ADC Telecommunications DIS080AB Digivance® 800 MHz Indoor Coverage Solution User Manual 75130 CV

ADC Telecommunications Inc Digivance® 800 MHz Indoor Coverage Solution 75130 CV

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PreliminaryADCP-75-130Preliminary Issue 3CAugust 20061371998 Rev 1Digivance®Indoor Coverage Solution800 MHz Single- or Multi-Mode FiberSystem Installation and Operation Manual

ADCP-75-130 Preliminary Issue 3C August 2006 Digivance® Indoor Coverage Solution 800 MHz Single or Multi-Mode Fiber System Installation and Operation Manual 1371998 Rev 1

ADCP-75-130 • Issue 3C • August 2006 • Preface Page ii COPYRIGHT © 2006, ADC Telecommunications, Inc. All Rights Reserved REVISION HISTORY ISSUE DATE REASON FOR CHANGE Issue 1 03/2002 Original Issue 2 09/2002 Updated to include new IC and UL certification statements, revised panel-type antenna designs, and new troubleshooting charts. Issue 3 03/2004 Deleted all references to the LIU, inserted new references to the HPCP, added air quality specifications and warnings, and updated phone numbers and email addresses. Issue 3C 08/2006 Updated to include new specifications for the RF output signal level at the DRU. TRADEMARK INFORMATION ADC, Digivance, and FiberGuide are registered trademarks of ADC Telecommunications, Inc. LC is a trademark of Lucent Technologies Inc. Telcordia is a registered trademark of Telcordia Technologies, Inc. TORX is a registered trademark of Textron, Inc. DISCLAIMER OF LIABILITY Contents herein are current as of the date of publication. ADC reserves the right to change the contents without prior notice. In no event shall ADC be liable for any damages resulting from loss of data, loss of use, or loss of profits and ADC further disclaims any and all liability for indirect, incidental, special, consequential or other similar damages. This disclaimer of liability applies to all products, publications and services during and after the warranty period. This publication may be verified at any time by contacting ADC’s Technical Assistance Center at 1-800-366-3891, extension 73476 (in U.S.A. or Canada) or 1-952-917-3476 (outside U.S.A. and Canada), or by e-mail to wireless.tac@adc.com. ADC Telecommunications, Inc.P.O. Box 1101, Minneapolis, Minnesota 55440-1101In U.S.A. and Canada: 1-800-366-3891Outside U.S.A. and Canada: (952) 938-8080Fax: (952) 917-1717

ADCP-75-130 • Issue 3C • August 2006 • Preface Page iii © 2006, ADC Telecommunications, Inc. TABLE OF CONTENTS Content Page 1 SYSTEM FUNCTIONAL OVERVIEW .......................................................... 1 1.1 Basic System Components ......................................................... 1 1.2 Interface With BTS............................................................... 1 1.3 Interface With Cellular Phones ...................................................... 1 1.4 Digital Fiber Optic Transport ........................................................ 2 1.5 Capacity for Expansion and Extended Runs .............................................. 3 1.6 Power Requirements ............................................................. 3 1.7 Fault Detection and Alarm Reporting .................................................. 3 2 DIGITAL UNIT DESCRIPTION.............................................................. 3 2.1 Digital Host Unit Description........................................................ 3 2.2 Digital Remote Unit Description ..................................................... 7 2.3 Digital Expansion Unit Description................................................... 10 2.4 Terms and Definitions ........................................................... 13 2.5 Specifications................................................................. 13 3 INSTALLATION PLANNING AND SYSTEM DESIGN ............................................... 17 3.1 Base Station Interface Requirements ................................................. 17 3.2 Locating and Mounting Requirements ................................................ 19 3.3 Powering Requirements .......................................................... 20 3.4 Optical Options and Requirements................................................... 21 3.5 Coaxial Cable Requirements....................................................... 22 3.6 System Expansion Planning ....................................................... 23 3.7 DRU Antenna Options............................................................ 23 3.8 External Alarm System Reporting Requirements ......................................... 24 3.9 Maintenance Requirements ....................................................... 24 3.10 System Design Recommendations ................................................... 25 4 DIGITAL HOST UNIT INSTALLATION PROCEDURE............................................... 28 4.1 System Plan Review and Pre-Installation Cable Routing .................................... 28 4.2 Tools and Materials............................................................. 28 4.3 Unpacking and Inspection......................................................... 29 4.4 Mounting Procecure ............................................................ 29 4.5 Chassis Ground Connections ....................................................... 32 4.6 Coaxial Cable Connections ........................................................ 33 4.7 Modular Optical Transceiver Installation............................................... 34 4.8 Ports 1–6 Optical Connections...................................................... 35 4.9 DC Power Connections ........................................................... 37 4.10 External Alarm System Connections .................................................. 38 4.11 AC Power Connections ........................................................... 39 4.12 Create As-Built Drawing .......................................................... 40 5 SYSTEM OPERATION.................................................................. 41 5.1 Tools and Materials............................................................. 41 5.2 Turn-Up System and Verify Operation ................................................. 41 (continued)

ADCP-75-130 • Issue 3C • August 2006 • Preface Page iv © 2006, ADC Telecommunications, Inc. TABLE OF CONTENTS Content Page 5.3 RF Input and Output Signal Level Adjustment ........................................... 44 5.4 Test System Performance ........................................................ 45 6 SYSTEM MAINTENANCE PROCEDURES ..................................................... 47 6.1 Tools and Materials ............................................................ 47 6.2 Fault Detection and Alarm Reporting................................................. 47 6.3 Fault Isolation and Troubleshooting ................................................. 48 6.4 Test Procedures ............................................................... 53 6.5 DHU or DEU Fan Replacement Procedure.............................................. 57 6.6 DHU or DEU Moudular Optical Transceiver Replacement Procedure ............................ 59 6.7 DRU Modular Optical Transceiver Replacement Proceudre .................................. 61 7 GENERAL INFORMATION............................................................... 64 7.1 Warranty/Software ............................................................. 64 7.2 Software Service Agreement ...................................................... 64 7.3 Repair/Exchange Policy.......................................................... 64 7.4 Repair Charges ............................................................... 65 7.5 Replacement/Spare Products ...................................................... 65 7.6 Returned Material ............................................................. 65 7.7 Customer Information and Assistance ................................................ 66

ADCP-75-130 • Issue 3C • August 2006 • Preface Page v © 2006, ADC Telecommunications, Inc. ABOUT THIS GUIDE This installation and operation manual provides the following information: • An overview of the Digivance Indoor Coverage Solution (ICS) • A description of the basic system components including the Digital Host Unit (DHU), Digital Expansion Unit (DEU), and the Digital Remote Unit (DRU). • System requirements for planning the Digivance ICS installation. • Procedures for installing the DHU. • Procedures for operating and maintaining the Digivance ICS. • Product warranty, repair, return, and replacement information The procedures for installing the DEU and DRU are provided in other publications which are referenced in the Related Publications section and at appropriate points within this manual. RELATED PUBLICATIONS Listed below are related manuals and their publication numbers. Copies of these publications can be ordered by contacting the ADC Technical Assistance Center at 1-800-366-3891, extension 73476 (in U.S.A. or Canada) or 952-917-3476, (outside U.S.A. and Canada). Title/Description ADCP Number Digivance ICS Digital Expansion Unit Installation Instructions 75-111 Provides a description of the DEU and procedures for installation. Digivance ICS Digital Remote Unit Installation Instructions 75-112 Provides a description of the DRU and procedures for installation. Digivance ICS 800 and 1900 MHz High Power Conditioning Panel User Manual 75-175 Provides a description of the 800 and 1900 MHz High Power Conditioning Panel (HPCP) and procedures for installation. Digivance ICS Single Band Remote Interface Unit (800 and 1900 MHz Systems) User Manual 75-178 Provides a description of the RIU and procedures for installation.

ADCP-75-130 • Issue 3C • August 2006 • Preface Page vi © 2006, ADC Telecommunications, Inc. ADMONISHMENTS Important safety admonishments are used throughout this manual to warn of possible hazards to persons or equipment. An admonishment identifies a possible hazard and then explains what may happen if the hazard is not avoided. The admonishments — in the form of Dangers, Warnings, and Cautions — must be followed at all times. These warnings are flagged by use of the triangular alert icon (seen below), and are listed in descending order of severity of injury or damage and likelihood of occurrence. Danger: Danger is used to indicate the presence of a hazard that will cause severe personal injury, death, or substantial property damage if the hazard is not avoided. Warning: Warning is used to indicate the presence of a hazard that can cause severe personal injury, death, or substantial property damage if the hazard is not avoided. Caution: Caution is used to indicate the presence of a hazard that will or can cause minor personal injury or property damage if the hazard is not avoided. GENERAL SAFETY PRECAUTIONS The following general admonishments apply throughout the procedures in this manual. Warning: Wet conditions increase the potential for receiving an electrical shock when installing or using electrically-powered equipment. To prevent electrical shock, never install or use electrical equipment in a wet location or during a lightning storm. Warning: Do not install the DRU in marine, industrial, or Intrinsic Safety (IS) environments without an engineering review of the air quality including the presence of other constituent gasses and dusts. Contact ADC for application assistance if necessary. Warning: The DRU is powered by 48 VDC power which is supplied over customer-provided wiring. To prevent electrical shock when installing or modifying the DRU power wiring, disconnect the wiring at the power source before working with uninsulated wires or terminals. Danger: This equipment uses a Class 1 Laser according to FDA/CDRH rules. Laser radiation can seriously damage the retina of the eye. Do not look into the ends of any optical fiber. Do not look directly into the optical adapters of any digital unit or exposure to laser radiation may result. An optical power meter should be used to verify active fibers. A protective cap or hood MUST be immediately placed over any radiating adapter or optical fiber connector to avoid the potential of dangerous amounts of radiation exposure. This practice also prevents dirt particles from entering the adapter or connector Danger: Do not look into the ends of any optical fiber. Exposure to laser radiation may result. Do not assume laser power is turned-off or the fiber is disconnected at the other end. Danger: Always allow sufficient fiber length to permit routing without severe bends. Fibers may be permanently damaged if bent/curved to a radius of less than 2 inches (50 mm).

ADCP-75-130 • Issue 3C • August 2006 • Preface Page vii © 2006, ADC Telecommunications, Inc. STANDARDS CERTIFICATION FCC: This equipment complies with the applicable sections of Title 47 CFR Part 22. Caution: Modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. Part 15.5 General conditions of operation: a. Persons operating intentional or unintentional radiators shall not be deemed to have any vested or recognizable right to continue use of any given frequency by virtue of prior registration or certificate of equipment. b. Operation of an intentional, unintentional, or incidental radiator is subject to the conditions that no harmful interference is caused and that interference must be accepted that may be caused by the operation of an authorized radio station, by another intentional or unintentional radiator, by industrial, scientific and medical (ISM) equipment, or by an incidental operator. c. The operator of a radio frequency device shall be required to cease operating the device upon notification by a Commission representative that the device is causing harmful interference. Operation shall not resume until the condition causing the harmful interference has been corrected. UL/CUL: This equipment complies with UL and CUL 60950 Standard for Safety for Information Technology Equipment, Including Electrical Business Equipment. NEC/CEC: The DRU is suitable for use in environmental air space in accordance with Section 300-22(c) of the National Electrical Code, and Sections 2-128, 12-010(3), and 12-100 of the Canadian Electrical Code, Part 1, C22.1. FDA/CDRH: This equipment uses a Class 1 LASER according to FDA/CDRH Rules. This product conforms to all applicable standards of 21 CFR Part 1040. IC: This equipment complies with the applicable sections of RSS-131. The term “IC:” before the radio certification number only signifies that Industry Canada Technical Specifications were met. LIST OF ACRONYMS AND ABBREVIATIONS The acronyms and abbreviations used in this manual are detailed in the following list: A Amperes AC Alternating Current AGC Automatic Gain Control AMPS Advanced Mobile Phone Service BTS Base Transceiver Station CDMA Code Division Multiple Access CDRH Center for Devices and Radiological Health CEC Canadian Electrical Code CUL Underwriters’ Laboratories of Canada DAS Distributed Antenna System

ADCP-75-130 • Issue 3C • August 2006 • Preface Page viii © 2006, ADC Telecommunications, Inc. DC Direct Current DEU Digital Expansion Unit DHU Digital Host Unit DRU Digital Remote Unit EIA Electronic Industries Association ERP Effective Radiated Power ESD Electrostatic Discharge FCC Federal Communications Commission FDA Food and Drug Administration HPCP High Power Conditioning Panel ICS Indoor Coverage Solution MM Multi-Mode NEC National Electrical Code NOC Network Operations Center PWR Power RIU Remote Interface Unit RF Radio Frequency RSSI Received Signal Strength Indication RX Receive or Receiver SM Single-Mode TDMA Time Division Multiple Access TX Transmit or Transmitter UL Underwriters’ Laboratories UPS Uninterruptible Power Supply V Volts VAC Volts Alternating Current VDC Volts Direct Current WECO Western Electric Company

ADCP-75-130 • Issue 3C • August 2006 Page 1 © 2006, ADC Telecommunications, Inc. 1 SYSTEM FUNCTIONAL OVERVIEW The Digivance ICS is a digitally distributed antenna system that provides in-building coverage for cellular analog (AMPS) and digital (TDMA and CDMA) phone systems operating within the 800 MHz frequency bands. Large buildings typically interfere with the transmission or reception of cellular phone system signals by imposing high attenuation losses on RF signals. The Digivance ICS is designed to overcome the attenuation losses that make cellular communications within buildings or structures difficult or impossible. With the Digivance ICS, cellular phone RF signals can be distributed to the interior areas of any building or structure to eliminate dead spots and improve reception. 1.1 Basic System Components The basic components of the Digivance ICS and their functions are shown in Figure 1. The basic system consists of the Digital Host Unit (DHU), Digital Remote Unit (DRU), and when additional capacity or longer fiber runs are required, the Digital Expansion Unit (DEU). In addition, two accessory items, the High Power Conditioning Panel (HPCP) and the Remote Interface Unit (RIU) may be used as needed to interface the DHU with the cellular system Base Transceiver Station (BTS). 1.2 Interface With BTS The DHU interfaces, either locally or remotely, with the BTS. As referenced in this publication, the BTS could be either a microcell or a cell site base station. When the BTS is co-located (microcell interface) with the DHU, a local interface over coaxial cable is possible. An interface device, such as the HPCP, may be used to provide the proper input RF signal level to the DHU. When the BTS is not co-located (cell site base station interface) with the DHU, a remote interface using a donor antenna is required. An interface device, such as the RIU, is used to provide the proper input and output RF signal levels between the donor antenna and the DHU. In the forward path, the DHU receives RF signals from the BTS. The DHU digitizes the RF signals and then converts them to digital optical signals for transport to the DEU’s and DRU’s. In the reverse path, the DHU receives digital optical signals from the DRU’s and DEU’s. The DHU converts the optical signals back to the original RF signal format for the interface with the BTS. 1.3 Interface With Cellular Phones The DRU interfaces (through an external antenna) with the cellular phones. In the reverse path, the DRU receives RF signals from each cellular phone. The DRU digitizes the RF signals and then converts them to digital optical signals for transport to the DHU. In the forward path, the DRU receives digital optical signals from the DHU. The DRU converts the optical signals back to the original RF signal format for transmission to the cellular phones. A small external antenna is connected to the DRU to transmit and receive RF signals to and from the cellular phones.

ADCP-75-130 • Issue 3C • August 2006 Page 2 © 2006, ADC Telecommunications, Inc. DRUDRUDRUDRUDRUDRUDRUDRUDRUDRUDRUDEUDEUDHURIUHPCPREMOTEBTSLOCALBTSRF16417-BRF Figure 1. System Overview Functional Block Diagram 1.4 Digital Fiber Optic Transport The DHU is connected to each DRU unit over a pair of multi-mode or single-mode (depending on the type of optical transceiver specified) optical fibers. One fiber is used to transport the forward path optical signal. The other fiber is used to transport the reverse path optical signal. Because the optical signal is digital, no adjustments to the optical signal level are required at the DRU or the DHU as long as the BER is adequate. Either 62.5 or 50 micron core multi-mode optical fiber; or 9 micron core single-mode optical fiber may be used for the

ADCP-75-130 • Issue 3C • August 2006 Page 3 © 2006, ADC Telecommunications, Inc. optical transport connection. With 62.5 micron core multi-mode fiber , the optical path may be up to 500 meters in length. With 50 micron core multi-mode fiber, the optical path may be up to 750 meters in length. With 9 micron core single-mode fiber, the optical path may be up to 10 kilometers in length. Single- and multi-mode fibers may be used in the same system. The optical fibers must be terminated with duplex LC connectors for connection with the DHU, DEU’s and DRU’s. 1.5 Capacity for Expansion and Extended Runs The DEU enables 6-way expansion of any optical port. This makes it possible to add more DRU’s without having to install additional DHU’s. Each DHU is equipped with six optical ports. If more than six DRU’s are required by the application, a DEU may be connected to one of the DHU optical ports which expands that port to six ports. If still more optical ports are required, then a second DEU may be connected to the DHU; or a second DEU may be connected to the first DEU. The ability to cascade DEU’s in parallel or in series provides unlimited flexibility. It is physically possible to connect an unlimited number DRU’s to the DHU through the installation of DEU’s. The maximum number of DRU’s that can connected to the DHU is limited only by the cumulative noise effect caused by antenna combining. 1.6 Power Requirements The DHU, DEU, and RIU are each powered by 120–240 VAC, 50/60 Hz, 2 Amp power which is supplied through a standard three-conductor 120 VAC power cord. The DRU is powered by 34–48 VDC which is supplied by either the DHU, DEU, or an AC/DC wall-mount style converter. When the DRU is powered by the DHU or DEU, the power is fed through a category 3 or 5 cable terminated with male RJ-45 connectors. 1.7 Fault Detection and Alarm Reporting LED indicators are provided on the front panel of the various units to indicate if the system is normal or if a fault is detected. In addition, normally open and normally closed alarm contacts (for both major and minor alarms) are provided at the DHU for connection to a customer provided external alarm system. This could be a local system or automatic call-out system. 2 DIGTAL UNIT DESCRIPTION This section provides a description of the functions and features provided by the units that comprise the ICS system, a listing of terms used and their definition, and a table of specifications. 2.1 Digital Host Unit Description The DHU, shown in Figure 2, serves as the BTS servicing unit for the Digivance ICS. The DHU provides the following basic functions: • RF inputs and outputs • Optical interface to the DRU’s or DEU’s

ADCP-75-130 • Issue 3C • August 2006 Page 4 © 2006, ADC Telecommunications, Inc. • Digitizing of the cellular forward path RF signal • Distribution of the digitized forward path RF signals into six digitized optical signals • Conversion of up to six reverse path digitized optical signals to six digitized RF signals • Combining of the six digitized RF signals into a single composite digitized RF signal • Conversion of the combined digitized RF signal to a composite RF signal • DC power for powering the DRU’s • Relay contact closures to provide alarm information to an external alarm system 17.2 INCHES(437 mm)3.5 INCHES(89 mm)11.4 INCHES(290 mm)15.3 INCHES(389 mm)FRONT PANELCABLE MANAGEMENTTRAYMOUNTINGBRACKET(BOTH SIDES)17267-A Figure 2. Digital Host Unit 2.1.1 Primary Components The DHU consists of two electronic circuit board assemblies, a power supply assembly, and a fan assembly that are mounted within a powder-coated sheet metal enclosure. The metal enclosure provides a mounting point for the electronic assemblies, serves as a heat sink, and controls RF emissions. Except for the fan units and optical transceivers, the DHU components are not field replaceable. The DHU is designed for use within a non-condensing indoor environment such as inside a wiring closet or cabinet. All controls, connectors, and indicators are mounted on the DHU front panel for convenient access. Cable management functions for the power and fiber optic cables are provided by a cable management tray that extends outward from the DHU front panel. 2.1.2 Mounting The DHU may be used in both rack-mount and wall-mount applications. For rack mount applications, a pair of reversible mounting brackets is provided that allow the DHU to be mounted in either a 19-inch or 23-inch EIA or WECO equipment rack. When rack-mounted, the front panel of the DHU is flush with the front of the rack and the cable management tray extends 3.9 inches (99 mm) beyond the front panel. For wall-mount applications, a pair of holes is provided in the cable management tray which allow the DHU to be mounted on any flat vertical surface. The DHU should be oriented with the front panel facing upward when wall-mounted. Fasteners are provided for rack-mount applications.

ADCP-75-130 • Issue 3C • August 2006 Page 5 © 2006, ADC Telecommunications, Inc. 2.1.3 Fault Detection and Alarm Reporting The DHU detects internal circuitry faults and optical port faults. Various front panel Light Emitting Diode (LED) indicators turn from green to red or yellow if a fault is detected or an optical input is lost. A set of alarm contacts (normally open and normally closed) are also provided for reporting an alarm to an external alarm system when a fault is detected. Both major alarm (all fault conditions except high temperature) and minor alarm (high temperature fault condition) contacts are provided. 2.1.4 RF Signal Connections The RF signal connections with the BTS are supported through two N-type female connectors. One connector is used for coaxial cable connection of the forward path RF signal. The other connector is used for coaxial cable connection of the reverse path RF signal. In most installations, the DHU will not connect directly to the BTS but will be connected to an interface device such as the RIU or the HPCP. Additional information concerning the DHU to BTS interface is provided in the Digivance ICS Remote Interface Unit User Manual (ADCP-75-178) and in the Digivance ICS 800 and 1900 MHz High Power Conditioning Panel User Manual (ADCP-75-175). Maximum output at the DRU antenna port is obtained when the level of the composite forward path RF signal input to the DHU is 1 dB below the DHU overdrive level. The maximum signal level the DHU will accept is determined by the DHU overdrive limiter. If the input signal level is above a specified level, the overdrive limiter will incrementally insert attenuation. The overdrive limiter protects the system against excessive inputs but does not function during normal operation. The level of the RF signal output at the DRU is dependent on the modulation protocol and the number of carriers. 2.1.5 Optical and Electrical Connections The optical and electrical connections with the DRU’s and DEU’s are supported by six optical and six electrical ports. Each optical and electrical port consists of a status LED, an RJ-45 DC power jack, a port enabled/disable switch, and a small form factor LC-type optical transceiver (available separately). Each transceiver is color-coded to identify whether it supports single-mode (blue) or multi-mode (black/beige) fiber. An optical port may be connected to a DRU, a DEU, or not used. An electrical port may be connected to a DRU or not used. Unused ports are disabled via the corresponding port enable/disable switch. When disabled, the port LED is off, the alarm reporting function is disabled, the laser is off, and the DC power is off. Enabling the enable/disable switch activates all functions. The modular optical transceivers are accessory items and are field replaceable. 2.1.6 Powering The DHU is powered by 120–240 VAC (50/60 Hz) power which is supplied through a standard three-conductor 120 VAC power cord. The power cord is provided with the DHU and is 98 inches (2.5 meters) long. A resetable circuit breaker/On-Off switch is provided at the unit front panel. The switch applies power to the DHU internal power supply.

ADCP-75-130 • Issue 3C • August 2006 Page 6 © 2006, ADC Telecommunications, Inc. 2.1.7 Cooling Continuous air-flow for cooling is provided by dual fans mounted on the right side of the housing. A minimum of 3 inches (76 mm) of clearance space must be provided on both the left and right sides of the DHU for air intake and exhaust. An alarm is provided that indicates if a high temperature condition (>50º C/122º F) occurs. The fans may be field-replaced if either fan fails. 2.1.8 User Interface The DHU user interface consists of the various connectors, switches, terminals, and LEDs that are provided on the DHU front panel. The DHU user interface points are described in Table 1 and indicated in Figure 3. Table 1. Digital Host Unit User Interface REFNo. USER INTERFACE DESIGNATION DEVICE FUNCTIONAL DESCRIPTION 1 Ground stud Used for connecting a grounding cable to the DHU chassis. 2 POWER 3-wire AC power cord connector Used for connecting the AC power cord. 3 I/O I/O rocker switch/ circuit breaker Provides AC power On/Off control and AC power over current protection. 4 OK/NOK (Ports 1–6) Multi-colored LED (Red/Green/Yellow) Indicates if the DRU or remote DEU connected to the optical port is normal or faulty or if the reverse path optical input from the DRU or remote DEU is normal or lost. (see Note) 5 ON/OFF (Ports 1–6) I/O rocker switch Enables or disables corresponding electrical and optical ports. 6 DC PWR (Ports 1–6) RJ-45 jack (female) Used for connecting a DRU cat 3 or 5 power cable to the designated DC power jack. 7 FIBER (Ports 1–6) LC-type optical transceiver Used for connecting each DEU or DRU forward path and reverse path optical fibers to the designated optical port. 8 UNIT Multi-colored LED (Red/Green/Yellow) Indicates if the DHU is normal or faulty. (see Note) 9 OVERDRIVE Multi-colored LED (Red/Green/Yellow) Indicates when the forward path RF input power is overdriving the DHU digitizing circuitry. (see Note) 10 MAJOR MINOR Screw-type terminal connector (14–26 AWG) Used for connecting an external alarm system to the DHU. Includes normally open (NO), normally closed (NC), and common (COM) wiring connections. 11 RF IN N-type female RF coaxial connector Used for connecting the forward path RF coaxial cable to the DHU. 12 RF OUT N-type female RF coaxial connector Used for connecting the reverse path RF coaxial cable to the DHU. Note: A more detailed description of LED operation is provided in Section 5.

ADCP-75-130 • Issue 3C • August 2006 Page 7 © 2006, ADC Telecommunications, Inc. (2) AC POWER CORDCONNECTOR(3) AC POWER ON/OFF SWITCH(1) GROUNDSTUD(4) OPTICAL PORT LED INDICATOR(6 PLACES)(5) OPT/ELEC PORTENABLE/DISABLESWITCH (6 PLACES)(6) ELECTRICAL PORTDC POWER JACK(6 PLACES)(7) OPTICAL PORTOPTICAL TRANSCEIVERTX-LEFT - RX-RIGHT(6 PLACES)(8) UNIT LEDINDICATOR(11) RF INPUTCONNECTOR(9) OVERDRIVELEDINDICATOR(10) ALARMCONNECTORRECEPTACLE(12) RF OUTPUTCONNECTOR17264-ANOTE: SHOWN WITHOUTCABLE MANAGEMENT TRAY Figure 3. Digital Host Unit User Interface 2.2 Digital Remote Unit Description The DRU, shown in Figure 4, serves as the remote interface unit for the Digivance ICS. The DRU provides the following basic functions: • RF interface to the cellular users via an external antenna • Optical interface to the DHU or DEU • Conversion of the forward path digitized optical signal to a digitized RF signal • Conversion of the digitized forward path RF signal to the original cellular RF signal • Digitizing of the cellular reverse path RF signal • Conversion of the digitized reverse path RF signal to a digital optical signal output • Transports alarm status over the reverse path optical fiber FRONT PANELMOUNTING FOOT(EACH CORNER)7.0 INCHES(178 mm)7.3 INCHES(185 mm)2.1 INCHES(53 mm)17268-A Figure 4. Digital Remote Unit

ADCP-75-130 • Issue 3C • August 2006 Page 8 © 2006, ADC Telecommunications, Inc. 2.2.1 Primary Components The DRU consists of an electronic circuit board assembly that is mounted within a powder-coated sheet metal enclosure. The metal enclosure provides a mounting point for the electronic assembly, serves as a heat sink, and controls RF emissions. Except for the optical transceiver, the DRU components are not field replaceable. The DRU is designed for use within a non-condensing indoor environment such as inside a building. All controls, connectors, and indicators (except the SMA antenna connector) are mounted on the DRU front panel for convenient access. 2.2.2 Mounting The DRU is equipped with four integral mounting feet that allow it to be mounted on any flat horizontal or vertical surface. A typical location for mounting the DRU would be on a ceiling or a wall. Slots are provided in the mounting feet for securing the DRU to the mounting surface. 2.2.3 Fault Detection The DRU detects internal circuitry faults or loss of system inputs. A front panel LED indicator turns from green to red when a fault condition is detected or when the optical input is lost. The DRU sends the fault information to the DHU or DEU over the reverse path optical fiber. A corresponding port LED at the DHU or DEU turns from green to red when the DRU reports a fault. 2.2.4 Antenna Connection The RF signal interface between the DRU and the cellular users is provided through an external antenna. An SMA connector is provided for connecting the DRU to the antenna. The antenna must be ordered separately. Several types of antennas with various RF propagations are available. Non-ADC antennas may also be used with the DRU to meet various application requirements but must comply with equipment authorization for RF exposure compliance. 2.2.5 Optical Port The DRU uses a small form factor LC-type optical transceiver for connecting the optical fibers. Each transceiver is color-coded to identify whether it supports single-mode (blue) or multi-mode (black/beige) fiber. Depending on the application requirements, the optical port may be connected to either a DHU or a DEU. The modular optical transceiver is an accessory item and is field replaceable. 2.2.6 Powering The DRU is equipped with a female RJ-45 jack that provides a connection point for the DC power cable. The DRU is powered by 34–48 VDC power which is supplied through the RJ-45 connector. Power to the DRU may be supplied by the DHU, DEU, or by a 120 VAC to 48

ADCP-75-130 • Issue 3C • August 2006 Page 9 © 2006, ADC Telecommunications, Inc. VDC power converter (available separately as an accessory item) plugged into a properly grounded 120 VAC outlet. The AC/DC converter is a UL Listed stand-alone Limited Power Supply (LPS) unit with a rated output of 48 VDC at 1.2 Amps. When powered by the DHU or DEU, a category 3 or 5 twisted-pair cable terminated with RJ-45 connectors is required. 2.2.7 Cooling The DRU is cooled by natural convection air-flow. The DRU mounting feet are designed to provide clearance under the unit so that air can enter the DRU enclosure from the bottom and exit through the top. A minimum clearance of 3 inches (76 mm) must be provided on all sides of the DRU (except the bottom) to ensure there is adequate air circulation for cooling. In addition, at least one surface of the DRU installation area must be open to the interior of the building. 2.2.8 User Interface The DRU user interface consists of the connectors and LED that are provided on the DRU front and rear panels. The DRU user interface points are described in Table 2 and indicated in Figure 5. Table 2. Digital Remote Unit User Interface REFNo. USER INTERFACE DESIGNATION DEVICE FUNCTIONAL DESCRIPTION 1 STATUS Multi-colored LED (Red/Green/Yellow) Indicates if the status of the DRU is normal or faulty or if the forward path optical input is normal or lost. (see Note) 2 48 VDC RJ-45 jack (female) Used for connecting a DC power cable. 3 FIBER TX RX LC-type optical transceiver Used for connecting the forward path and reverse path optical fibers. 4 – SMA-type coaxial connector (female) Used for connecting the antenna coaxial cable lead. Note: A more detailed description of LED operation is provided in Section 5. 17269-AREAR VIEWFRONT VIEW(4) ANTENNA CONNECTOR(1) STATUS LED(2) 48 VDC POWERCONNECTOR(3) FIBER LINKOPTICAL ADAPTERSTX-LEFT - RX-RIGHT Figure 5. Digital Remote Unit User Interface

ADCP-75-130 • Issue 3C • August 2006 Page 10 © 2006, ADC Telecommunications, Inc. 2.3 Digital Expansion Unit Description The DEU, shown in Figure 6, serves as a service expansion unit and line extender for the Digivance ICS. The DEU provides the following basic functions: • Optical interface to the DHU and up to six DRU’s or DEU’s • Conversion of the forward path digitized optical signal to an electrical bit stream • Splitting of the electrical bit stream into six separate bit streams • Conversion of the six forward path electrical bit streams into six digital optical signals • Conversion of up to six reverse path digital optical signals into six serial bit streams • Combining of the six reverse path serial bit streams into a single digital composite signal • Conversion of the single digital composite signal to a digital optical signal • DC power for powering the DRU’s • Alarm transport via the optical fibers FRONT PANELCABLE MANAGEMENTTRAYMOUNTINGBRACKET(BOTH SIDES)17270-A3.5 INCHES(89 mm)11.4 INCHES(290 mm)15.3 INCHES(389 mm)17.2 INCHES(437 mm) Figure 6. Digital Expansion Unit 2.3.1 Primary Components The DEU consists of two electronic circuit board assemblies and a power supply that are mounted within a powder-coated sheet metal enclosure. The metal enclosure provides a mounting point for the electronic assemblies and serves as a heat sink. Except for the fan units and optical transceivers, the DEU components are not field replaceable. The DEU is designed for use within a non-condensing indoor environment such as inside a wiring closet or cabinet. All controls, connectors, and indicators are mounted on the DEU front panel for convenient access. Cable management functions for the power and fiber optic cables are provided by a cable management tray that extends outward from the DEU front panel. 2.3.2 Mounting The DEU may be used in both rack-mount and wall-mount applications. For rack mount applications, a pair of reversible mounting brackets is provided that allows the DEU to be

ADCP-75-130 • Issue 3C • August 2006 Page 11 © 2006, ADC Telecommunications, Inc. mounted in either a 19-inch or 23-inch EIA or WECO equipment rack. When rack-mounted, the front panel of the DEU is flush with the front of the rack and the cable management tray extends 3.9 inches (99 mm) beyond the front panel. For wall-mount applications, a pair of holes is provided in the cable management tray which allow the DEU to be mounted on any flat vertical surface. The DEU should be oriented with the front panel facing upward when wall-mounted. Fasteners are provided for rack-mount applications. 2.3.3 Fault Detection The DEU detects internal circuitry faults or loss of system inputs. Various front panel Light Emitting Diode (LED) indicators turn from green to red or yellow when a fault is detected or when an optical input is lost. The DEU transports the fault information to the DHU or supporting DEU over the reverse path optical fiber. A corresponding port LED at the DHU or DEU turns from green to red when the DEU reports a fault. 2.3.4 Optical and Electrical Connections The optical and electrical connections with the DRU’s and DEU’s are supported by six optical and six electrical ports. Each optical and electrical port consists of a status LED, an RJ-45 DC power jack, a port enable/disable switch, and a small form factor LC type optical transceiver (available separately). Each transceiver is color-coded to identify whether it supports single-mode (blue) or multi-mode (black/beige) fiber. An optical port may be connected to a DRU, a DEU, or not used. An electrical port may be connected to a DRU or not used. Unused ports are disabled via the corresponding port enable/disable switch. When disabled, the port LED is off, the alarm reporting function is disabled, the laser is off, and the DC power is off. Enabling the enable/disable switch activates all functions. The DEU also provides one optical port (designated as the host port ) for the optical interface with the DHU or a supporting DEU. The modular optical transceivers are available as accessory items and are field replaceable. 2.3.5 Powering The DEU is powered by 120–240 VAC (50/60 Hz) power which is supplied though a standard three-conductor 120 VAC power cord. The power cord is provided with the DEU and is 98 inches (2.5 meters) long. A resetable circuit breaker/On-Off switch is provided at the unit front panel. The switch applies power to the DEU internal power supply. 2.3.6 Cooling Continuous air flow for cooling is provided by dual fans mounted on the right side of the sheet metal housing. A minimum of 3 inches (76 mm) of clearance space must be provided on both the left and right sides of the DEU for air intake and exhaust. An alarm is provided that indicates if a high temperature condition (>50º C/122º F) occurs. The fans may be field-replaced if either unit fails. 2.3.7 User Interface The DEU user interface consists of the various connectors, switches, and LEDs that are provided on the DEU front panel. The DEU user interface points are described in Table 3 and indicated in Figure 7.

ADCP-75-130 • Issue 3C • August 2006 Page 12 © 2006, ADC Telecommunications, Inc. Table 3. Digital Expansion Unit User Interface REFNo. USER INTERFACE DESIGNATION DEVICE FUNCTIONAL DESCRIPTION 1 Grounding stud Used for connecting a grounding cable to the DEU chassis. 2 POWER 3-wire AC power cord connector Used for connecting the AC power cord. 3 I/O I/O rocker switch/ circuit breaker Provides AC power On/Off control and AC power over current protection. 4 OK/NOK (Ports 1–6) Multi-colored LED (Red/Green/Yellow) Indicates if the DRU or remote DEU connected to the optical port is normal or faulty or if the reverse path optical input from the DRU or remote DEU is normal or lost. (see Note) 5 ON/OFF (Ports 1–6) I/O rocker switch Enables or disables corresponding electrical and optical ports. 6 DC PWR (Ports 1–6) RJ-45 jack (female) Used for connecting a DRU cat 3 or 5 power cable to the designated DC power jack. 7 FIBER (Ports 1–6) LC-type optical transceiver Used for connecting each DRU or remote DEU forward path and reverse path optical fiber to the designated optical port. 8 HOST PORT LC-type optical transceiver Used for connecting the DHU or supporting DEU forward path and reverse path optical fiber. 9 UNIT Multi-colored LED (Red/Green/Yellow) Indicates if the DEU is normal or faulty. (see Note) 10 HOST PORT Multi-colored LED (Red/Green/Yellow) Indicates if the forward path optical input from the DHU or supporting DEU is normal or lost. (see Note) Note: A more detailed description of LED operation is provided in Section 5. 17266-A(3) AC POWER ON/OFF SWITCH(1) GROUNDINGSTUD(4) OPTICAL PORT LED INDICATOR(6 PLACES)(5) OPT/ELEC PORTENABLE/DISABLESWITCH (6 PLACES)(9) UNIT LEDINDICATOR(2) AC POWER CORDCONNECTOR(6) ELECTRICAL PORTDC POWER JACK(6 PLACES)(7) OPTICAL PORTOPTICAL TRANSCEIVERTX-LEFT - RX-RIGHT(6 PLACES)(10) HOST PORTLEDINDICATOR(8) HOST PORTOPTICAL TRANSCEIVERTX-LEFT - RX-RIGHTNOTE: SHOWN WITHOUTCABLE MANAGEMENT TRAY Figure 7. Digital Expansion Unit User Interface

ADCP-75-130 • Issue 3C • August 2006 Page 13 © 2006, ADC Telecommunications, Inc. 2.4 Terms and Definitions Refer to Table 4 for a listing of the terms used in this manual and their definition. Table 4. Terms and Definitions TERM DEFINITION Alarm Response The response to an alarm input. Base Transceiver Station The radio equipment that transmits and receives the voice and control channels to and from the cellular handsets. Composite Signal A signal that is the sum of several signals. Digital Expansion Unit The unit that extends a single optical interface to multiple optical interfaces or that extends an optical run. Digital Host Unit The unit that converts and provides the digital source signal to all DEU’s and DRU’s and converts summed inputs from DEU’s and DRU’s. Digital Remote Unit The unit that interfaces the in-building user to the Digivance optical transport. Digitized RF Signal The RF signal in a digitized form. Forward Path Signal A signal that travels from the base station to the cell phone. Major Alarm An alarm condition that applies when any fault (except high temperature) occurs. Minor Alarm The alarm condition that applies when a high temperature condition occurs. (> 50º C/122º F) Mute To force a forward path RF signal to a “no signal” state. Normal State The operating state after power-up is completed and no faults are detected. Port An RF, optical, or electrical interface point. Port Alarm A fault that affects only the unit or units connected to that port. Indicates no optical input to port. Power-Up State The period between the application of power to a unit and the normal state. This period includes time for circuit stabilization and initialization operations. Reverse Path Signal A signal that travels from one or more cell phones to the base station. Transport Alarm Signal An alarm signal transported over the reverse path optical fiber. Unit Alarm A fault within a unit that usually affects all connected ports. 2.5 Specifications Refer to Table 5 for the Digivance ICS system specifications. All specifications apply after a five minute warm-up period.

ADCP-75-130 • Issue 3C • August 2006 Page 14 © 2006, ADC Telecommunications, Inc. Table 5. System Specifications PARAMETER SPECIFICATION REMARKS Optical – All Units Fiber type Multi-mode: 50 or 62.5 micron coreSingle-mode: 9 micron core Two fibers per transport link Maximum fiber length for guaranteed performance 500 m (1,641 ft) 750 m (2461 ft) 10 km (32,808 ft) With 62.5 micron core MM fiber With 50 micron core MM fiber With 9 micron core SM fiber Optical output power –10 to –3 dBm Optical wavelength 850 nm for multi-mode use 1310 nm for single-mode use Environmental Operating temperature 0º to 50º C (32º to 122º F) Storage temperature –30º to +70º C (–22 to 158º F) Humidity No condensation Weather resistance NEMA 1, IEC 529 IP30 Indoor installation only Airborne contaminants (DRU only) At or below levels established in Telecordia Standard, GR-63-CORE, Network Equipment-Building System (NEBS) Requirements: Physical Protection, Section 4.5 Airborne Contaminants, Table 4-11, Indoor Contaminant Levels. RF Forward Path System bandwidth 25 MHz 800 MHz (A and B bands) US Cellular 869 to 894 MHz Output power See Table 6 Maximum composite output signal requires maximum input signal Gain +33 dB nominal At room temperature Gain variation < 6 dB < 1.5 dB variation per 1.25 MHz CDMA channel Over frequency, temperature, and unit to unit. May have up to 2 dB variation at upper band edge. OIP3 +35 dBm typical At max. composite output power CDMA ACPR1 < –45 dBc Spurious Output < –40 dBm Maximum RF input signal level (composite) Approximately –10 dBm Will vary depending on access protocol and number of carriers RF Reverse Path System bandwidth 25 MHz 800 MHz (A and B bands) US Cellular 824 to 849 MHz Gain +10 dB nominal Gain Variation < 6 dB < 1.5 dB variation per 1.25 MHz CDMA channel Over frequency, temperature, and unit to unit. Automatic Gain Limiting Enabled for composite RF input > –40 dBm Prevents A/D saturation with large inputs. (continued)

ADCP-75-130 • Issue 3C • August 2006 Page 15 © 2006, ADC Telecommunications, Inc. Table 5. System Specifications, continued PARAMETER SPECIFICATION REMARKS Noise Figure < 8 dB + 10 log N where N = # of remotes < 8 dB typical. See Note at end of table. DHU RF output signal level –30 dBm maximum With a –40 dBm composite maximum input signal at the DRU Physical/Electrical – DHU Weight 18.5 lbs (8.4 kg) RF connection Type N Female Alarm connection Screw terminals (14–26 AWG) NO, NC, and COM (form C relay contacts) Optical connection Duplex LC transceiver DC power output connection RJ-45 Female Power input 120–240 VAC, 50/60 Hz AC power connection IEC 320 Male Power consumption 250 W Maximum Current rating 2 Amps at 120 VAC Physical/Electrical – DEU Weight 18.5 lbs (8.4 kg) Optical connection Duplex LC transceiver DC pwr output connection RJ-45 Female Power input 120–240 VAC, 50/60 Hz AC power connection IEC 320 Male Power consumption 250 W Maximum Current rating 2 Amps at 120 VAC Physical/Electrical – DRU Weight 1.5 lbs (708 g) RF connection SMA Female Antenna types Ceiling mount omni directional 90º directional panel Ceiling mount hallway 2.5 dBi gain 7.5 dBi gain 4 dBi gain Optical connection Duplex LC transceiver DC pwr input connection RJ-45 Female Power input 34 to 48 VDC DC power cable length (Cat-3 or -5 cable) 500 meters (1,641 ft) maximum Any distance beyond 500 meters requires alternate power sourcing Power consumption 17 W Typical Current rating 400 mA at 48 VDC Note : The noise from all remotes is added at the host. Given N units with identical gain and noise, the formula applies exactly. Slight unit to unit noise figure and gain variations make this a very useful approximation.