00-44 Figure 11. Remote and Local Power Connections on the RAU - 12 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide The Installation Parameters Installation times will depend on the size of each installation; however, Andrew can provide rough guidelines for installing the CDU and RAU that may be used to determine the total system installation time once the number of equipment parts is determined. The CDU may be mounted in a standard 19” equipment rack or on a wall. Allow 30 minutes for unpacking the CDU, installing the unit into the rack or wall and connecting the RF, fiber and power cables. Upon application of system power, front panel indicators will give the installer a visual indication of power and link status. Mounting hardware is provided for rack or wall mounting. RAUs are typically mounted on walls or ceilings throughout the building. The units are small and lightweight and installers may carry multiple RAUs at one time to speed installation. Mounting the RAU to a wall or ceiling and connecting the fiber and power cables and the antenna takes only minutes. Upon application of system power, indicators on the RAU give the installer a visual indication of RAU power and link status. Mounting hardware is provided for the RAU. To minimize system wiring times, Andrew composite cable is recommended to allow the fiber optic links and the power to be routed to each RAU in one small, easy to pull cable. The composite cables eliminate the need for conduit to each remote antenna location, improving wiring installation time. Disruption to business is minimal as the CDU is typically installed in a electronic equipment room and the remote antennas and wiring may be installed after work hours. The cables are small and lightweight making them easy to pull through risers, above roofs and through tubes. Site survey testing before and after installation may be done during business hours using small, portable RF measurement tools. - 13 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide CDU REAR PANEL CDU FRONT PANEL CDU Side View e View CDU Sid - 14 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide RAU Front View RAU Front View RAU Rear View - 15 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Sample Implementation Figure 12 illustrates a small off-air implementation using an Andrew GridPACK donor antenna, an Andrew Cellular Extender (ACE), and a single InCell™ Central Distribution Unit driving up to six Remote Antenna Units. The donor antenna and extender can be replaced with other RF inputs, such as another off-air interface, a base station, or distribution unit depending on the application. Andrew CK GRIDPA ntenna Donor A in Hig Andrew ester rg S e Arr Andrew Cable Heliax Andrew Off-Air r Family Repeate Central Andrew ite Compos ble iber Ca tic Km) (up to 1.5 Andrew InCell Unit Antenna Remote Indoor tenna Patch An Figure 12. Typical System Configuration Using Off-Air Interface - 16 - Andrew InCell n Unit Distributio Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide InCell™ Specifications Technical Performance The technical specifications are summarized in Table 1. Table 1. InCell™ Performance Specification Wireless Service Standard InCell Part Number Downlink Passband (MHz) Uplink Passband (MHz) US Cellular (AMPS/TDMA/CDMA) GSM-900 DCS-1800 PCS-1900 2.4 GHz ISM WLAN US Cellular/PCS-1900 GSM-900/GSM-1800 2000-1000-000 2000-2000-000 2000-3000-000 2000-4000-000 2000-5000-000 2000-6000-000 2000-7000-000 869-894 935-960 1805-1880 1930-1990 2400-2500 869-894/1930-1990 935-960/1805-1880 824-849 890-915 1710-1785 1850-1910 2400-2500 824-849/1850-1910 890-915/1710-1785 InCell™ Uplink Performance Uplink Frequency Range 2000-1000-000 (US Cellular) 2000-2000-000 (GSM-900) 2000-3000-000 (DCS-1800) 2000-4000-000 (PCS) 2000-5000-000 (WLAN) 2000-6000-000 (Dual Band) 2000-7000-000 (Dual Band) End-to-End RF Gain (dB) Gain Flatness Over Frequency Maximum Input Power Noise Figure* 824-849 MHz 890-915 MHz 1710-1785 MHz 1850-1910 MHz 2400-2500 MHz 824-849/1850-1910 MHz 890-915/1710-1785 MHz 15 dB +/- 2.5 dB Limiter threshold at -40 dBm 11 dB InCell™ Downlink Performance Downlink Freqnency Range 2000-1000-000 (US Cellular) 2000-2000-000 (GSM 900) 2000-3000-000 (DCS-1800) 2000-4000-00 (PCS) 2000-5000-000 (WLAN) 2000-6000-000 (Dual Band) 2000-7000-000 (Dual Band) End-to-End RF Gain (dB) Gain Flatness Over Frequency Maximum Input Power Return Loss Spurious/Intermodulation 1 dB Compression Point Output Intercept Point Wideband Noise CDMA Spectral Regrowth Analog Output 15 dBm, 2 carriers Power 12 dBm, 4 carriers 9 dBm, 8 carriers 869-894 MHz 935-960 MHz 1805-1880 MHz 1930-1990 MHz 2400-2500 MHz 869-894/1930-1990 MHz 935-960/1805-1880 MHz 15 dB +/-2.5 dB 20 dBm >17 dB -13 dBm for non-European Systems -36 dBm from 9 kHz to 1 GHz -30 dBm from 1 GHz to 12.75 GHz 20 dBm 20 dBm -121.5 dBm/Hz -45 dBc TDMA CDMA 15 dBm, 2 carriers 10 dBm, 1 carrier 12 dBm, 4 carriers 4 dBm, 2 carriers 9 dBm, 8 carriers - 17 - GSM-900 10 dBm, 2 carriers 7 dBm, 4 carriers 4 dBm, 8 carriers DCS-1800 12 dBm, 2 carriers 9 dBm, 4 carriers 6 dBm, 8 carriers Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Interface Specifications The BTS interface specifications are shown in Table 2 and the antenna interface specifications are in Table 3. Table 2. BTS Interface Specifications Requirement Performance Specification Operational Bandwidth Uplink 890-915 MHz 1710-1785 MHz 890-915 MHz 1710-1785 MHz GSM-900 DCS-1800 Dual Band 900/1800 Downlink 935-960 MHz 1805-1880 MHz 935-960 MHz 1805-1880 MHz Connector Types- CDU RF Optical Fiber AC Power (CDU only) DC Power Connector Locations Type N Type SC Single Mode Fiber Standard 3-pin “D” type Molex 2-pin RF and AC connectors on rear of CDU Fiber and DC power on front of CDU Interface Type RF Optical Fiber RF Impedance/VSWR 1 dB Compression Point Downlink Third Order Output Intercept Point Downlink Uplink Spurious Response Duplex (bi-directional port) Single mode fiber: 1 uplink, 1 downlink 50 ohms, typical 10 dB return loss 20 dBm N/A -36 dBm from 9 kHz to 1 GHz -30 dBm from 1 GHz to 12.75 GHz Gain/Gain Linearity Downlink Uplink Group Delay 15 db ± 2.5 15 db ± 2.5 <1.0 usec (CDU, fiber and RAU) - 18 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Table 3. Antenna Interface Specifications Requirement Performance Specification Operational Bandwidth GSM-900 DCS-1800 Dual Band 900/1800 Uplink 890-915 MHz 1710-1785 MHz 890-915 MHz 1710-1785 MHz Downlink 935-960 MHz 1805-1880 MHz 935-960 MHz 1805-1880 MHz Connector Types- RAU RF Optical Fiber AC Power (CDU only) DC Power SMA Type SC Single Mode Fiber N/A Molex 2-pin RF connector on rear of RAU Fiber and DC power on front of RAU Connector Locations Interface Type RF Optical Fiber RF Impedance/VSWR Duplex (bi-directional port) Single mode fiber: 1 uplink, 1 downlink 50 ohms, typical 10 dB return loss 1 dB Compression Point Downlink Uplink Third Order Output Intercept Point Downlink Uplink Spurious Response 20 dBm N/A 36 dBm -6 dBm -36 dBm from 9 kHz to 1 GHz -30 dBm from 1 GHz to 12.75 GHz Gain/Gain Linearity Downlink Uplink Group Delay 15 db ± 2.5 15 db ± 2.5 <1.0 usec (CDU, fiber and RAU) Electrical Specifications The power requirements for the first and second generation Central Distribution Units (CDU) are summarized in Table 4. The RAU is generally remotely powered from the CDU. Table 4. Electrical Specifications Line Voltage Power Consumption Power Supply Redundancy Backup Power Supply Slim Line Smart Rack 3U 100 – 240 VAC, 47 – 63 Hz 40 Watts (CDU w/6 RAU’s) None External 100 – 240 VAC, 47 – 63 Hz 140 Watts (CDU w/20 RAU’s) Hot Standby External - 19 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide Environmental and Mechanical Specifications The environmental and mechanical specifications are summarized in Table 5. We have not completed shock and vibration testing at this time. Table 5. InCell™ Environmental and Mechanical Specification Parameters CDU RAU Enclosure Dimensions 1.75”H x 16.75”W x 12”D 1U, 19” rack-mountable 1.5”H x 5”W x 6.5”D Enclosure Weight 4 pounds 0.6 pounds RF Connector N-female, bi-directional SMA-female, bi-directional Fiber Connector 6 pairs (12), SC Type 1 pair (2), SC Type Remote Alarm from CDU 9-pin D-Sub with summary power and system link status N/A Local Alarm One power and one link status LED per antenna port One power and one link status LED AC Power 100-240 VAC, 47-63 Hz N/A DC Power 24 VDC output to each RAU +28 to +12 VDC input Maximum DC Power Draw CDU: 10 Watts System: 40 Watts with 6 RAUs 5 Watts MTBF > 27,000 hours > 180,000 hours -10 to +70o C Storage Temperature 0 to +50o C Operating Temperature Humidity 0 to 95 % RH, non-condensing MTBF A system MTBF using one CDU and six RAU’s is calculated to be 26,954 hours for the slim line unit and 9,851 hours for a fully populated 3U 20 unit chassis. Each RAU has a MTBF of 181,265 hours. These MTBF values were calculated using the Bellcore part count method. MTTR Low MTTR values are achieved due to the extensive internally monitoring capability. The MTTR of the Slim Line unit is estimated at 15 minutes using a board replacement maintenance concept. The MTTR for the 3U chassis is less than 5 minutes as modules can be easily replaced while the unit is operating. The RAU MTTR is 5 to 30 minutes depending upon the complexity and ease of access to the installed device. The proposed maintenance concept for the RAU is a direct replacement of the unit. - 20 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide InCell™ Network Monitoring System The InCell™ family is designed to minimize maintenance and monitoring costs. Provisions are made for both local and remote monitoring of small and large systems. The InCell™ system continuously monitors and reports status of the system hardware, by a combination of indicators available at the central hub and at each remote antenna and alarms for remote monitoring that aid in system fault detection and fault isolation down to a circuit board or cable. The wideband, single mode fiber cable allows a low frequency RF test signal to be continuously passed over the downlink and uplink signal paths with multiple RF wireless signals. In a dual band system, the 67 MHz pilot test signal, the 800 MHz service, and the 1900 MHz service signals simultaneously pass through the downlink and uplink paths. Pilot Tone Generation The CDU generates a continuous pilot tone for system level fault detection and isolation and distributes the signal to each RAU port. This low frequency RF tone is combined with the downlink RF signal and transmitted over the fiber optic cable to the RAU where it is received and filtered from the downlink RF signal. In the RAU, the pilot tone is filtered, amplified and combined with the RF uplink signal to be sent over the optical uplink path back to the CDU. Within the RAU, the pilot tone is detected by a threshold detector to indicate the presence of the pilot tone at a minimum signal level. The pilot threshold detector drives an LED on the RAU that indicates that the downlink optical signal path to the RAU is connected. The return path pilot tone from the RAU is also filtered, amplified and detected. The detected pilot signal is passed to a threshold detector to indicate the tone presence at a minimum signal level. The pilot threshold detector in turn drives an LED at each port of the CDU indicating that both the downlink to the RAU and the uplink back to the CDU are connected and that power is properly functioning at the RAU. RAU Indicators The Power indicator on the RAU shows that DC power from the composite cable is present at the RAU. If the indicator is green, DC power is present in the RAU. The LINK indicator on the RAU shows that the pilot tone from the CDU is present over the downlink. When the LINK indicator is off on the RAU, the downlink optical path between the CDU and the RAU is installed correctly and DC power is present in the RAU. If the LINK indicator is red, there may be a problem with the downlink optical path between the CDU and RAU or a problem with the RAU power. The RAU indicators allow system installers and maintainers to easily determine the RAU functional status, the power supply status, and the downlink optical path status. CDU Front Panel Indicators The Power indicator for each port of the CDU indicates that the DC power is present at that port. If the CDU Power indicator is green, power is good at that CDU port, also indicating that the internal AC power supply is good. If the Power indicator for one CDU port is off, there is - 21 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide problem with that CDU port interface. If the Power indicators for all CDU ports are off, the AC power supply may be bad, AC power may be switched off or there may be another problem with the AC power. The LINK indicator at each CDU port shows that the CDU generated pilot tone was sent over the downlink from the CDU to the RAU then received and transmitted over the uplink path from the RAU back to the CDU. When the CDU LINK indicator is off, the downlink and uplink optical paths are installed correctly and DC power is present in the RAU. If the LINK indicator is red, there may be a problem with the fiber optic signals between the CDU and RAU; a problem with the RAU power; or a problem with the RAU itself. The CDU indicators allow system installers and maintainers to easily determine each RAU functional status, power distribution to each RAU, and the correct connection of the fiber optic cables. Alarm Functions The CDU has two alarm outputs on the rear panel to indicate the overall health of the power supply and the uplink and downlink to each remote antenna units. The link alarm output is a summary alarm of all of system uplinks and downlinks and remote antenna power. The alarm outputs are through a DB-9 connector located on the CDU chassis rear panel. Remote Monitoring Functions As an option that will be available in February 2001, InCell™ Systems will support remote system health monitoring using standard protocols that will allow customers to monitor full system status. This feature uses an embedded processor (see Error! Reference source not found.) to monitor and report system health for the CDU and all RAUs, including power supplies, uplink and downlink paths and cables. With this option, the InCell™ System hardware can be remotely monitored in three ways: v Locally using a RS-232 connection to a terminal or PC (see Figure 13) v Remotely using an SNMP Agent chassis connected to a telephone, LAN/WAN or other communications medium v Remotely using dry-contact terminals connected to a third party SCADA In the first method, the RS-232C interface option does not require a separate chassis. An RS-485 bus daisy chains the system status and alarms together as illustrated in Figure 13 and Figure 14. Communications between CDU’s is accomplished over an RS-485 link, and the user can connect to the master bus using a standard computer or RS-232C terminal. In the second method, a separate 1U chassis is required to act as the SNMP agent. The SNMP agent allows a network management system to monitor InCell™ device(s) by telephone or network connection using industry standard interfaces. The SNMP agent performs network management operations such as setting configuration parameters, alarm notification and current operation statistics. A database of the InCell™ network management information, called the management information base (MIB), is maintained by the Agent. - 22 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide In the third method, dry contact alarm terminals can be connected to a third party SCADA system over copper wires. Management System SNMP InCell Agent InCell RS-485 (network) InCell RS-232 (Local) InCell Laptop computer Figure 13. Remote Alarm Capability RS485 SERIAL INTERFACE NETWORK RF REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM REMOTE ALARM RF RF RF RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF POWER 100-240 VAC RF RF RF RF RF RF IN D00-48 Figure 14. Daisy Chaining CDU’s for Remote Monitoring - 23 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide InCell™ Operation, Maintenance and Support Operation InCell™ system operation is continuous. Andrew recommends using an uninterruptible power supply (UPS) to provide power to the CDU. If the system uses composite cable to provide power to the remote antenna units located throughout the building, the UPS can keep the CDU and all RAUs powered and operational during brownouts and power outages. Unlike some hybrid fiber distributed antenna systems that use frequency translation in the wireless distribution process, the InCell™ uses no frequency synthesizers or synchronizing circuitry that may be affected by power failures. The InCell™ operates immediately after power is applied and is not susceptible to power failures. Regular Maintenance Minimal maintenance is required to support installed InCell™ systems. System maintainers should ensure that all RF, power and fiber connectors are tight and that the CDU is mounted with adequate room to allow air to flow into the chassis. Indicator LEDs show system status while relay and optional remote alarm interfaces allow small or large system status to be monitored. Andrew does recommend using a commercially available fiber optic cleaning kit to maintain clean fiber optic connections. Typically, after system installation, no removal or cleaning of the fiber connectors will be required. Fault Repair If a fault is detected in the system, maintainers can determine the problem cause problem by reviewing reports from remote monitoring systems or by observing the front panel LED indicators on the CDU chassis. Because the different CDU ports correspond to different remote antenna locations, maintainers can determine where the problem exists in the building. Maintainers can replace RAUs in the building without having to power down the system. If a CDU fails, spare CDU boards can be installed. Support Andrew engineers and technicians familiar with the operation of the InCell™ system are available Monday through Friday, 8am to 5pm CST. These personnel are familiar with distributed in-building antenna systems, with fiber optic cable installation and with troubleshooting and in-building coverage solutions. In special cases, Andrew has provided local support of indoor wireless distributed antenna systems. Please contact Andrew DCS if this type of maintenance support is required. Spare Policy For the Slim Line CDU assembly, we recommend sparing at the board level. This unit is comprised of 2 unique board types and a power supply module. There is a single printed circuit board that provides the necessary RF power, DC and alarm distribution and 6 identical printed - 24 - Andrew InCell™ Fiber Optic Distributed Antenna System Users Guide circuit boards that perform the gain and optical conversion (see Error! Reference source not found.). If the remote monitoring option is selected, there is a third 2-teir printed circuit board. - 25 -
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