FCC ID: NEO60-2128SERIES Q116270 Cell Enhancer

by: Axell Wireless latest update: 2008-03-03 model: 60-2128SERIES

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1		Cover Letter(s)	pdf		March 03 2008

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Fibre Optic Master and Remote Site User Handbook For R.F. Design & Integration, Inc. AFL Works Order AFL Product Part No. 60-212701 - 500 MHz F/O Master Site 60-212801 - 500 MHz F/O Remote Site Q116270 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 2 of 50 Table of Contents 1. 1.1. 1.2. INTRODUCTION ............................................................................................................ 5 Scope and Purpose of Document ............................................................................. 5 Limitation of Liability Notice....................................................................................... 5 2. 2.1. 2.2. 2.3. 2.4. 2.5. 2.6. 2.7. SAFETY CONSIDERATIONS......................................................................................... 6 Earthing of Equipment .............................................................................................. 6 Electric Shock Hazard............................................................................................... 6 RF Radiation Hazard ................................................................................................ 6 Lifting and other Health and Safety Recommendations ............................................ 6 Chemical Hazard ...................................................................................................... 7 Laser safety .............................................................................................................. 7 Emergency Contact Numbers ................................................................................... 7 3. 3.1. 3.2. 3.3. 3.4. MASTER SITE 60-212701 ............................................................................................. 8 60-212701 Parts List (Major Components) ............................................................... 8 60-212701 Diagrams ................................................................................................ 9 60-212701 System Diagram ................................................................................... 10 60-212701 Major Sub Components ........................................................................ 11 3.4.1. UHF 3dB Splitter/Combiner (05-002603) ............................................................. 11 3.4.2. Switched Attenuator 0-30dB 0.25W (10-000701)................................................. 11 3.4.3. Switched Attenuator 0-30dB 1W (10-000801)...................................................... 12 3.4.4. Fibre Optic Transmitter (2.7GHz) (20-005401) .................................................... 12 3.4.5. Fibre Optic Receiver (2.7GHz) (20-005501) ........................................................ 13 3.4.6. 12V Relay Assembly (80-008901) ....................................................................... 14 3.4.7. PSU 50W (12V 5A) (96-300048).......................................................................... 15 4. 4.1. 4.2. REMOTE SITE 60-212801 ........................................................................................... 16 100W Linearised Amplifier (80-245101).................................................................. 16 4.1.1. 80-245101 Specification....................................................................................... 16 4.1.2. 80-245101 Parts List (Major Components) .......................................................... 16 4.1.3. 80-245101 Photographs ...................................................................................... 17 4.1.4. 80-245101 Outline Drawing ................................................................................. 18 4.1.5. 80-245101 System Diagram ................................................................................ 19 4.1.6. 80-245101 Major Sub Components ..................................................................... 20 25W Linearised Amplifier Module (12-026902) ......................................................... 20 4.1.6.1. 4.1.6.2. UHF 3dB Splitter/Combiner (05-002603)................................................................... 21 24V Relay PCB Assembly (80-008902)..................................................................... 21 4.1.6.3. Remote Uplink/Downlink Shelf (60-212802) ........................................................... 22 4.2.1. 60-212802 Parts List (Major Components) .......................................................... 22 4.2.2. 60-212802 Photographs ...................................................................................... 23 4.2.3. Remote Site 60-212801 System Diagram............................................................ 25 4.2.4. 60-212802 Major Sub Components ..................................................................... 26 4.2.4.1. Bandpass Filter (02-010901) ..................................................................................... 26 4.2.4.2. Bandpass Filter (02-011204) ..................................................................................... 26 4.2.4.3. Switched Attenuator 0-30dB 0.25W (10-000701) ...................................................... 27 4.2.4.4. Switched Attenuator 0-30dB 1W (10-000801) ........................................................... 27 4.2.4.5. Low Noise Amplifier (11-007402) .............................................................................. 28 Low Power Amplifier (1W) (11-007901)..................................................................... 29 4.2.4.6. Low Power Amplifier (1W) (12-021801)..................................................................... 30 4.2.4.7. 4.2.4.8. Low Power Amplifier (2W) (12-021802)..................................................................... 31 4.2.4.9. DC-DC Convter 24V -12V (13-003011) .................................................................... 32 4.2.4.10. Mains Filter (8 Amp) (13-003301) ............................................................................ 32 4.2.4.11. Downlink AGC Components .................................................................................... 33 4.2.4.12. Uplink AGC Components ......................................................................................... 34 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 3 of 50 12V Relay Board (20-001601) ................................................................................. 35 4.2.4.13. 4.2.4.14. 24V Relay Board (20-001602) ................................................................................. 35 4.2.4.15. Fibre Optic Transmitter (2.7GHz) (20-005401) ........................................................ 36 4.2.4.16. Fibre Optic Receiver (2.7GHz) (20-005501) ............................................................ 37 4.2.4.17. 12V Relay Assembly (80-008901) ........................................................................... 38 4.2.4.18. 60A Dual Diode (94-100004) ................................................................................... 38 4.2.4.19. PSU 600W (24V 23A) (96-300067).......................................................................... 38 5. INSTALLATION ............................................................................................................ 39 5.1 General Remarks....................................................................................................... 39 5.2 Electrical Connections ............................................................................................... 39 5.3 RF Connections ......................................................................................................... 39 5.4 Optical Connections................................................................................................... 39 5.5 Commissioning .......................................................................................................... 40 5.6 Antenna Installation & Gain Calculations ................................................................... 40 5.7 Antenna Isolation ....................................................................................................... 41 6. 6.1. MAINTENANCE............................................................................................................ 42 Fault Finding ........................................................................................................... 42 6.1.1. Quick Fault Checklist ........................................................................................... 42 6.1.2 Fault Isolation....................................................................................................... 42 6.1.3 Downlink .............................................................................................................. 43 6.1.4 Uplink ................................................................................................................... 43 6.1.5 Fibre Optics.......................................................................................................... 43 6.1.7 Checking service.................................................................................................. 43 Fault repair........................................................................................................... 43 6.1.8 6.1.9 Service Support ................................................................................................... 44 6.2 Tools & Test Equipment............................................................................................. 44 6.3 Care of Modules......................................................................................................... 45 6.3.1 General Comments.............................................................................................. 45 6.3.2 Module Removal (LNAs, general procedure): ..................................................... 45 6.3.3 Module Replacement (general):........................................................................... 45 Power Amplifiers .................................................................................................. 45 6.3.4 6.3.5 Low Power Amplifier Replacement ...................................................................... 46 6.3.6 Module Transportation: ........................................................................................ 46 APPENDIX A ......................................................................................................................... 47 Glossary of Terms used in this document ............................................................... 47 Key to Drawing Symbols used in this document ..................................................... 48 EC Declaration of Conformity.................................................................................. 49 Amendment List Record Sheet ............................................................................... 50 A.1. A.2. A.3. A.4. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 4 of 50 1. INTRODUCTION 1.1. Scope and Purpose of Document This handbook is for use solely with the equipment identified by the Aerial Facilities Limited (AFL) Part Number shown on the front cover. It is not to be used with any other equipment unless specifically authorised by AFL. This is a controlled release document and, as such, becomes a part of Aerial Facilities Total Quality Management System. Alterations and modification may therefore only be performed by AFL. AFL recommends that the installer of this equipment familiarise themselves with the safety and installation procedures contained within this document before installation commences. The purpose of this handbook is to provide the user/maintainer with sufficient information to service and repair the equipment to the level agreed. Maintenance and adjustments to any deeper level must be performed by AFL, normally at the companys repair facility in Chesham, England. This handbook has been prepared in accordance with BS 4884, and AFLs Quality procedures, which maintain the companys registration to BS EN ISO 9001:2000 and to the R&TTE Directive of the European Parliament. Copies of the relevant certificates and the company Quality Manual can be supplied on application to the Quality Manager. This document fulfils the relevant requirements of Article 6 of the R&TTE Directive. 1.2. Limitation of Liability Notice This manual is written for the use of technically competent operators/service persons. No liability is accepted by AFL for use or misuse of this manual, the information contained therein, or the consequences of any actions resulting from the use of the said information, including, but not limited to, descriptive, procedural, typographical, arithmetical, or listing errors. Furthermore, AFL does not warrant the absolute accuracy of the information contained within this manual, or its completeness, fitness for purpose, or scope. AFL has a policy of continuous product development and enhancement, and as such, reserves the right to amend, alter, update and generally change the contents, appearance and pertinence of this document without notice. All AFL products carry a twelve month warranty from date of shipment. The warranty is expressly on a return to base repair or exchange basis and the warranty cover does not extend to on-site repair or complete unit exchange. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 5 of 50 2. SAFETY CONSIDERATIONS 2.1. Earthing of Equipment Equipment supplied from the mains must be connected to grounded outlets and earthed in conformity with appropriate local, national and international electricity supply and safety regulations. 2.2. Electric Shock Hazard The risk of electrical shocks due to faulty mains driven power supplies whilst potentially ever present in any electrical equipment, would be minimised by adherence to good installation practice and thorough testing at the following stages:

a) b) c) Original assembly. Commissioning. Regular intervals, thereafter. All test equipment must be in good working order prior to its use. High current power supplies can be dangerous because of the possibility of substantial arcing. Always switch off during disconnection and reconnection. 2.3. RF Radiation Hazard RF radiation, (especially at UHF frequencies) arising from transmitter outputs connected to AFLs equipment, must be considered a safety hazard. This condition might only occur in the event of cable disconnection, or because a spare output has been left un-terminated. Either of these conditions would impair the systems efficiency. No investigation should be carried out until all RF power sources have been removed. This would always be a wise precaution, despite the severe mismatch between the impedance of an N type connector at 50, and that of free space at 377, which would severely mitigate against the efficient radiation of RF power. Radio frequency burns could also be a hazard, if any RF power carrying components were to be carelessly touched!

Antenna positions should be chosen to comply with requirements (both local & statutory) regarding exposure of personnel to RF radiation. When connected to an antenna, the unit is capable of producing RF field strengths, which may exceed guideline safe values especially if used with antennas having appreciable gain. In this regard the use of directional antennas with backscreens and a strict site rule that personnel must remain behind the screen while the RF power is on, is strongly recommended. Where the equipment is used near power lines or in association with temporary masts not having lightning protection, the use of a safety earth connected to the case-earthing bolt is strongly advised. 2.4. Lifting and other Health and Safety Recommendations Certain items of AFL equipment are heavy and care should be taken when lifting them by hand. Ensure that a suitable number of personnel, appropriate lifting apparatus and appropriate personal protective equipment is used especially when installing Cell Enhancers above ground e.g. on a mast or pole. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 6 of 50 2.5. Chemical Hazard Beryllium Oxide, also known as Beryllium Monoxide, or Thermalox, is sometimes used in devices within equipment produced by Aerial Facilities Ltd. Beryllium oxide dust can be toxic if inhaled, leading to chronic respiratory problems. It is harmless if ingested or by contact. Products that contain beryllium are load terminations (dummy loads) and some power amplifiers. These products can be identified by a yellow and black skull and crossbones danger symbol (shown above). They are marked as hazardous in line with international regulations, but pose no threat under normal circumstances. Only if a component containing beryllium oxide has suffered catastrophic failure, or exploded, will there be any danger of the formation of dust. Any dust that has been created will be contained within the equipment module as long as the module remains sealed. For this reason, any module carrying the yellow and black danger sign should not be opened. If the equipment is suspected of failure, or is at the end of its life-cycle, it must be returned to Aerial Facilities Ltd for disposal. To return such equipment, please contact the Quality Department, who will give you a Returned Materials Authorisation (RMA) number. Please quote this number on the packing documents, and on all correspondence relating to the shipment. PolyTetraFluoroEthylene, (P.T.F.E.) and P.T.F.E. Composite Materials Many modules/components in AFL equipment contain P.T.F.E. as part of the RF insulation barrier. This material should never be heated to the point where smoke or fumes are evolved. Any person feeling drowsy after coming into contact with P.T.F.E. especially dust or fumes should seek medical attention. 2.6. Laser safety General good working practices adapted from EN60825-2: 2004/ EC 60825-2:2004 Do not stare with unprotected eyes or with any unapproved optical device at the fibre ends or connector faces or point them at other people, Use only approved filtered or attenuating viewing aids. Any single or multiple fibre end or ends found not to be terminated (for example, matched, spliced) shall be individually or collectively covered when not being worked on. They shall not be readily visible and sharp ends shall not be exposed. When using test cords, the optical power source shall be the last connected and the first disconnected; use only approved methods for cleaning and preparing optical fibres and optical connectors. Always keep optical connectors covered to avoid physical damage and do not allow any dirt/foreign material ingress on the optical connector bulkheads. The optical fibre jumper cable maximum bend radius is 3cm; any smaller radii may result in optical cable breakage or excessive transmission losses. Caution: The FO units are NOT weather proof. 2.7. Emergency Contact Numbers The AFL Quality Department can be contacted on:

Telephone Fax. e-mail

+44 (0)1494 777000

+44 (0)1494 777002 qa@aerialfacilities.com Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 7 of 50 3. MASTER SITE 60-212701 The Master Site Shelf is a 3U Rack mount shelf and provides two separate RF paths, uplink and downlink with provision to vary the gain of either path using a switched variable attenuator, one in each path. The active Fibre Optic modules in the unit are powered from an internal 12V PSU which runs from a mains feed of 110V AC The downlink signal is received from the antenna and enters the master site via the port labelled TX, the signal passes through a switched variable attenuator (10-000801) providing up to 30dB of attenuation 2dB steps. After leaving the attenuator the signal is split into two equal paths by a 3dB splitter/combiner (05-002603) and each path is passed into a Fibre Optic Transmitter (20-005401) where the signal is modulated onto a laser as an optical signal for transmission to the remote site via fibre optic cable. The fibre optic signal leaves the master site via the ports labelled F/O DL (Fibre Optic Downlink). Only one F/O DL port is used, the second one being available for future expansion. Uplink signals are received at the master site as optical signals sent from the remote site, the fibre optic cable carrying the optical signals enter the master site via the ports labelled F/O UL (Only one F/O UL port is used, the second one being available for future expansion). Upon entering the master site the optical signal is passed to a fibre optic receiver (20-005501) where the signal is demodulated into an RF signal. After leaving the fibre optic receivers the two RF signal paths are combined by a 3dB splitter/combiner (05-002603) to produce a single path which then passes through a switched variable attenuator (10-000701) providing up to 30dB of attenuation 2dB steps. After leaving the attenuator the RF signal leaves the master site via the port labelled RX 3.1. 60-212701 Parts List (Major Components) Component Part 05-002603 10-000701 10-000801 20-005401 20-005501 80-008901 96-300048 96-920022 Component Part Description UHF 3dB Splitter/Combiner Switched Attenuator 0-30dB 0.25W Switched Attenuator 0-30dB 1W Fibre Optic Transmitter (2.7GHz) Fibre Optic Receiver (2.7GHz) 12V Relay Assembly PSU 50W (12V 5A) Circuit Breaker (3A) Qty Per Assembly 2 1 1 1 1 1 1 1 The individual fibre optic TX and RX units are fitted with a pair of status indicators on their front panels. One is a green LED, which indicates that the unit is connected to a 12 Volt DC power supply. This indicator is common to both transmit and receive units. The second LED on the TX module indicates that the laser is operating (transmitting). On the RX unit the second LED indicates that a laser-light signal is being received. When all the fibre connections are completed and power to each site is connected each fibre unit must show two illuminated indicators. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 8 of 50 3.2. 60-212701 Diagrams Master Site 60-212701 Front Panel (Not to scale) A Green LED Power On B Red LED Alarm C Green LED Fibre Optic Receiver 1 Power On D Green LED Fibre Optic Receiver 1 Laser On, LED not illuminated = Alarm E Fibre Optic Receiver 1 Gain Adjust F Green LED Fibre Optic Receiver 2 Power On G Green LED Fibre Optic Receiver 2 Laser On, LED not illuminated = Alarm H Fibre Optic Receiver 2 Gain Adjust I Green LED Fibre Optic Transmitter 1 Power On J Green LED Fibre Optic Transmitter 1 Laser On, LED not illuminated = Alarm K Green LED Fibre Optic Transmitter 2 Power On L Green LED Fibre Optic Transmitter 2 Laser On, LED not illuminated = Alarm Master Site 60-212701 Rear Panel (Not to scale) A RX Port Uplink RF out to antenna B Fibre Optic input 2 (uplink from remote site) C Fibre Optic input 1 (uplink from remote site) D TX Port Downlink RF in from antenna E Fibre Optic output 2 (downlink to remote site) F Fibre Optic output 1 (downlink to remote site) G Earth connection H Uplink Switched Attenuator I Downlink Switched Attenuator J Alarm Output K AC Trip Switch L AC input (110V) Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 9 of 50 3.3. 60-212701 System Diagram Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 10 of 50 3.4. 60-212701 Major Sub Components 3.4.1. UHF 3dB Splitter/Combiner (05-002603) The 3dB Splitter/Combiner (05-002603) is a device for accurately matching two RF signals to a single port or splitting an RF signal to two ports whilst maintaining an accurate 50 load to all inputs/outputs and ensuring that the VSWR and insertion losses are kept to a minimum. 05-002603 Specification PARAMETER SPECIFICATION Frequency range 380 - 520 MHz Ports Bandwidth 140 MHz As Combiner 2 inputs 1 output As Splitter 1 input 2 outputs Insertion loss 3.5 dB (typical) Isolation >18 dB Return Loss (VSWR) Input Better than 1.3:1 Return Loss (VSWR) Output Better than 1.3:1 Impedance 50 Power Rating Combiner 0.5 Watt Power Rating Splitter 20 Watts Connectors SMA female Size 54 x 44 x 21 mm Weight 200 gm (approximately) 3.4.2. Switched Attenuator 0-30dB 0.25W (10-000701) 10-000701 provides attenuation from 0 - 30dB in 2 dB steps, the attenuation is simply set using the four miniature toggle switches on the top of each unit. Each switch is clearly marked with the attenuation it provides, and the total attenuation in line is the sum of the values switched in. They are designed to maintain an accurate 50 impedance over their operating frequency at both input and output. 10-000701 Specification PARAMETER SPECIFICATION Attenuation Values 0-30dB Attenuation Steps 2, 4, 8 and 16dB Power Handling 0.25 Watt Attenuation Accuracy 1.0 dB Frequency Rang DC to 1GHz Impedance 50 Connectors SMA VSWR 1.3:1 Weigh 0.2kg Temperature range operation -20C to +60C storage -40C to +70C Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 11 of 50 3.4.3. Switched Attenuator 0-30dB 1W (10-000801) 10-000801 provides attenuation from 0 - 30dB in 2 dB steps, the attenuation is simply set using the four miniature toggle switches on the top of each unit. Each switch is clearly marked with the attenuation it provides, and the total attenuation in line is the sum of the values switched in. They are designed to maintain an accurate 50 impedance over their operating frequency at both input and output. 10-000801 Specification PARAMETER SPECIFICATION Attenuation Values 0-30dB Attenuation Steps 2, 4, 8 and 16dB Power Handling 1 Watt Attenuation Accuracy 1.0 dB Frequency Rang DC to 1GHz Impedance 50 Connectors SMA VSWR 1.3:1 Weigh 0.2kg Temperature range operation -20C to +60C storage -40C to +70C 3.4.4. Fibre Optic Transmitter (2.7GHz) (20-005401) The transmitter modulates the RF signal on to a laser, which is then transmitted over a fibre optic cable to a receiver. The laser current is monitored and compensated for constant optical out put power against temperature variation and aging. Laser over-current alarm function is provided as LED output as well as open collect and voltage-free relay contacts on 9 way D-type connector. 20-005401 specification PARAMETER SPECIFICATION Frequency Range (RF path) 70 - 3000 MHz Frequency Range (Data path) 20 35 MHz Available Link Gain (RF Path) 18 dB Link Gain ( DATA Path) 0 dB Gain Flatness (entire frequency range) 1.5 dB p-p

Gain vs. Temperature -20 to 70 C 3.5 dB Gain adjustment range ( RF Path ) 30 dB In/Out Return Loss (RF path) 10 dB Min Output IP3 @ max gain * 37 dBm In/Output IP3 @ 0dB Gain * 33 dBm RF impedance 50 Ohm Noise Figure @ 0dB gain (400MHz) 36 dB Optical Transmit Power 2.70.3 dBm Optical return loss >50 dB Received Power Alarm Threshold -10 dBm(optic) Optical wavelength 1310 nm DC Supply Voltage 10-12 Vdc DC Supply Current 120 mA Operating Temperature -20 to 70 C Storage Temperature -30 to 85 C RF Connector type SMA Fibre optic connector type FC/APC Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 12 of 50 Fibre Optic Transmitter (20-005401) D Type Female Connector Pinouts Pin No. 1 2 3 4 5 6 7 8 9 Signal Description

+10-12V DC Power 0V DC, Power Ground 0V DC, Power Ground No Connection No Connection TTL Alarm, (0V=good, open coll.= fail) Relay Alarm Contact (N.C) Relay Alarm Contact (Common) Relay Alarm Contact (N.O) 3.4.5. Fibre Optic Receiver (2.7GHz) (20-005501) The receiver demodulates RF signals from the laser with a typical gain of 18dB and with 30dB adjustability in the RF domain. The received optical power is monitored for alarm function in case of fibre damage. 20-005501 Specification PARAMETER SPECIFICATION Frequency Range (RF path) 70 - 3000 MHz Frequency Range (Data path) 20 35 MHz Available Link Gain (RF Path) 18 dB Link Gain ( DATA Path) 0 dB Gain Flatness (entire frequency range) 1.5 dB p-p

Gain vs. Temperature -20 to 70 C 3.5 dB Gain adjustment range ( RF Path ) 30 dB In/Out Return Loss (RF path) 10 dB Min Output IP3 @ max Gain 37 dBm In/Output IP3 @ 0dB Gain 33 dBm RF impedance 50 Ohm Noise Figure @ 0dB gain (400MHz) 36 dB Optical Transmit Power 2.70.3 dBm Optical return loss >50 dB Received Power Alarm Threshold -10 dBm(optic) Optical wavelength 1310 nm DC Supply Voltage 10-12 Vdc DC Supply Current 350 mA Operating Temperature -20 to 70 C Storage Temperature -30 to 85 C RF Connector type SMA Fibre optic connector type FC/APC Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 13 of 50 Fibre Optic Receiver (20-005501) D Type Female Connector Pinouts Pin No. 1 2 3 4 5 6 7 8 9 Signal Description

+10-12V DC Power 0V DC, Power Ground 0V DC, Power Ground No Connection No Connection TTL Alarm, (0V=good, open coll.= fail) Relay Alarm Contact (N.C) Relay Alarm Contact (Common) Relay Alarm Contact (N.O) 3.4.6. 12V Relay Assembly (80-008901) The General Purpose Relay Board allows the inversion of signals and the isolation of circuits. It is equipped with a single dual pole change-over relay RL1, with completely isolated wiring, accessed via a 15 way in-line connector. The relay is provided with polarity protection diodes and diodes for suppressing the transients caused by "flywheel effect" which can destroy switching transistors or induce spikes on neighbouring circuits. Its common use is to amalgamate all the alarm signals into one, volts-free relay contact pair for the main alarm system. 80-008901 Specification PARAMETER SPECIFICATION Operating voltage 8 to 30V (floating earth) Alarm threshold Vcc - 1.20 volt +15%

Alarm output relay contacts Max. switch current 1.0Amp Max. switch volts 120Vdc/60VA Max. switch power 24W/60VA Min. switch load 10.0A/10.0mV Relay isolation 1.5kV Mechanical life >2x107 operations Relay approval BT type 56 Temperature range Connector details Screw terminals

-10C to +60C storage -20C to +70C operational Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 14 of 50 3.4.7. PSU 50W (12V 5A) (96-300048) The power supply unit is a switched-mode type capable of supplying 12V DC at 5Amps continuously. No routine maintenance of the PSU is required. If a fault is suspected, then the output voltage from the power supply may be measured on its output terminals. This is typically set to 12.2V. The adjustment potentiometer will be found close to the DC output terminals. All the PSUs used in AFL Cell Enhancers are capable of operation from either 110 or 220V nominal AC supplies. The line voltage is sensed automatically, so no adjustment or link setting is needed by the operator. 96-300048 Specification AC Input Supply 110 or 220V nominal Voltage: 90 to 132 or 180 to 264V

(absolute limits) Frequency: 47 to 63Hz DC Output Supply Voltage:

12V DC (nominal) 10.5-13.8V (absolute limits) Current: 5.0A Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 15 of 50 4. REMOTE SITE 60-212801 The Remote Site 60-212801 is composed of two rack mount chassis, one containing the filtering, and amplification modules along with the fibre optic transmitter and receiver (60-212802), the second tray is a 100 W amplifier (80-245101), part of the Downlink signal path. 60-212801 sub components section Component Component Part Description 4.1. 4.2. Part 80-245101 60-212802 100W Linearised Amplifier Remote Uplink/Downlink Tray Qty Per Assembly 1 1 4.1. 100W Linearised Amplifier (80-245101) 100W Linearised Amplifier (80-245101) shelf is a Class A 100W TETRA Linearised Class A amplifier where 4 linearised power amplifiers are combined together in a phased-parallel arrangement. Its housing is a 4U 19 Rack-mount shelf with SMA connectors for the RF input/output, 2 D-Type connectors for the alarm function and 2 DC connectors with fuses for the 24 DC supplies. Cooling is effected by fans mounted on the front panel. It has a built in Current Fault Alarm Function with the four amplifiers in two summary alarm paths. The summary alarm on D connector A will show an alarm for the two amplifiers mounted on the top of the shelf (amplifier pair A). The summary alarm on D connector B will show an alarm for the two amplifiers mounted at the bottom of the shelf (amplifier pair B) 4.1.1. 80-245101 Specification PARAMETER SPECIFICATION Frequency range: 440-500MHz Small signal gain: 37dB Gain flatness: 0.5dB I/O Return loss: >18dB 1dB compression point: +50dBm OIP3: +69dBm Supply voltage: 24V DC (x2) Supply current: 18-19Amps Environmental protection rating:

operational:

storage:

Weight: <5kg Impedance: 50 IP44

-10C to +60C

-40C to +70C Temperature range 4.1.2. 80-245101 Parts List (Major Components) AFL Part No. 05-002603 12-026902 80-008902 96-400002 Part Description UHF 3dB Splitter/Combiner 25W Linearised Amplifier Module 24V Relay PCB Assembly Cooling Fan Qty. 6 4 2 4 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 16 of 50 4.1.3. 80-245101 Photographs 100W Linearised Amplifier (80-245101) rear view A B C Amplifier pair A Amplifier pair B Earthing connections 100W Linearised Amplifier (80-245101) front view Red LED Alarm Amplifier pair A A Green LED Power On Amplifier pair A B C RF input from 60-212802 D E F G Alarm output Amplifier pair A DC input Amplifier pair A Fuse holder Amplifier pair A Earth connection for 80-245101 H Green LED Power On Amplifier pair B I J K L M N Cooling fans Red LED Alarm Amplifier pair B RF output to 60-212802 Alarm output Amplifier pair B DC input Amplifier pair B Fuse holder Amplifier pair B Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 17 of 50 B N O R E W O P T U P T U O F R B M R A L A D U T S H T R A E 0 5

. 1 0 1 4.1.4. 80-245101 Outline Drawing B T R O P M R A L A B T U P N I C D V 4 2 E S U F A 5 1 4 N A F 3 N A F 2 N A F 1 N A F D U T S H T R A E A T U P N I C D V 4 2 T R O P M R A L A T U P N I F AR M R A L A E S U F A 5 1 A N O R E W O AP 482.00 177.00 I I I K C A R R E F L P M A D E Z R A E N L A S S A L C A R T E T W 0 0 1 I L P L P E U S S I I L A N G R O I 3 3 7 3 N C E A 1 A A 1 0 1 5 4 2

0 8 o N T R A P A 1 0 9 1 5 4 2

0 8 4

1 I G N W A R D E N L T U O I B I B C 5 0 0 2 9 0

4 1 5 0 0 2 9 0

4 1 Y O L L A M U N M U L A I I

I L A R E T A M G U L P E P Y T

Y A W 9

X C N

G U L P N P 3 I 5 0 6 0

1 2 L P T E K C O S A M S

S R O T C E N N O C 0 0

. 4 9 4 0 0

. 4 5 4 D U T S H T R A E 436.80 464.50 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 18 of 50 4.1.5. 80-245101 System Diagram Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 19 of 50 4.1.6. 80-245101 Major Sub Components 4.1.6.1. 25W Linearised Amplifier Module (12-026902) Linearised Power Amplifier (12-026902) is a multi-stage, solid state power amplifier. Class A circuitry is employed throughout the device to ensure excellent linearity over a wide dynamic frequency range. All the semi-conductor devices are very conservatively rated to ensure low device junction temperatures and a long, trouble free working lifetime. The power amplifier should require no maintenance over its operating life. Under no circumstances should the cover be removed or the side adjustments disturbed unless it is certain that the amplifier has failed; since it is critically aligned during manufacture and any re-alignment will require extensive test equipment. The module housing is an aluminium case (Iridite NCP finish) with SMA connectors for the RF input/output and a D-Type connector for the power supply and the Current Fault Alarm Function. 12-026902 Specification PARAMETER SPECIFICATION Frequency range: 440-500MHz (tuned to spec.) Bandwidth: <60MHz (typical) Maximum RF output: >25Watt Small signal gain: 37.5dB (typical) 1dB compression point: +44dBm 3rd order intercept point: +61dBm Noise figure: N/A Return input loss: >15dB Return output loss: >15dB VSWR: better than 1.5:1 Connectors: SMA female Supply: 4.6Amps @ 24V DC operation:

storage:

Weight: 1.5 kg

-10C to +60C

-20C to +70C Temperature range:

PA 7-Way Connector Pin-outs Connector Pin A1 (large pin) A2 (large pin) Signal

+24V DC GND 1 2 3 4 5 Alarm relay common TTL alarm/0V good Alarm relay contact (bad) Alarm relay contact (good) O/C good/0V bad (TTL) Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 20 of 50 4.1.6.2. UHF 3dB Splitter/Combiner (05-002603) The 3dB Splitter/Combiner (05-002603) is a device for accurately matching two RF signals to a single port or splitting an RF signal to two ports whilst maintaining an accurate 50 load to all inputs/outputs and ensuring that the VSWR and insertion losses are kept to a minimum. 05-002603 Specification PARAMETER SPECIFICATION Frequency range 380 - 520 MHz Ports Bandwidth 140 MHz As Combiner 2 inputs 1 output As Splitter 1 input 2 outputs Insertion loss 3.5 dB (typical) Isolation >18 dB Return Loss (VSWR) Input Better than 1.3:1 Return Loss (VSWR) Output Better than 1.3:1 Impedance 50 Power Rating Combiner 0.5 Watt Power Rating Splitter 20 Watts Connectors SMA female Size 54 x 44 x 21 mm Weight 200 gm (approximately) 4.1.6.3. 24V Relay PCB Assembly (80-008902) The General Purpose Relay Board allows the inversion of signals and the isolation of circuits. It is equipped with a single, dual pole, change-over relay RL1 with completely isolated wiring, accessed via screw terminals. The relay is provided with a polarity protection diode and diodes for suppressing the transients caused by "flywheel effect" which can destroy switching transistors or induce spikes on neighbouring circuits. Its common use is to amalgamate all the alarm signals into one, volts-free relay contact pair for the main alarm system. 80-008902 Technical Specification Parameter Max. switch current 1.0Amp Specification Max. switch volts 120Vdc/60VA Max. switch power 24W/60VA Min. switch load 10.0A/10.0mV Relay isolation 1.5kV Mechanical life >2x107 operations Relay approval BT type 56 Connector details 15-way 0.1" pitch Temperature range operational

-10C to +55C storage -40C to +70C Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 21 of 50 4.2. Remote Uplink/Downlink Shelf (60-212802) The Remote Uplink/Downlink Shelf is an 8U Rack mount shelf and provides two separate RF paths, uplink and downlink with provision to vary the gain of either path using a switched variable (0 to 30dB) attenuator, one in each path. Each path is also fitted with an Automatic Gain Control (AGC) circuit which consists of two units, a detector/amplifier and an attenuator. Normally the attenuators in the AGC circuit are at minimum attenuation. The detector/amplifier unit monitors the RF level being delivered by the power amplifier, and when a certain threshold is reached it begins to increase the value of the attenuator to limit the RF output to the (factory set) threshold; therefore overloading of the amplifiers is avoided. The downlink signal is received from the master site as an optical signal which is demodulated into an RF signal. The RF signal is then passed through a bandpass filter (tuned to pass the downlink bandwidth 502.4MHz to 502.8MHz) to reject out-of-band noise and then passes through the downlink AGC attenuator and into the Downlink Switched Attenuator. From the Switched Attenuator the Downlink signal passes through two low power amplifiers (1W, 15dB gain and 2W, 15dB gain) and then exits 60-212802 to go to the 100W Linearised Amplifier (80-245101). After leaving 60-212802 the downlink signal re-enters 60-212802, passing through the downlink AGC detector and a second bandpass filter before exiting the shelf via the D/L Output port The uplink RF path enters 60-212802 at the U/L Input port and the signal passes through a bandpass filter (tuned to pass the uplink bandwidth 505.4MHz to 505.8MHz) to reject out-of-band noise. After the bandpass filter the signal passes through a 30dB Low Noise Amplifier and then into the uplink Switched Attenuator followed by the uplink AGC attenuator. After the AGC attenuator the signal passes through a second bandpass filter and then through a low power amplifier (1W, 37dB gain) followed by the uplink AGC detector. From the AGC detector the uplink signal passes into a fibre optic transmitter where the RF signal is modulated into an optical signal for transmission via fibre optic cable to the master site. All the amplifier modules in this shelf are alarmed and the summary terminates at the rear panel mounted 9-way D alarm connector. 4.2.1. 60-212802 Parts List (Major Components) Component Part 02-010901 02-011204 10-000701 10-000801 11-007402 11-007901 12-021801 12-021802 13-003011 13-003301 17-001109 17-001117 17-001201 20-001601 20-001602 20-005401 20-005501 80-008901 93-510077 94-100004 96-300067 96-920026 Component Part Description Bandpass Filter Bandpass Filter Switched Attenuator 0-30dB 0.25W Switched Attenuator 0-30dB 1W Low Noise Amplifier Low Power Amplifier (1W) Low Power Amplifier (1W) Low Power Amplifier (2W) DC-DC Converter 24V -12V Mains Filter (8 Amp) AGC Logarithmic Detector /Amplifier AGC Detector /Amplifier AGC Attenuator 12V Relay Board 24V Relay Board Fibre Optic Transmitter (2.7GHz) Fibre Optic Receiver (2.7GHz) 12V Relay Assembly 0R02 50W Resistor Aluminium Clad 60A Dual Diode PSU 600W (24V 23A) Circuit Breaker 10A Qty Per Assembly 3 1 1 1 1 1 1 1 1 1 1 1 2 1 1 1 1 1 2 1 2 1 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 22 of 50 4.2.2. 60-212802 Photographs Remote Uplink/Downlink Tray (60-212802) front view A RF output to 100W Linearised Amplifier 80-245101 B Alarm input from amplifier pair A in 80-245101 C DC output to amplifier pair A in 80-245101 D Fuse on DC output to amplifier pair A in 80-245101 E RF input from 100W Linearised Amplifier 80-245101 F Alarm input from amplifier pair B in 80-245101 G DC output to amplifier pair B in 80-245101 H Fuse on DC output to amplifier pair B in 80-245101 I Green LED Power On J Red LED Alarm K Power On LED, Alarm LED and Gain Adjust for Fibre Optic Receiver 20-005501 L Power On LED and Alarm LED for Fibre Optic Transmitter 20-005401 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 23 of 50 Remote Uplink/Downlink Tray (60-212802) rear view A Uplink Fibre Optic output to Master site B Uplink RF input from mobile antenna C Downlink Fibre Optic input from Master site D Downlink RF output to mobile antenna E Uplink switched attenuator 10-000701 F Downlink switched attenuator 10-000801 G Alarm Output H AC Trip switch I AC Input (110V ) J DC Fuse K 12V DC Auxiliary Output L Earth connection M AC power cord N DC, RF and Alarm interconnections for Amplifier 80-245101 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 24 of 50 4.2.3. Remote Site 60-212801 System Diagram Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 25 of 50 4.2.4. 60-212802 Major Sub Components 4.2.4.1. Bandpass Filter (02-010901) Bandpass Filter (02-010901) is a multi-section design with a bandwidth dependent upon the passband frequencies, (both tuned to customer requirements). The response shape is basically Chebyshev with a passband design ripple of 0.1dB. The filters are of helical & combline design respectively, and are carefully aligned during manufacture in order to optimise the insertion loss, VSWR and intermodulation characteristics of the unit. The body and tuned elements are silver-plated to reduce surface ohmic losses and maintain a good VSWR figure and 50 load at the input and output ports. Being passive devices, the bandpass filters should have an extremely long operational life and require no maintenance. 02-010901 specification SPECIFICATION Passband Frequency Bandwidth PARAMETER Uplink 505.4 to 505.8MHz **

Downlink 502.4 to 502.8MHz **

Uplink 400kHz **

Downlink 400kHz **

Insertion Loss 1.2 dB (typical) Power Rating 50W Impedance 50 VSWR Better than 1.2:1 Connectors SMA Weight 3Kg (approximately)

**as tuned for use in 60-212802 uplink and downlink paths 4.2.4.2. Bandpass Filter (02-011204) Bandpass Filter 02-011204 is a multi-section designs with a bandwidth dependent upon the passband frequencies, (both tuned to customer requirements). The response shape is basically Chebyshev with a passband design ripple of 0.1dB. The filters are of combline design, and are carefully aligned during manufacture in order to optimise the insertion loss, VSWR and intermodulation characteristics of the unit. The cases and tuned elements are silver-plated to reduce surface ohmic losses and maintain a good VSWR figure and 50 load at the input and output ports. Being passive devices, the bandpass filters should have an extremely long operational life and require no maintenance. Should a filter be suspect, it is usually most time efficient to replace the module rather than attempt repair or re-tuning. No adjustments should be attempted without full network sweep analysis facilities to monitor both insertion loss and VSWR simultaneously. 02-011204 Specification Passband Frequency 502.4 to 502.8MHz **

Bandwidth 400kHz **

Insertion Loss <1.0dB Power Rating 100W Impedance 50 VSWR 1.2:1 (typical) Connectors SMA Weight 3Kg (approximately)

**as tuned for use in 60-212802 uplink path Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 26 of 50 4.2.4.3. Switched Attenuator 0-30dB 0.25W (10-000701) 10-000701 provides attenuation from 0 - 30dB in 2 dB steps The attenuation is simply set using the four miniature toggle switches on the top of each unit. Each switch is clearly marked with the attenuation it provides, and the total attenuation in line is the sum of the values switched in. They are designed to maintain an accurate 50 impedance over their operating frequency at both input and output. 10-000701 Specification PARAMETER SPECIFICATION Attenuation Values 0-30dB Attenuation Steps 2, 4, 8 and 16dB Power Handling 0.25 Watt Attenuation Accuracy 1.0 dB Frequency Rang DC to 1GHz Impedance 50 Connectors SMA VSWR 1.3:1 Weigh 0.2kg Temperature range operation -20C to +60C storage -40C to +70C 4.2.4.4. Switched Attenuator 0-30dB 1W (10-000801) 10-000801 provides attenuation from 0 - 30dB in 2 dB steps The attenuation is simply set using the four miniature toggle switches on the top of each unit. Each switch is clearly marked with the attenuation it provides, and the total attenuation in line is the sum of the values switched in. They are designed to maintain an accurate 50 impedance over their operating frequency at both input and output. 10-000801 Specification PARAMETER SPECIFICATION Attenuation Values 0-30dB Attenuation Steps 2, 4, 8 and 16dB Power Handling 1 Watt Attenuation Accuracy 1.0 dB Frequency Rang DC to 1GHz Impedance 50 Connectors SMA VSWR 1.3:1 Weigh 0.2kg Temperature range operation -20C to +60C storage -40C to +70C Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 27 of 50 4.2.4.5. Low Noise Amplifier (11-007402) The 30dB gain low noise amplifier used is a double stage solid-state low-noise amplifier. Class A circuitry is used in the unit to ensure excellent linearity over a very wide dynamic range. The two active devices are very moderately rated to provide a long trouble-free working life. There are no adjustments on this amplifier, and in the unlikely event of failure then the entire amplifier should be replaced. The amplifier features a dedicated, in-built alarm monitoring system which gives a TTL open collector type switched signal on alarm, this is then integrated using a built-in relay to give a volt-free contact for summation into the main alarm system. 11-007402 Specification PARAMETER SPECIFICATION Frequency range 380-500MHz Bandwidth <140MHz Gain 30-32dB 1dB Compression point +22dBm (typical) 3rd order intercept +34-35dBm (typical) Input/Output return loss >20dB Noise figure <1.3dB Connectors SMA female Supply 300-330mA @ 24V DC Temperature range operational

-20C to +60C storage -40C to +70C LNA D Connector Pin-out details Signal Connector pin 1 2 3 4 5 6 7 8 9

(Iridite NCP finish) with SMA connectors for the RF input/output and a 9way D-type connector for DC and alarm outputs. 11-007901 Specifications PARAMETER SPECIFICATION Frequency range: 380-470MHz Small signal gain: 37.5dB Gain flatness: 0.5dB Gain vs. temperature: 1.5dB Temperature range:

operational:

storage:

-20C to +60C

-40C to +70C Input/output return loss: 18dB Maximum output power: 30.4dBm (@ 1dB comp. point) OIP3: 43dBm Supply voltage: 10-15V DC Current consumption: 780mA (typical) Noise Figure: <1.75dB LNA D Connector Pin-out details Signal Connector pin 1 2 3 4 5 6 7 8 9

+ve input (10-24V) GND Alarm relay O/P bad Alarm relay common Alarm relay good No connection TTL voltage set TTL alarm/0V (good) O/C good/0V bad Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 29 of 50 4.2.4.7. Low Power Amplifier (1W) (12-021801) The low power amplifier used is a 1 stage balanced configuration, solid-state amplifier. Class A circuitry is used in the unit to ensure excellent linearity over a very wide dynamic range. The three active devices are very moderately rated to provide a long trouble-free working life. Its housing is an aluminium case (Iridite NCP finish) with SMA connectors for the RF input/output and a D-Type connector for the power supply and the Current Fault Alarm Function. There are no adjustments on this amplifier, and in the unlikely event of failure then the entire amplifier should be replaced. 12-021801 Specification PARAMETER SPECIFICATION Temperature -20 to +70 C Frequency Range 380 - 500 MHz Small Signal Gain 15.5 +/- 0.5 dB Gain Flatness 0.7 dB p-p Max

Gain vs. Temperature 0.7 dB Max In RL 20 dB Min Out RL 20 dB Min Output Power @ 1dB Compression Point 30.5 dBm Min Output 3rd Order IP 41.5 dBm Min Temperature range:

Noise Figure 6 dB Max DC Supply Voltage 10-15 Vdc DC Supply Current 540 mA Max operational:

storage:

Weight: <0.5 kg

-10C to +60C

-20C to +70C Size: 110.5 x 66mm x 24.6mm Low Power Amplifier (12-021801) 9-Way Connector Pin-outs Connector pin 1 2 3 4 5 6 7 8 9 Signal

+ve input (10-24V) GND Alarm relay O/P bad Alarm relay common Alarm relay good No connection TTL voltage set TTL alarm/0V (good) O/C good/0V bad 9-Way Pin-Out Graphical Representation 1 2 3 4 5 6 7 8 9 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 30 of 50 4.2.4.8. Low Power Amplifier (2W) (12-021802) The low power amplifier used is a 1 stage balanced configuration, solid-state amplifier. Class A circuitry is used in the unit to ensure excellent linearity over a very wide dynamic range. The three active devices are very moderately rated to provide a long trouble-free working life. Its housing is an aluminium case (Iridite NCP finish) with SMA connectors for the RF input/output and a D-Type connector for the power supply and the Current Fault Alarm Function. There are no adjustments on this amplifier, and in the unlikely event of failure then the entire amplifier should be replaced. 12-021802 Specification PARAMETER SPECIFICATION Temperature -20 to +70 C Frequency Range 380 - 500 MHz Small Signal Gain 15.5 +/- 0.5 dB Gain Flatness 0.7 dB p-p Max

Gain vs. Temperature 0.7 dB Max In RL 20 dB Min Out RL 20 dB Min Output Power @ 1dB Compression Point 33 dBm Min Output 3rd Order IP 46 dBm Min Temperature range Noise Figure 6 dB Max DC Supply Voltage 10-15 Vdc DC Supply Current 850 mA Max operational

-20C to +70C storage -40C to +100C Weight <0.5 kg Size 110.5 x 66mm x 24.6mm Low Power Amplifier (12-021802) 9-Way Connector Pin-outs Connector pin 1 2 3 4 5 6 7 8 9 Signal

+ve input (10-24V) GND Alarm relay O/P bad Alarm relay common Alarm relay good No connection TTL voltage set TTL alarm/0V (good) O/C good/0V bad 9-Way Pin-Out Graphical Representation 1 2 3 4 5 6 7 8 9 Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 31 of 50 4.2.4.9. DC-DC Converter 24V -12V (13-003011) The DC/DC converter fitted is an AFL assembled, high power PCB unit with an 8 amp at 12V output capability. The circuit is basically an O.E.M semiconductor regulator (one side of which has a heatsink mounting plate, usually bolted to the casing of a Cell Enhancer) and smoothing components built onto a printed circuit board with screw block terminations. In event of failure this unit should not be repaired, only replaced. 13-003011 Specification PARAMETER SPECIFICATION Input Voltage range: 18-28V DC Output voltage: 12V0.5V Max. current load: 8.0Amps Temperature range:

operation:

storage:

-10C to +60C

-20C to +70C Size(PCB): 190 x 63mm Weight (Loaded PCB): 291gms 4.2.4.10. Mains Filter (8 Amp) (13-003301) The 8A Mains Filter Assembly (13-003301) has been designed to remove mains-borne interference caused by external electrical radiation. Many filters exist which partially satisfy the criteria needed for cell enhancer power supplies (the main criteria being high continuous current) but a more cost efficient solution was realized using AFLs own manufacturing capability. 13-003301 Specification PARAMETER SPECIFICATION Maximum surge current: 6.5kA (8/20) Maximum leakage current: <0.3mA (@ working voltage Maximum continuous current: 8A Maximum continuous voltage: 253V Working voltage: 230V (nominal) Impulse energy absorption: 420J Ambient temperature limits:

-25C to +85C Humidity: 5-95% RHNC Case material: ABS plastic (IP50 rated) Maximum attenuation: 70dB (common mode 50-60Hz) Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 32 of 50 4.2.4.11. Downlink AGC Components AGC Detector /Amplifier (17-001117) AGC Attenuator (17-001201) The Remote Site Uplink/Downlink Tray (60-212802) Downlink path is fitted with an Automatic Gain Control (AGC) system. The AGC system consists of two units, a detector/amplifier (part No. 17-

001117) and an attenuator (part No. 17-001201). The detector/amplifier unit is inserted in the RF path on the output of the power amplifier, and the attenuator is situated in the RF before 1st stage of amplification. Normally the attenuator is at minimum attenuation. The detector/amplifier unit monitors the RF level being delivered by the power amplifier, and when a certain threshold is reached it begins to increase the value of the attenuator to limit the RF output to the (factory set) threshold. Therefore overloading of the power amplifier is avoided. The factory set threshold is 1dB below the amplifier 1dB compression point. Adjustment of this AGC threshold level is possible to reduce the maximum power; a 10dB range is mostly achieved. It is not recommended under any circumstances to adjust the AGC threshold to a level greater than the 1dB compression point as system degradation and signal distortion will occur. The detector comprises of a 50 transmission line with a resistive tap which samples a small portion of the mainline power. The sampled signal is amplified and fed to a conventional half wave diode rectifier, the output of which is a DC voltage proportional to the RF input signal. This DC voltage is passed via an inverting DC amplifier with integrating characteristics, to the output, which drives the attenuation control line of the corresponding AGC attenuator. This unit is fitted at some earlier point in the RF circuit. For small signals, below AGC onset, the output control line will be close to 12V and the AGC attenuator will have minimum attenuation. As the signal level increases the control line voltage will fall, increasing the attenuator value and keeping the system output level at a constant value. The AGC onset level is adjusted by the choice of sampler resistor R1 and by the setting of potentiometer VR1. The attenuator comprises a 50 P.I.N diode, voltage-variable attenuator with a range of 3 to 30dB. The attenuation is controlled by a DC voltage which is derived from the associated AGC detector unit. Technical Specifications PARAMETER SPECIFICATION Frequency range up to 1000MHz Attenuation range 3 to 30dB Attenuation steps continuously variable VSWR better than 1.2:1 RF Connectors SMA female Attenuator 1W Detector/amp >30W (or as required) operation -10C to +60C storage -20C to +70C attenuator pcb 50 x 42 x 21mm detector/amp pcb 54 x 42 x 21mm attenuator 90gm detector/amp 100gm Power Handling Temperature range Size Weight Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 33 of 50 4.2.4.12. Uplink AGC Components AGC Logarithmic Detector /Amplifier (17-001109) AGC Attenuator (17-001201) The Remote Site Uplink/Downlink Tray (60-212802) Uplink path is fitted with a wide dynamic range Automatic Gain Control (AGC) system. This is fitted in the Uplink path to avoid overloading the amplifiers (with the associated performance degradation) should a mobile be operated very close to the unit. The AFL wide dynamic range Automatic Gain Control system consists of two units, a logarithmic detector/amplifier (17-001109) and an attenuator (17-001201). The logarithmic detector/amplifier unit is inserted in the RF path on the output of the power amplifier, and the attenuator is situated in the RF path between the 1st and 2nd stages of amplification. Normally the attenuator is at minimum attenuation. The detector/amplifier unit monitors the RF level being delivered by the power amplifier, and when a certain threshold is reached it begins to increase the value of the attenuator to limit the RF output to the (factory set) threshold. Therefore overloading of the power amplifier is avoided. The factory set threshold is 1dB below the Enhancer 1dB compression point. Some adjustment of this AGC threshold level is possible; a 10dB range is mostly achieved. It is not recommended under any circumstances to adjust the AGC threshold to a level greater than the 1dB compression point as system degradation will occur. The detector comprises of a 50 transmission line with a resistive tap which samples a small portion of the mainline power. The sampled signal is amplified and fed to a conventional half wave diode rectifier, the output of which is a DC voltage proportional to the RF input signal. This DC voltage is passed via an inverting DC amplifier with integrating characteristics, to the output, which drives the attenuation control line of the corresponding AGC attenuator. This unit is fitted at some earlier point in the RF circuit. For small signals, below AGC onset, the output control line will be close to 12V and the AGC attenuator will have minimum attenuation. As the signal level increases the control line voltage will fall, increasing the attenuator value and keeping the system output level at a constant value. The AGC onset level is adjusted by the choice of sampler resistor R1 and by the setting of potentiometer VR1, (factory set at the time of system test) do not adjust unless able to monitor subsequent RF levels. The attenuator comprises a 50 P.I.N diode, voltage-variable attenuator with a range of 3 to 30dB. The attenuation is controlled by a DC voltage which is derived from the associated AGC detector unit. Wide Dynamic Range AGC Specification PARAMETER SPECIFICATION Frequency Range up to 1000MHz Attenuation Range 3 to 30dB Attenuation Steps continuously variable VSWR better than 1.2:1 RF Connectors SMA female attenuator 1W detector/amp >30W (or as required) operation -10C to +60C storage -20C to +70C attenuator pcb 50 x 42 x 21mm detector/amp pcb 54 x 42 x 21mm attenuator 90gm detector/amp 100gm Power Handling Temperature Range Size Weight Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 34 of 50 4.2.4.13. 12V Relay Board (20-001601) The General Purpose Relay Board allows the inversion of signals and the isolation of circuits. It is equipped with two dual pole change-over relays with completely isolated wiring, accessed via screw terminals. Both relays are provided with polarity protection diodes and diodes for suppressing the transients caused by "flywheel effect" which can destroy switching transistors or induce spikes on neighbouring circuits. Its common use is to amalgamate all the alarm signals into one, volts-free relay contact pair for the main alarm system. 20-001601 Specification PARAMETER SPECIFICATION Operating voltage 8 to 30V (floating earth) Alarm threshold Vcc - 1.20 volt +15%

Alarm output relay contacts:

Max. switch current 1.0Amp Max. switch volts 120Vdc/60VA Max. switch power 24W/60VA Min. switch load 10.0A/10.0mV Relay isolation 1.5kV Mechanical life >2x107 operations Relay approval BT type 56 Temperature range Connector details Screw terminals

-10C to +60C storage -20C to +70C operational 4.2.4.14. 24V Relay Board (20-001602) The General Purpose 24V Relay Board (20-001602) allows the inversion of signals and the isolation of circuits. It is equipped with two dual pole change-over relays RL1 and RL2, with completely isolated wiring, accessed via screw terminals. Both relays are provided with polarity protection diodes and diodes for suppressing the transients caused by "flywheel effect" which can destroy switching transistors or induce spikes on neighbouring circuits. Its common use is to amalgamate all the alarm signals into one, volts-free relay contact pair for the main alarm system. 20-001602 Specification PARAMETER SPECIFICATION Operating voltage 8 to 30V (floating earth) Alarm Threshold Vcc - 1.20 volt +15%

Alarm output relay contacts:

-10C to +60C storage -20C to +70C operational Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 35 of 50 4.2.4.15. Fibre Optic Transmitter (2.7GHz) (20-005401) The transmitter modulates the RF signal on to a laser, which is then transmitted over a fibre optic cable to a receiver. The laser current is monitored and compensated for constant optical out put power against temperature variation and aging. Laser over-current alarm function is provided as LED output as well as open collect and voltage-free relay contacts on 9 way D-type connector. 20-005401 specification PARAMETER SPECIFICATION Frequency Range (RF path) 70 - 3000 MHz Frequency Range (Data path) 20 35 MHz Available Link Gain (RF Path) 18 dB Link Gain ( DATA Path) 0 dB Gain Flatness (entire frequency range) 1.5 dB p-p

Gain vs. Temperature -20 to 70 C 3.5 dB Gain adjustment range ( RF Path ) 30 dB In/Out Return Loss (RF path) 10 dB Min Output IP3 @ max gain * 37 dBm In/Output IP3 @ 0dB Gain * 33 dBm RF impedance 50 Ohm Noise Figure @ 0dB gain (400MHz) 36 dB Optical Transmit Power 2.70.3 dBm Optical return loss >50 dB Received Power Alarm Threshold -10 dBm(optic) Optical wavelength 1310 nm DC Supply Voltage 10-12 Vdc DC Supply Current 120 mA Operating Temperature -20 to 70 C Storage Temperature -30 to 85 C RF Connector type SMA Fibre optic connector type FC/APC Fibre Optic Transmitter (20-005401) D Type Female Connector Pinouts Pin No. 1 2 3 4 5 6 7 8 9 Signal Description

+10-12V DC Power 0V DC, Power Ground 0V DC, Power Ground No Connection No Connection TTL Alarm, (0V=good, open coll.= fail) Relay Alarm Contact (N.C) Relay Alarm Contact (Common) Relay Alarm Contact (N.O) Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 36 of 50 4.2.4.16. Fibre Optic Receiver (2.7GHz) (20-005501) The receiver demodulates RF signals from the laser with a typical gain of 18dB and with 30dB adjustability in the RF domain. The received optical power is monitored for alarm function in case of fibre damage. 20-005501 Specification PARAMETER SPECIFICATION Frequency Range (RF path) 70 - 3000 MHz Frequency Range (Data path) 20 35 MHz Available Link Gain (RF Path) 18 dB Link Gain ( DATA Path) 0 dB Gain Flatness (entire frequency range) 1.5 dB p-p

Gain vs. Temperature -20 to 70 C 3.5 dB Gain adjustment range ( RF Path ) 30 dB In/Out Return Loss (RF path) 10 dB Min Output IP3 @ max Gain 37 dBm In/Output IP3 @ 0dB Gain 33 dBm RF impedance 50 Ohm Noise Figure @ 0dB gain (400MHz) 36 dB Optical Transmit Power 2.70.3 dBm Optical return loss >50 dB Received Power Alarm Threshold -10 dBm(optic) Optical wavelength 1310 nm DC Supply Voltage 10-12 Vdc DC Supply Current 350 mA Operating Temperature -20 to 70 C Storage Temperature -30 to 85 C RF Connector type SMA Fibre optic connector type FC/APC Fibre Optic Receiver (20-005501) D Type Female Connector Pinouts Pin No. 1 2 3 4 5 6 7 8 9 Signal Description

+10-12V DC Power 0V DC, Power Ground 0V DC, Power Ground No Connection No Connection TTL Alarm, (0V=good, open coll.= fail) Relay Alarm Contact (N.C) Relay Alarm Contact (Common) Relay Alarm Contact (N.O) Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 37 of 50 4.2.4.17. 12V Relay Assembly (80-008901) The General Purpose Relay Board allows the inversion of signals and the isolation of circuits. It is equipped with a single dual pole change-over relay RL1, with completely isolated wiring, accessed via a 15 way in-line connector. The relay is provided with polarity protection diodes and diodes for suppressing the transients caused by "flywheel effect" which can destroy switching transistors or induce spikes on neighbouring circuits. Its common use is to amalgamate all the alarm signals into one, volts-free relay contact pair for the main alarm system. 80-008901 Specification PARAMETER SPECIFICATION Operating voltage 8 to 30V (floating earth) Alarm threshold Vcc - 1.20 volt +15%

-10C to +60C storage -20C to +70C operational 4.2.4.18. 60A Dual Diode (94-100004) The purpose of these dual diode assemblies is to allow two DC voltage sources to be combined, so that the main DC rail within the equipment can be sourced from either a mains driven PSU, or externally through an XLR connector or from dual mains driven PSUs . They are very heavy-duty diodes and they prevent any reverse current from flowing back to their source or the alternative supply rail. Combining diodes such as these will also be used if the equipment is to be powered from external back-up batteries. 4.2.4.19. PSU 600W (24V 23A) (96-300067) The power supply unit is a switched-mode type capable of supplying 24V DC at 23.0Amps continuously. Equipment of this type typically requires approximately 10.0 Amps at 24V DC, so the PSU will be used conservatively ensuring a long operational lifetime. No routine maintenance of the PSU is required. If a fault is suspected, then the output voltage from the power supply may be measured on its output terminals. This is typically set to 24.5V using the multi-turn potentiometer mounted close to the DC output studs on the PSU PCB. All the PSUs used in AFL Cell Enhancers are capable of operation from either 110 or 220V nominal AC supplies. The line voltage is sensed automatically, so no adjustment or link setting is needed by the operator. 96-300067 Specification AC Input Supply Voltages:

110 or 220V nominal 90 to 132 or 180 to 264V (absolute limits) Frequency: 47 to 63Hz Voltage:

DC Output Supply:

24V DC (nominal) 20 to 28V (absolute limits) Maximum current: 23A Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 38 of 50 5. INSTALLATION 5.1 General Remarks When this equipment is initially commissioned, please use the equipment set-up record sheet in Appendix B. This will help both the installation personnel and AFL should these figures be needed for future reference or diagnosis. The equipment racks must be located on a flat, level surface that is made from a material suitable for bearing the weight of the rack assembly. If the installer is in any doubt about the suitability of a site it is recommended that he consult with an appropriately qualified Structural Engineer. It is important in determining the location of the rack within the room that space is allowed for access to the front and rear of the equipment. To enable maintenance to be carried out, the doors must be able to fully open. The location must be served with a duct to allow the entry of cables into the rack. 5.2 Electrical Connections It is recommended that the electrical mains connection is made by a qualified electrician, who must be satisfied that the supply will be the correct voltage and of sufficient capacity. All electrical and RF connections should be completed and checked prior to power being applied for the first time. Ensure that connections are kept clean and are fully tightened. 5.3 RF Connections Care must be taken to ensure that the correct connections are made with particular attention made to the base station TX/RX ports. In the event that the base transmitter is connected to the RX output of the equipment, damage to the equipment will be done if the base station transmitter is then keyed. Ensure that connections are kept clean and are fully tightened. 5.4 Optical Connections The optical input and output ports will be located on the appropriate shelf as shown in the system drawings. The ports are supplied with a green plastic cover, which must be removed prior to the connection of the fibre cable. Ensure that transmitter and receiver fibre cable are identified to prevent misconnection. At the master site, the fibre transmitters are in the downlink path with the receivers in the uplink. At the remote sites the fibre transmitters are in the uplink with the receivers in the downlink. In the master site 60-212701 both of the RF paths have provision for a second path, the downlink RF path being split into two and fed to two fibre optic transmitters providing two optical outputs and the uplink path having two optical inputs each to its own fibre optic receiver, the resulting RF outputs being combined to produce a single RF output path. The two downlink optical paths are identical so either may be used, the same applies to the uplink, however the optical ports not in use must be capped with their green plastic covers. Always ensure that connections are kept clean and are fully tightened. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 39 of 50 5.5 Commissioning Once all connections are made the equipment is ready for commissioning. To commission the system the test equipment detailed in Section 6.2. will be required. Using the system diagrams and the end-to-end test specification (supplied with the equipment), the equipment should be tested to ensure correct operation. Typical RF levels that are not listed in the end-to-end specification, such as input levels to the fibre transmitters are detailed in the maintenance section of this manual. On initial power up the system alarm indicators on the front panels of the equipment should be checked. A red LED illuminated indicates a fault in that particular tray that must be investigated before proceeding with the commissioning. A green LED on each shelf illuminates, to indicate that the power supply is connected to the shelf In the event that any part of the system does not function correctly as expected, check all connections to ensure that they are to the correct port, that the interconnecting cables are not faulty and that they are tightened. The majority of commissioning difficulties arise from problems with the interconnecting cables and connectors. 5.6 Antenna Installation & Gain Calculations A B C D E F The equipment requires two antennas, one a highly directional Yagi or similar directed towards the donor cell base station, and one a leaky feeder, omni-directional antenna or Yagi to cover the area in which the mobiles are to be served. The maximum gain at which the equipment can be set is limited by the isolation that can be achieved between these two antennas. Therefore when the antennas have been installed, inject a signal (at a known power level) into one of them and measure the signal level received by the other antenna on a spectrum analyser. The isolation can then be calculated as the difference between these two figures. The gain in each path of the equipment should be set at least 10 dB below this figure, using attenuators as described below in paragraph 5. Also measure the received signal from the donor cell at the input to the equipment (base port). The gain of the equipment downlink path should be set such the donor site will not overload the equipment amplifiers. It is recommended that the input level should be less than -50dBm at the input of the equipment (Base Port). (This figure is assuming maximum gain, and may be increased by the value of the attenuator fitted in the downlink path.) Ensure that the mobile facing antenna has at least 70dB isolation from the nearest mobile.

(This is usually easily achieved when using a leaky feeder.) The equipment gain is set by setting the variable switched attenuators in each path (uplink and downlink) refer to the photographs and layout drawings for the exact attenuator locations). Note that the uplink (mobile to base) and downlink (base to mobile) path gains are set independently. This allows the paths to have different gains if required to set the correct output power levels. It is recommended that the gains are set such that the Downlink channel output levels from the equipment are typically +30dBm per channel

(Input level + Gain = Output level). Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 40 of 50 5.7 Antenna Isolation Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 41 of 50 6. MAINTENANCE 6.1. Fault Finding 6.1.1. Quick Fault Checklist All tunnel equipment is individually tested to specification prior to despatch. Failure of this type of equipment is not common. Experience has shown that a large number of fault conditions relating to tunnel installations result from simple causes often occurring as result of transportation, unpacking and installation. Below are listed some common problems which have resulted in poor performance or an indicated non-functioning of the equipment. Input signals not present due to faults in the aerial and feeder system. Internal connectors becoming loose due to transport vibration. Mains power not connected or not switched on. External connectors not fitted or incorrectly fitted. Wiring becoming detached as a result of heavy handling. Base transmissions not present due to fault at the base station. Modems fitted with incorrect software configuration. Changes to channel frequencies and inhibiting channels. Hand held radio equipment not set to repeater channels. Hand held radio equipment not set to correct base station. 6.1.2 Fault Isolation In the event that the performance of the system is suspect, a methodical and logical approach to the problem will reveal the cause of the difficulty. The System consists of modules fitted in enclosed shelves within a rack mounted, environmentally protected enclosure. Transmissions from the main base stations are passed though the system to the mobile radio equipment; this could be a handheld radio or a transceiver in a vehicle. This path is referred to as the downlink. The return signal path from the mobile radio equipment to the base station is referred to as the uplink. The first operation is to check the alarms of each of the active units and determine that the power supplies to the equipment are connected and active. This can be achieved remotely (via CEMS, the RS232 Coverage Enhancement Management System, if fitted), or locally with the front panel LEDs. The green LED on the front panel should be illuminated, while the red alarm indicator should be off. If an Alarm is on, then that individual shelf must be isolated and individually tested against the original test specification. The individual amplifier units within the shelf have a green LED showing through a hole in their piggy-

back alarm board, which is illuminated if the unit is working correctly. If an amplifier is suspect, check the DC power supply to the unit. If no other fault is apparent use a spectrum analyser to measure the incoming signal level at the input and then after reconnecting the amplifier input, measure the output level. Consult with the system diagram to determine the expected gain and compare result. In the event that there are no alarms on and all units appear to be functioning it will be necessary to test the system in a systematic manner to confirm correct operation. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 42 of 50 6.1.3 Downlink Confirm that there is a signal at the expected frequency and strength from the base station. If this is not present then the fault may lay outside the system. To confirm this, inject a downlink frequency signal from a known source at the master site BTS input and check for output at the remote site feeder output. If a signal is not received at the output it will be necessary to follow the downlink path through the system to find a point at which the signal is lost. The expected downlink output for the given input can be found in the end-to-end test specification. 6.1.4 Uplink Testing the uplink involves a similar procedure to the downlink except that the frequencies used are those transmitted by the mobile equipment. 6.1.5 Fibre Optics The Fibre Optic transmitters and receivers both have two LED status indicators, one on each module showing DC power and the other indicating Laser On for the transmitter, and Carrier Being Received for the receiver. Assuming that all of the indicators are illuminated, it will be necessary to check the RF inputs and outputs to the fibre optic units. Typically the input to transmitter units will be at a level of between -30 and -15 dBm. The RF gain of a pair (TX to RX) units is factory set to give a 0dB gain, but this is with a short, low loss fibre. In determining the performance of the link, the insertion loss of the fibre and any power splitters fitted must be considered. A general rule of thumb figure would be around 0.5 - 1.5dB loss per Kilometre. 6.1.7 Checking service Following the repair of any part of the system it is recommended that a full end-to-end test is carried out in accordance with the test specification and that the coverage is checked by survey. It is important to bear in mind that the system includes a radiating cable network and base stations that may be faulty or may have been damaged. 6.1.8 Fault repair Once a faulty component has been identified, a decision must be made on the appropriate course to carry out a repair. A competent engineer can quickly remedy typical faults such as faulty connections or cables. The exceptions to this are cable assemblies connecting bandpass filter assemblies that are manufactured to critical lengths to maintain a 50-ohm system. Care should be taken when replacing cables or connectors to ensure that items are of the correct specification. The repair of component modules such as amplifiers and bandpass filters will not usually be possible in the field, as they frequently require specialist knowledge and test equipment to ensure correct operation. It is recommended that items of this type are replaced with a spare unit and the faulty unit returned to AFL for repair. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 43 of 50 6.1.9 Service Support Advice and assistance with maintaining and servicing this system are available by contacting Aerial Facilities Ltd., see section 2.7. NOTE Individual modules are not intended to be repaired on site and attempts at repair will invalidate active warranties. Company policy is that individual modules should be repaired by replacement. Aerial Facilities Ltd maintains a high level of stock of most modules which can usually be despatched at short notice to support this policy. 6.2 Tools & Test Equipment The minimum tools and test equipment needed to successfully service this AFL product are as follows:-

Spectrum analyser Signal Generator Attenuator Test Antenna Optical Power Meter Digital multi-meter Test cable x 2 Test cable x 2 Hand tools 100kHz to 2GHz (Dynamic range = 90dB). 30MHz to 2GHz (-120dBm to 0dBm o/p level). 20dB, 10W, DC-2GHz, (N male N female). Yagi or dipole for operating frequency. 1300 1560nM (-40 - +10dB) Universal Volt-Ohm-Amp meter. N male N male, 2M long RG214. SMA male N male, 1m long RG223. Philips #1&2 tip screwdriver. 3mm flat bladed screwdriver. SMA spanner and torque setter. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 44 of 50 6.3 Care of Modules 6.3.1 General Comments Many of the active modules contain semiconductor devices utilising MOS technology, which can be damaged by electrostatic discharge. Correct handling of such modules is mandatory to ensure their long-term reliability. To prevent damage to a module, it must be withdrawn/inserted with care. The module may have connectors on its underside, which might not be visible to the service operative. 6.3.2 Module Removal (LNAs, general procedure):

The following general instructions should be followed to remove a module:

Remove power to the unit 1 Remove all visible connectors (RF, DC & alarm) 2 Release module retaining screws. 3 4 Slowly but firmly, pull the module straight out of its position. Take care not to twist/turn the module during withdrawal. (When the module is loose, care may be needed, as there may be concealed connections underneath). 1 2 3 4 1) 2) 6.3.3 Module Replacement (general):

Carefully align the module into its location then slowly push the module directly straight into its position, taking care not to twist/turn it during insertion. Reconnect all connectors, RF, alarm, power etc., (concealed connectors may have to be connected first). Replace retaining screws (if any). Double-check all connections before applying power. 6.3.4 Power Amplifiers Remove power to the unit. (Switch off at mains/battery, or remove DC in connector) Remove alarm wires from alarm screw terminal block or disconnect multi-way alarm connector. 3) Carefully disconnect the RF input and output coaxial connectors (usually SMA) If alarm board removal is not required, go to step 5. 4) 5) There is (usually) a plate attached to the alarm board which fixes it to the amplifier, remove its retaining screws and the alarm board can be withdrawn from the amplifier in its entirety. On certain types of amplifier the alarm board is not mounted on a dedicated mounting plate; in this case it will have to firstly be removed by unscrewing it from the mounting pillars, in most cases, the pillars will not have to be removed before lifting the amplifier. If the amplifier to be removed has a heatsink attached, there may be several different ways it can have been assembled. The most commonly used method, is screws through the front of the heatsink to threaded screw holes (or nuts and bolts), into the amplifier within the main case. If the heatsink is mounted on the rear of the main case (e.g., against a wall in the case of wall mounted enclosures), then the fixing method for the heatsink will be from within the case, (otherwise the enclosure would have to be removed from the wall in order to remove the heatsink). Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 45 of 50 When the heatsink has been removed, the amplifier may be unscrewed from the main casing by its four corner fixings and gently withdrawn. Fitting a new power amplifier module will be the exact reverse of the above. Note: Do not forget to apply fresh heatsink compound to the heatsink/main case joint and also between the amplifier and the main case. 6.3.5 Low Power Amplifier Replacement Disconnect the mains power supply and disconnect the 24V dc supply connector for the LPA. Disconnect the RF input and output cables from the LPA. Disconnect the alarm connector. Remove the alarm monitoring wires from (D type connector) pins 9 and 10. Remove the LPA module by removing the four retaining screws, replace with a new LPA module and secure it with the screws. Connect the RF cables to the LPA input and output connectors. Reconnect the wires to the alarm board connector pins 9 and 10. Reconnect the DC supply connector and turn the mains switch on. Note: Tighten SMA connectors using only a dedicated SMA torque spanner. If SMA connectors are over-tightened, irreparable damage will occur. Do not use adjustable pliers to loosen/tighten SMA connectors. Also take care not to drop or knock the module as this can damage (or misalign in the case of tuned passive modules) sensitive internal components. Always store the modules in an environmentally friendly location 6.3.6 Module Transportation:

To maintain the operation, performance and reliability of any module it must be stored and transported correctly. Any module not installed in a whole system must be kept in an anti-static bag or container. These bags or containers are normally identified by being pink or black, and are often marked with an ESD label. Any module sent back to AFL for investigation/repair must be so protected. Please contact AFLs quality department before returning a module, see section 2.7. Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 46 of 50 APPENDIX A A.1. Glossary of Terms used in this document Repeater or Cell Enhancer Band Selective Repeater Channel Selective Repeater A Radio Frequency (RF) amplifier which can simultaneously amplify and re-broadcast Mobile Station (MS) and Base Transceiver Station (BTS) signals. A Cell Enhancer designed for operation on a range of channels within a specified frequency band. A Cell Enhancer, designed for operation on specified channel(s) within a specified frequency band. Channel frequencies may be factory set or on-site programmable. AC AGC BBU BTS CEMS C/NR DC Alternating Current Automatic Gain Control Battery Backup Unit Base Transceiver Station Coverage Enhanced Management System Carrier-to-Noise Ratio Direct Current Downlink (D/L) RF signals TX from the BTS to the Master Site FO GND ID LED LNA LPA MOU M.S. MTBF N/A N/C OFR OIP3 P1dB PA RF RSA RX S/N TX Fibre Optic Ground Identification Number Light Emitting Diode Low Noise Amplifier Low Power Amplifier Master Optical Unit Mobile Station Mean Time Between Failures Not Applicable No Connection On Frequency Repeater Output Third Order Intercept Point 1dB Compression Point Power Amplifier Radio Frequency Receiver/Splitter Amplifier Receiver Serial Number Transmitter Uplink (U/L) RF signals transmitted from the MS to the BTS VSWR WDM Voltage Standing Wave Ratio Wave division multiplex Fibre Optic Master and Remote Site User Handbook Document Number: 60-212701HBK - Issue No. 1 Page 47 of 50 A.2. Key to Drawing Symbols used in this document A B C D E T P E C X E D R A D N A T S

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. I I I D T L S E T L C A F L A R E A Y B I I N O T C E J O R P E L G N A D R H T I I R O T A L L C S O L A C O L R O T A L L I C S O L A C O L R O T C E N N O C C P A C F

S I I I S R E H T O Y B N G S E D S H T F O E S U R O N O T C U D O R P E R I

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		frequency	equipment class	purpose
1	2008-03-03	505.4 ~ 507.96	TNB - Licensed Non-Broadcast Station Transmitter	Original Equipment

Application Forms

app s	Applicant Information
1	Effective	2008-03-03
1	Applicant's complete, legal business name	Axell Wireless
1	FCC Registration Number (FRN)	0007840820
1	Physical Address	The Cobham Centre
1		Marlow, Bucks, N/A SL7 1TF
1		United Kingdom

app s	TCB Information
1	TCB Application Email Address	p******@trac-trl.com
1	TCB Scope	B2: General Mobile Radio And Broadcast Services equipment in the following 47 CFR Parts 22 (non-cellular) 73, 74, 90, 95, 97, & 101 (all below 3 GHz)

app s	FCC ID
1	Grantee Code	NEO
1	Equipment Product Code	60-2128SERIES

app s	Person at the applicant's address to receive grant or for contact
1	Name	B** B**
1	Title	Operations Support Director
1	Telephone Number	+44(0********
1	Fax Number	+44(0********
1	E-mail	b******@cobhamwireless.com

app s	Technical Contact
		n/a

app s	Non Technical Contact
		n/a

app s	Confidentiality (long or short term)
1	Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?:	Yes
1	Long-Term Confidentiality Does this application include a request for confidentiality for any portion(s) of the data contained in this application pursuant to 47 CFR § 0.459 of the Commission Rules?:	No
	if no date is supplied, the release date will be set to 45 calendar days past the date of grant.

app s	Cognitive Radio & Software Defined Radio, Class, etc
1	Is this application for software defined/cognitive radio authorization?	No
1	Equipment Class	TNB - Licensed Non-Broadcast Station Transmitter
1	Description of product as it is marketed: (NOTE: This text will appear below the equipment class on the grant)	Q116270 Cell Enhancer
1	Related OET KnowledgeDataBase Inquiry: Is there a KDB inquiry associated with this application?	No
1	Modular Equipment Type	Does not apply
1	Purpose / Application is for	Original Equipment
1	Composite Equipment: Is the equipment in this application a composite device subject to an additional equipment authorization?	No
1	Related Equipment: Is the equipment in this application part of a system that operates with, or is marketed with, another device that requires an equipment authorization?	No
1	Grant Comments	Booster, declared output power is per channel
1	Is there an equipment authorization waiver associated with this application?	No
1	If there is an equipment authorization waiver associated with this application, has the associated waiver been approved and all information uploaded?	No

app s	Test Firm Name and Contact Information
1	Firm Name	Element Materials Technology Warwick Ltd
1	Name	K**** W******
1	Telephone Number	00-44********
1	Fax Number	00-44********
1	E-mail	K******@element.com

Equipment Specifications
	Line	Rule Parts	Grant Notes	Lower Frequency	Upper Frequency	Power Output	Tolerance	Emission Designator	Microprocessor Number
1	1	9		501.35	503.15	1	Amp	F3E
1	2	9		505.4	507.96	0.001	Amp	F3E

some individual PII (Personally Identifiable Information) available on the public forms may be redacted, original source may include additional details