P009152A Ericsson GSM System RBS 2106, RBS 2206 Hardware Reference Manual EN/LZT 720 0024 R2A
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Introduction 1 &$37,21 /,67 Document No.
E RBS 2106, RBS 2206 Hardware Reference Manual RBS 2106, RBS 2206 Hardware Reference Manual © Ericsson Radio Systems AB — All Rights Reserved — EN/LZT 720 0024 2002-11-01 R2A © Ericsson Radio Systems AB — All Rights Reserved — 1 (34)
RBS 2106, RBS 2206 Hardware Reference Manual Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to revision without notice.
RBS 2106, RBS 2206 Hardware Reference Manual Contents 1 Introduction ................................................................................................... 7 1.1 Objectives................................................................................................ 7 1.2 Target Groups.......................................................................................... 8 1.3 RBS 2000 Library Overview.................................................................... 8 1.
RBS 2106, RBS 2206 Hardware Reference Manual 3.5.5 Mechanically Active Substances .......................................................... 18 3.5.6 Mechanical Conditions..........................................................................18 3.6 Handling -40 C - +70 C...........................................................................19 3.6.1 General Conditions...............................................................................19 3.6.2 Climatic Conditions............................
RBS 2106, RBS 2206 Hardware Reference Manual 4.3.2 Conducted Emission.............................................................................30 4.3.3 Radiated Emission from Enclosure...................................................... 30 4.3.4 Conducted Immunity on AC Input Power Ports................................... 31 4.3.5 Immunity on DC Input/Output Power Ports..........................................32 4.3.6 Immunity on Telecommunication and External Signal Lines ............... 32 4.3.
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Introduction 1 Introduction This Hardware Reference Manual is valid for the Ericsson GSM system BSS R8 except for the description of GSM 800, which is valid from BSS R9. 1.1 Objectives This manual describes the hardware for RBS 2106 and RBS 2206, the Ericsson RBS 2000 Macro system based on 12–TRX cabinets for GSM 800, GSM 900, GSM 1800 and GSM 1900.
Introduction Table 1 1.
Introduction 1.4 How to Order CPI CPI can be ordered in the same way as all other Ericsson products using the product number to identify each product. Orders can be placed through any local Ericsson company, or alternatively, on the Internet. How operators and customers and Ericsson companies order CPI is described in detail below. 1.4.1 Outside Ericsson To place an order for CPI, contact any Ericsson company and follow the same procedure as with all other Ericsson products.
Introduction 1.4.2 Inside Ericsson The Intranet is an internal Ericsson web that can only be accessed by Ericsson personnel. All CPI products are available on the Intranet at CPI Store: http://cpistore.ericsson.se Ericsson personnel, who may require access to CPI while operating outside Ericsson’s firewall, can get more information about Extranet access from the following address: http://inside.ericsson.se/ebusiness/ 1.
Introduction Table 2 Revised or updated chapters (documents) Title New Reason for Revision Revision No. Radio Configurations, RBS 2106 and RBS 2206 R1A RBS 2106 Antenna Configurations R1A Information has been added for CDU-G 1x4, 1x6 and 1+1+2 configurations. This chapter has been made into an independent CPI product. Antenna connection field information has been updated for RF LMU connections. This chapter has been made into an independent CPI product.
Introduction This page is intentionally left blank 12 (34) © Ericsson Radio Systems AB — All Rights Reserved — EN/LZT 720 0024 R2A 2002-11-01
Product Safety Requirements RBS 2000 2 Product Safety Requirements RBS 2000 The purpose of this document is to specify the product safety requirements for RBS 2000. 2.1 References 73/23/EEC Low Voltage Directive CAN/CSA-C22.2 No 1-M94 Audio, Video and Similar Electronic Equipment CAN/CSA-C22.2 No 950-95 Safety of Information Technology Equipment Including Electrical Business Equipment 2.
Product Safety Requirements RBS 2000 In addition to this the product fulfills the environmental requirements. The RBS is so designed and constructed that, under all conditions of normal use and under a likely fault condition, it protects against personal injury from electrical shock and other hazards. The RBS is protected against serious fire originating in the equipment as well as mechanical hazards in the equipment, as well as mechanical hazards in the meaning of the applicable standard.
Environmental Capabilities 3 Environmental Capabilities 3.1 Scope This chapter covers the environmental requirements for the indoor and outdoor temperature non-controlled operation conditions. The subjects are: Climatic, Biological, Chemically active substances, Mechanically active substances and Mechanical conditions. 3.2 Terminology Definition of concepts: Normal Operation Conditions Environmental conditions where all units shall be able to function as specified.
Environmental Capabilities 3.3 3.4 3.4.1 References IEC 721-3-.. Classification of groups of environmental parameters and their severities. ETSI 300 019-1-.. Classification of environmental conditions. Transport -40 C - +70 C General Conditions The severity of the requirements is in conformity with: IEC 721-3-2 classes 2K4/2B2/2C2/2S2/2M2. and ETS 300 019-1-2 Class 2.3 "PUBLIC transportation". These requirements are valid for equipped cabinets (excluding batteries).
Environmental Capabilities Note: 3.4.5 The values are average yearly levels of airborne contaminants that can be accepted. It is assumed that one of the contaminants is dominant at each site, and that the other is present in insignificant amounts. Mechanically Active Substances The severity of these requirements is in conformity with: IEC 721-3-2 class 2S2. and ETS 300 019-1-2 Class 2.3. 3.4.
Environmental Capabilities The severity of these requirements is in conformity with IEC 721-3-1 classes 1K4/1Z2/1Z3/1Z5. and ETS 300 019-1-1 class 1.2. Requirements Table 5 3.5.3 Environmental Parameters Unit Value Temperature -25 - +55 Relative humidity % C 10 - 100 Biological Conditions The severity of these requirements is in conformity with IEC 721-3-1 class 1B2. and ETS 300 019-1-1 class 1.2. 3.5.
Environmental Capabilities 3.6 Handling -40 C - +70 C 3.6.1 General Conditions This section refers to shorter periods of transport and storage in unpacked conditions. Precautions to avoid condensation before subjecting the equipment to operational conditions are necessary. 3.6.2 Climatic Conditions During handling the equipment withstands the conditions stated in Section 3.4.2 on page 16 in this document. 3.6.
Environmental Capabilities 3.7.2 Climatic Conditions The severity of these requirements are in conformity with: IEC 721-3-3 classes 3K3/3Z2/3Z4. and ETS 300 019-1-3 Class 3.1. Table 7 Environmental Unit Parameters 3.7.3 Temperature Relative humidity % C Value Normal Condition Safe Function Nondestruction +5 - +40 0 - +45 -10 - +55 5 - 85 5 - 90 5 - 90 Biological Conditions Requirements There are no requirements for this condition. 3.7.
Environmental Capabilities Table 8 Environmental Parameters Unit Value Vibration sinus: displacement mm acceleration m/s² frequency Hz 0.6 2 2-9 9 - 200 Vibration random: 2 3 0.1 m /s 2 3 0.2 acceleration m/s² 3.8 acceleration m/s² 5.
Environmental Capabilities 3.9 Operation Outdoor -33 C - +45 C The severity of the requirements is in conformity with: IEC 721-3-4 classes 4K2/4Z5/4Z7/4B1/4C2(4C3)/4S2/4M5. and ETS 300 019-1-4 Class 4.1. "NON-WEATHERPROTECTED location", except for the temperature range which is extended to +45 C. This clause refers to the environment which an RBS for outdoor non-weather protected location endures.
Environmental Capabilities Table 11 Environmental Parameters Unit Value Vibration sinus: displacement mm acceleration m/s² frequency Hz 0.6 2 2-9 9 - 200 no. of sweep cycles 5 no. of test directions 3 testing method IEC 68-2-6 Vibration random: 2 3 0.1 m /s 2 3 0.2 acceleration m/s² 3.8 acceleration m/s² 5.
Environmental Capabilities There are possibilities to equip the RBS with an optional Seismic Exposure protection device. 3.10 Operation Outdoor -33 C - +55 C This Environmental class corresponds in full to Operation Outdoor -33 C - +45 C with the exception of the upper temperature limit. 3.11 Operation Mast Mounted Equipment -33 C - +45 C This Environmental class corresponds to Operation Outdoor -33 C +45 C with the exceptions stated below.
Environmental Capabilities Table 14 Environmental Parameters Unit Temperature Relative humidity Absolute humidity Change of temperature Rain temperature C % 3 g/m C/min C Value Normal Condition Non-destruction -33 - +55 5 - 100 0.26 -40 6 5 -40 - +70 5 - 100 0.26 - 40 6 5 Vibration sinus: displacement acceleration frequency Vibration random: mm 2 m/s Hz 2 3 3 2-9 10 9 - 200 0.5 2 - 200 0.2 200 - 500 ASD frequency m /s Hz peak acc. duration m/s ms 100 11 none Not Appl.
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EMC Capabilities 4 EMC Capabilities This specification covers the capabilities of the RBS 2000 in respect of EMC (ElectroMagnetic Compatibility). The capabilities include conducted and radiated emission as well as conducted and radiated immunity thresholds. The internal EMC capabilities of RBS 2000 and interference appearing on antenna ports are not covered by this chapter. 4.1 References 1.
EMC Capabilities Power frequency magnetic fiels immunity tests 13. EN 61000–4–11 Voltage Dips, short interruptions and voltage variations. Immunity tests 14. VDE 0878, 1986 Radio Interface Suppression of Telecommunication Systems and Apparatus 15. ITU-T Recommendation K.20, 1984 Resistibility of Telecommunication Switching Equipment to Overvoltages and Overcurrents. 4.
EMC Capabilities Performance Criteria TT Transient phenomena applied to Transmitters. A communication link shall be established at the start of the test and maintained during and after injection of the transients Performance Criteria CR Continous phenomena applied to Receivers. A communication link shall be established at the start of the test and maintained during the test. For the system the RXQUAL (as defined in GSM 05.
EMC Capabilities EMC directive The EMC capabilities of the RBS fulfills the mandatory requirements specified in the EMC directive, 89/336/EEC, which gives compliance for trade in EU member countries. Generic Standards The following generic standards are fulfilled by the system: EN 50 081–1, Jan 1992 Emission EN 50 082–1, Jan 1992 Immunity 4.3.
EMC Capabilities Table 21 4.3.
EMC Capabilities 4.3.
EMC Capabilities Table 30 Surge test 1.
EMC Capabilities Criteria CT for transmitter units Criteria CR for receiver units Table 35 4.3.8 Immunity of 50/60 Hz magnetic fields Basic standard EN 61000-4-8 Test level 10 A/m, 50/60 Hz Performance Criteria A Electro-static Discharges Table 36 Immunity of enclosure port Basic standard EN 61000-4-2 Test level Air discharges: 15 kV Contact discharges: 8 kV Performance Criteria B Limit standard ETS 300 342-2 Test level Air discharges: 8 kV Contact discharges: 4 kV.
RBS 2106 Product Description RBS 2206 Product Description RBS 2106, RBS 2206 Radio Configurations 2/001 53-EN/LZT 720 0024 RBS 2106 Antenna Configurations RBS 2106, RBS 2206 Hardware Reference Manual RBS 2206 Antenna Configurations ACCU-01, Description ACCU-02, Description ADM-01, Description ASU, Description BFU-21, Description BFU-22, Description CDU-F, Description CDU-G, Description Combined Climate Unit, Description CXU-10, Descript
EN/LZT 720 0222 R3A RBS 2106 Radio Base Station Product Description The RBS 2106, a member of the RBS 2000 family, is a 12 TRX radio base station for outdoor applications. RBS 2106 can be configured for omni cells, or for multi-sector cells of up to three sectors.
Radio Base Station RBS 2106 Contents 2 (30) 1 1.1 1.2 1.3 Product Overview Main features Variants Optional Equipment 3 3 4 4 2 Dimensions 5 3 Space requirements 6 4 4.1 4.2 4.3 4.4 Environment Operating Environment Environmental Impact Compliance Distances for Electromagnetic Exposure Materials 7 8 8 10 12 5 5.1 5.2 Hardware Units Standard Hardware Units Optional Hardware Units 12 13 16 6 6.1 6.2 6.3 Interfaces External connections Test interface Operator Interface 18 18 22 22 7 7.1 7.
RBS 2106 1 Radio Base Station Product Overview The RBS 2106 is a high-capacity outdoor base station. It is used for outdoor applications, with up to six double Transceiver Units (dTRU). There is space inside the cabinet for transmission equipment and battery back-up. The RBS 2106 is designed to be transported as a fully-assembled cabinet to the site. All units in the cabinet are easily accessible from the front of the cabinet, which means that the cabinet can be mounted against a wall. 1.
Radio Base Station 1.2 RBS 2106 Variants The following variants are available and can be combined according to ordering information: 1.
RBS 2106 2 Radio Base Station Dimensions This section describes the RBS 2106 dimensions, space requirements and colour. Size and weight 1300 925 1560 56,5 710 925 Unit of measurement: mm P008565A Figure 1 RBS 2106 dimensions Table 1 RBS 2106 weights Unit Weight Fully equipped including batteries 685 kg Fully equipped excluding batteries 560 kg Door with climate unit 150 kg Surface and Colour The RBS 2106 has a surface quality according to Ericsson standard class A3/B6.
Radio Base Station RBS 2106 Table 2 3 RBS 2106 colours Colour Reference number Ericsson number Grey RAL 7035 MZY 543 03/8119 Green NCS 8010-G 10Y MZY 543 03/685 Space requirements Installation and maintenance require that the door can be opened at least 90°. In practice this means that the space in front of the cabinet must be kept clear for a distance of 1300 mm, see figure below.
RBS 2106 Radio Base Station Footprint The footprint of the RBS 2106 is 1300 mm wide and 710 mm deep. Note that the door, which is 242 mm deep, is not included in the footprint, as it does not reach down to the ground. The installation frame of the RBS 2106 has the same bottom holing pattern as that of the RBS 2102.
Radio Base Station 4.1 RBS 2106 Operating Environment Climatic Requirements Table 3 Climatic requirements Safe function Temperature Normal Conditions -33° – +45°C (1) 15 – 100% Transport -40° – +70°C 5 – 100% Storage -25° – +55°C 10 – 100% Handling -40° – +70°C 5 – 100% (1) Relative humidity Upper limit +40°C with the Air-to-Air Heat Exchanger. Ground Vibrations The RBS 2106 is designed to fulfill earthquake protection according to IEC 68–2–57.
RBS 2106 Radio Base Station FRONT Mounted in free field Ambient temperature <30oC dB 60 FRONT Mounted in free field Max. ambient temperature dB 60 50 50 40 40 30 30 5 dB 60 10 15 20 25 m 5 10 BEHIND Mounted in free field Ambient temperature <30oC 15 dB 60 50 50 40 40 20 25 30 35 m BEHIND Mounted in free field Max.
Radio Base Station 4.3 RBS 2106 Compliance Distances for Electromagnetic Exposure The compliance distance is the minimum separation that should be kept between an antenna and a person to ensure that RF exposure limits are not exceeded. Ericsson has performed a near-field RF exposure assessment of typical configurations of the RBS 2106 with a recommended antenna. The resulting dimensions, in metres, for a compliance boundary for both public and occupational exposure, are shown in Table 4.
RBS 2106 Radio Base Station Table 4 Compliance boundary dimensions for the General Public (GP) and Occupational (O) exposure for typical configurations. Tilt: 0°. Compliance distances (m) (1) Diameter of cylinder Frequency Configuration GP (MHz) 900 G:1x2, G:1x4 5 O GP O Distance behind antenna GP O 2 1.6 1.3 0.1 0.05 900 F:1x12 9 4 2.0 1.5 0.1 0.05 1800 G:1x2, G:1x4 4 1 1.6 1.6 0.1 0.05 1800 F:1x12 6 2 1.6 1.6 0.1 0.
Radio Base Station RBS 2106 Table 6 Frequency (MHz) Configuration Maximum CDU output power(1) per TRU (dBm)/(W) 48.3 / 67.6 Maximum power into antenna (2) (dBm)/(W) G:1x2 No. TRUs per antenna 1 E-GSM 900 E-GSM 900 G:1x4 2 45 / 31.6 45.0 / 31.7 E-GSM 900 F:1x12 6 46 / 39.8 50.8 / 120 GSM 1800 G:1x2 1 46.8 / 47.9 43.8 / 24.0 GSM 1800 G:1x4 2 43.5 / 22.4 43.5 / 22.4 GSM 1800 F:1x12 6 43 / 20 47.8 / 60 (1) (2) 4.
RBS 2106 Radio Base Station ACCU Climate unit PSU DXU IDM OXU FCU Bias injector DC/DC converter CDU CXU, ASU and OXU dummies dTRU DF AC main switch BFU ADM P008683D Figure 7 RBS 2106 overview 5.1 Standard Hardware Units This section briefly describes the standard hardware units required for function, irrespective of configuration or frequency. ACCU – AC Connection Unit The ACCU connects, disconnects, and distributes the incoming AC power supply to the PSUs and the climate unit.
Radio Base Station RBS 2106 Climate Unit The climate unit maintains the internal temperature and humidity inside the cabinet. The climate unit is mounted in the door of the cabinet. Two types of climate unit are available: • Combined Climate Unit. This unit provides both heating and refrigeration. • Air-to-Air Heat Exchanger climate unit. This provides heating, and cooling through forced convection.
RBS 2106 Radio Base Station DF – Distribution Frame The Distribution Frame (DF) is a connection and overvoltage protection (OVP) device for external alarms and PCM links. The DF protects equipment inside the RBS from overvoltage and overcurrent which may occur in external lines. Examples of equipment requiring OVP include transmission lines, ESBs, external alarms and positioning devices (GPS and LMU). Number of units: 1 DXU-21 – Distribution Switch Unit The DXU-21 is the central control unit for the RBS.
Radio Base Station RBS 2106 IDM – Internal Distribution Module The IDM is a panel for distributing the internal +24 V DC power to the various units. Each distribution circuit in the cabinet is connected to a circuit breaker in the IDM. Number of units: 1 PSU – Power Supply Unit The PSU converts 120 – 250 V to regulated +24 V DC. Number of units: 1 – 4 5.2 Optional Hardware Units This section describes the RBS 2106 optional hardware units.
RBS 2106 Radio Base Station DC/DC Converter The DC/DC converter can supply -48 V DC power to transmission equipment in the TM compartment. It converts +24 V DC to -48 V DC. Number of units: 0 – 2 ddTMA The ddTMA is to be mast-mounted and placed close to the antenna. It improves the receiver sensitivity. The ddTMA saves feeder cables by duplexing RX and TX signals to the same cable. Number of units per cabinet: 0 – 6.
Radio Base Station RBS 2106 Number of units: 0 – 2 6 Interfaces In this section, all external and internal connections are listed, as well as the test interface and the operator interface. All external connectors enter the cabinet through the bottom of the cabinet. Internal connections, test interface and operator interface are located on some cabinet hardware units. . External battery back-up . Customer options Internal Connection Field 3 Transport Module Power System OXU DXU Connection Field 2 .
RBS 2106 Radio Base Station Connection field 3 110 393 274 Transmission connection field 102 543 757 200 710 557 AC mains inlet Antenna connection field 1198 1300 P009697B Figure 9 Cable inlet measurements Connections on Distribution Frame (DF) The DF is a modular construction containing overvoltage arrestors for external alarms and OVP modules for PCM and ESB cables. Overvoltage Arrestors for External Alarms All voltage arrestors, for example external alarms, have space for two alarms.
Radio Base Station RBS 2106 Table 7 Overvoltage arrestors Alarm Connector Alarm 1+ OVP 1, terminal 4 Alarm 1- OVP 1, terminal 3 Alarm 2+ OVP 1, terminal 2 Alarm 2- OVP 1, terminal 1 Alarm 3+ OVP 2, terminal 4 Alarm 3- OVP 2, terminal 3 Alarm 4+ OVP 2, terminal 2 Alarm 4- OVP 2, terminal 1 Alarm 5+ OVP 3, terminal 4 Alarm 5- OVP 3, terminal 3 Alarm 6+ OVP 3, terminal 2 Alarm 6- OVP 3, terminal 1 Alarm 7+ OVP 4, terminal 4 Alarm 7- OVP 4, terminal 3 Alarm 8+ OVP 4, terminal
RBS 2106 Radio Base Station To CDUs (x6) 7-16 Connectors A1 2 3 4 5 6 B1 B8 B7 B6 B2 Antenna sharing connectors B3 B4 B5 N connectors P008714B Figure 10 Antenna connections Table 8 EN/LZT 720 0222 R3A Antenna connections Connection No.
Radio Base Station RBS 2106 Other External Connections Table 9 External connections Connection Connection to Location AC connection AC Mains box connections Type of connector Screw terminal for wires 4 – 16 mm • ACCU AC Service outlet • • Reference Earth Earthing connection IEC 83:1975 standard C 2b (Sweden, Germany and others) IEC 83:1975 standard B2, same as BS 1363:1984 standard 13A (UK) IEC 83:1975 standard A5-15 (USA) M8 screw, 50 mm2 stranded copper wire External connections to TM Optical
RBS 2106 Radio Base Station Indicators Description Bat disconnect Battery disconnected Battery mode Indicates that the RBS is running on battery BS fault One or more faults are detected on RUs in the RBS External alarm One or more supervised external alarms are active Fault Fault detected and localised to the RU Local mode The RU is in local mode Operational The RU is operational Fan Fault A fan is faulty EPC Bus Fault Communication to superior RU is lost RF off No RF antennas TMA 1
Radio Base Station RBS 2106 Buttons Table 10 Switches and circuit breakers Switch Position DXU reset DXU Local/remote DXU, dTRU TRU reset DTRU Battery disconnected BFU DC out BFU DC out 1 BFU DC out 2 BFU EC BFU Mains switch ACCU TMA/no TMA ASU Function Resets the DXU and all subunits Changes mode between local and remote Resets the dTRU Disconnects the battery supply Automatic CB for DC out Automatic CB for DC out 1 Automatic CB for DC out 2 Automatic CB for EC supply Mains switch f
RBS 2106 Radio Base Station AC outlet AC mains External battery ACCU CU DC Filter & OVP ACCU DU Outside RBS cabinet Inside RBS cabinet Internal battery PSUs Climate BFU TM equipment DF IDM DC out Internal DC users P008677D Figure 11 Power system 7.1 Power Supply AC Mains Supply Voltage Single-phase, two-phase or three-phase AC may be used.
Radio Base Station RBS 2106 Mains Fuses Table 12 Mains fuses recommendation Minimum for Safe Function 25 A/40 A (1) (1) 7.2 Recommended for Maximum Selectivity 32 A/50 A(1) Maximum Allowed Fuse Rating 63 A Three-phase/Single phase Battery Back-up Battery back-up is used to power the site during mains failure and also to protect the site from short-term interruptions in the mains supply.
RBS 2106 7.4 Radio Base Station Power Consumption Table 14 Power consumption Climate system Heater plus forced-air cooling only Heater plus refrigerated cooling 8 Power consumption, input voltage >200 V AC Power consumption, input voltage < 120 V AC 5948 W 6049 W 6588 W 6049 W Transmission The RBS 2106 supports two transmission standards: 9 • T1 1.
Radio Base Station 10.2 RBS 2106 • IP 55 according to IEC 60529 • EN 60950 / IEC 60950 • EN 60215 / IEC 60215 • UL 1950 • CSA 22.2 No. 950 Other Standards and Regulations Marking The product is marked with signs to show compliance with product safety standards. Type Approval Standards The RBS complies with the European Community and the North America market requirements regarding radio performance.
RBS 2106 Radio Base Station Vandal Resistance The RBS 2106 fulfils Ericsson’s requirements for vandal resistance.
Radio Base Station Ericsson AB SE-164 80 Stockholm Sweden implementation.GSMsupport@era.ericsson.se 30 (30) RBS 2106 Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
EN/LZT 720 0225 R3A RBS 2206 Radio Base Station Product Description The RBS 2206, a member of the RBS 2000 family, is a 12-TRX radio base station for indoor applications. This cabinet covers the same floor area as the RBS 2202, its predecessor, and boasts double capacity.
Radio Base Station RBS 2206 Contents 2 (24) 1 1.1 1.2 1.3 Product Overview Main Features Variants Optional Equipment 3 3 3 4 2 Dimensions 4 3 Space Requirements 5 4 4.1 4.2 4.3 4.4 Environment Operating Environment Environmental Impact Compliance Distances for Electromagnetic Exposure Materials 7 7 8 8 10 5 5.1 5.2 Hardware Units Standard Hardware Units Optional Hardware Units 11 11 13 6 6.1 6.2 6.3 Interfaces External Connections Test Interface Operator Interface 15 16 17 17 7 7.1 7.
RBS 2206 1 Radio Base Station Product Overview The RBS 2206 is a high-capacity indoor base station. It is used for indoor applications, with up to six double Transceiver Units (dTRU). The RBS 2206 is designed to be transported as a fully-assembled cabinet to the site. All units in the cabinet are easily accessible from the front of the cabinet, which means that the cabinets can be mounted side by side with their backs against a wall. 1.
Radio Base Station RBS 2206 • 1.3 +24 V DC (without PSUs) Optional Equipment The equipment listed below is available, but is not necessary for basic functionality. • ASU • Battery back-up • Bias injectors • DM • dual duplex Tower Mounted Amplifier (ddTMA) Note: 2 For GSM 1800 and GSM 1900 the ddTMA is mandatory equipment.
RBS 2206 3 Radio Base Station Space Requirements In the following sections the required space and recommended floor layout is indicated. 600 2100 1800 1850 250 300 Free Space above the RBS Cabinet 400 P006382B Figure 1 RBS 2206, free space above the cabinet The recommended distance between the cabinet and cable ladder is 250 mm. A shorter distance makes it difficult to exchange fans and may restrict the air flow.
Radio Base Station RBS 2206 Layout for RBS Cabinets RBS BBS RBS RBS 1000 a=130o 1000 Unit of measurement: mm P007781A Figure 2 Floor layout and space requirements The RBS cabinets and BBS racks are mounted on the floor, and may be positioned against a wall, back to back, or free standing without contact with other cabinets. Expansion cabinets and racks can be positioned to the left or to the right of the master cabinet.
RBS 2206 Radio Base Station Footprint o 20x75 45 220 (RBS 2202) 320 400 RBS 2206 FRONT 400 598 99 Unit of measurement: mm P008315A Figure 3 Hole pattern overview The RBS 2206 has the same footprint as the RBS 2202 cabinet. The base frame is used as a template to mark new holes. If an RBS 2202 is being replace by an RBS 2206, the holes for the old cabinet can be used for the new cabinet.
Radio Base Station RBS 2206 Ground Vibrations The RBS 2206 is tested to withstand random vibrations of up to 0.2 m²/s². It is also tested for single shocks up to 40 m/s². The cabinet is tested for seismic exposure with a test frequency of 1 – 35 Hz. Maximum test level of the Required Response Spectrum (RRS) is 50 m/s² within 2 – 5 Hz. The shape of RRS is defined by the ETSI standard.
RBS 2206 Radio Base Station Diameter Distance behind antenna Height Antenna P009694A Figure 4 Compliance boundary cylinder Note: Table 4 shows an example for a typical antenna. As the antenna field distributions will differ for different configurations and environments, complete calculations or measurements may be necessary in order to establish the compliance boundary for other configurations chosen by the customer.
Radio Base Station RBS 2206 Table 5 Characteristics for a typical antenna (KRE 101 1916/1) Antenna specifications X-pol macro RBS sector antenna Antenna height 1.3 m Half-power beam width 60 degrees Antenna gain 14.5 dBi at 900 MHz, 17 dBi at 1800 MHz The maximum power fed to the antenna, as a function of the number of transceiver units (TRUs) per antenna and the maximum power (including tolerances and transmission loss) per TRU, for RBS 2206 at 900 MHz and 1800 MHz, are given in Table 6.
RBS 2206 5 Radio Base Station Hardware Units A high level of availability is achieved using strict functional modularity with a system of standardised units. A failed unit can easily be replaced by a new one. It is possible to add up to three new units in the PSU/DXU magazine. The RBS 2206 cabinet contains the radio equipment, power supply and the climate equipment (fans). All required transmission equipment and battery back-up must be housed outside the cabinet.
Radio Base Station RBS 2206 CDU – Combining and Distribution Unit The CDU is the interface between the transceivers and the antenna system. All signals are filtered before transmission and after reception by means of bandpass filters. The CDU allows several dTRUs to share antennas. There are a maximum of three CDUs in one RBS 2206. The CDU combines transmitted signals from several transceivers, and distributes the received signal to several transceivers. The CDU is hardwareprepared to support EDGE.
RBS 2206 Radio Base Station climate equipment for the RBS. It has a removable compact flashcard which makes it possible to replace a faulty DXU without the need for loading RBS software from the BSC. The DXU is also provided with four connections for transmission lines. It can handle both 2 Mbit (E1) and 1.5 Mbit (T1) PCM links. The DXU has hardware support for EDGE on 12 TRXs. Number of units: 1 FCU – Fan Control Unit The FCU controls the four fans in the cooling system by regulating fan speed.
Radio Base Station RBS 2206 Number of units: 0 – 1 Bias injector The bias injector is used to provide the ddTMA with DC power, from the TMA-CM, over the RX/TX feeder cables. Six bias injectors can be connected to one TMA-CM. The BIAS-IC is mounted outside the cabinet, as close to the RF output as possible. Number of units: 0 – 6 BBS The RBS 2206 can be provided with battery back-up from an external cabinet, either a BBS 2000 or a BBS 2202.
RBS 2206 Radio Base Station TMA-CM – Tower Mounted Amplifier - Control Module The Control Module is used to provide up to six ddTMAs with 15 V DC power through the bias injector. It is also used to identify TMA faults and forward this information to the alarm module in the RBS. The TMA-CM is mounted in an OXU position. Number of units per cabinet: 0 – 2 6 Interfaces In this section all external and internal connections are listed, as well as the test interface and the operator interface.
Radio Base Station 6.1 RBS 2206 External Connections G703-1 G703-2 ACCU/DCCU FCU +24 V DC DC out G703-4 TD G703-3 External Alarms RD DC-Filter-01 ESB-2 ESB-1 CDU P008990A Figure 7 External connectors (shown here with CDU-F) Antenna feeders are directly connected to the CDUs. If bias injectors are used, they are connected directly to the CDU and the antenna feeder is connected to the bias injector.
RBS 2206 Radio Base Station Connection Description Name DCCU 1 – 4 -48 V connection to PSU-DC 1 – 4 ASU 6.2 Antenna sharing connections Connector Type Screw terminal SMA-connector Test Interface The test interface for the RBS 2206 is on the front panel of the DXU-21 unit. The OMT port is used to connect the Operation and Maintenance Tool (OMT) to the RBS. A remote OMT can also be used from the BSC, which sends signals over the Abis interface. 6.
Radio Base Station RBS 2206 External Indicators The RBS 2206 has three indicators on the cabinet door: RBS Fault There is a fault in the RBS. External Battery Mode The RBS is operating on battery power. External Alarm There is at least one external alarm present in the RBS.
RBS 2206 Radio Base Station There are two ways to connect power to the base station. They are: • Single phase line to neutral. • Single phase line to line. Note: Table 9 When single phase line to line is used, each PSU requires two circuit breakers. AC mains power requirements Voltage range for specified Performance (phase voltage) Voltage range 108 – 275 V AC (1) Frequency 45 – 65 Hz Inrush current, max. 30 A (1 – 30 ms) Maximum AC power 1.
Radio Base Station RBS 2206 Mains Fuses Table 10 Mains fuses recommendation Minimum for Safe Function 4x10 A (1)/16 A 1) Recommended for Maximum Selectivity 4x16 A Maximum Allowed Fuse Rating 4x20 A For 200 – 250 V range only. External Earth Fault Circuit Breakers If external earth fault (ground fault) circuit breakers are used, then the recommended minimum trip value is 100 mA. 7.2 +24 V DC Supply Voltage Table 11 DC power requirements Nominal +24 V DC Default +27.2 V DC Range +20.5 – +29.
RBS 2206 Radio Base Station Fuses Table 14 –(48 – 60) V DC fuse recommendation Minimum for Safe Function 4x32 A 7.4 Recommended for Maximum Selectivity 4x35 A Maximum Allowed Fuse Rating 4x40 A Battery Back-up Battery back-up is used to power the site during mains failure and to protect the site from short interruptions in the AC mains supply. It is available in an external cabinet. It is possible to supply external transmission equipment from the battery cabinet.
Radio Base Station RBS 2206 • T1 1.5 Mbit/s, 100 Ω balanced PCM line. • E1 2 Mbit/s, 75 Ω unbalanced (balun used), or 120 Ω balanced line. PCM Overvoltage Module This module contains overvoltage protection for the PCM lines. If the PCM lines are terminated in equipment outside the RBS equipment room, these lines must be protected by overvoltage protectors (OVP) in the DF. Failure to do so might damage the DXU-21, if a voltage transient is transported along the cable.
RBS 2206 Radio Base Station DC. The external alarms are defined during installation using the Operation and Maintenance Terminal (OMT) or from the BSC. 10 Standards, Regulations and Dependability In this section a brief overview of standards, type approval, and electromagnetic compatibility are stated. 10.1 Safety Standards In accordance with the market requirements, the RBS 2206 complies with the following product safety standards: 10.
Radio Base Station RBS 2206 Dependability The RBS 2206 is designed for a technical lifetime of 25 years (24-hour operation). The following preventive maintenance conditions must be fulfilled to guarantee the availability of the RBS: Fans The fans must be inspected (cleaned if necessary) every year. The lifetime is estimated to at least 5 years. Air filters The air filters must be regularly inspected and cleaned (interval depends on the environmental conditions at the site).
EN/LZT 720 0318 Uen R1A RBS 2106 and RBS 2206 Radio Configurations Description This document describes the radio configurations for RBS 2106 and RBS 2206. dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 X TX/ RXA FCOMB TX1 Ant.
Radio Configurations RBS 2106 and RBS 2206 Contents ,QWURGXFWLRQ 1.1 Mobile Telephone System 3 1.2 Radio Base Station 4 5HIHUHQFHV 'HILQLWLRQV 3.1 Cabinet Types 6 3.2 Configurations Identity 7 )UHTXHQF\ %DQGV %DVLF &RQILJXUDWLRQV 5.1 dTRU Topology 10 5.2 CDU-F Configurations 11 5.3 CDU-G Configurations 25 5.4 RX Connection from Antenna to dTRU 52 6LWH &HOO &RQILJXUDWLRQV 6&& 6.1 RBS 2106 and RBS 2206 Configurations 58 6.
RBS 2106 and RBS 2206 1 Radio Configurations Introduction The radio configurations described are valid for RBS 2106 and RBS 2206, equipped with a maximum of six dTRUs/12 TRXs per cabinet. The descriptions include basic configurations, site cell configurations, and co-siting. They also include information about configurations with CDU-G and CDU-F as well as valid GSM frequencies (the GSM 800 configurations are valid from BSS R9). 0RELOH 7HOHSKRQH 6\VWHP PSTN BSS SS BSC RBS 2000 OSS BTS SS Swi
Radio Configurations RBS 2106 and RBS 2206 )LJXUH $Q H[DPSOH RI DQ 5%6 VHUYLFLQJ D WKUHH FHOO VLWH 5DGLR %DVH 6WDWLRQ The Radio Base Station 2000 (RBS 2000) is Ericsson’s second generation of RBSs developed to meet the GSM specifications for BTSs. 2 4 (90) References *60 GSM Requirements 05.05 phase 2+ Radio Transmission and Reception. *60 GSM Requirements 05.08 phase 2+ Radio Subsystem Link Control.
RBS 2106 and RBS 2206 3 Radio Configurations Definitions 7RZHU 0RXQWHG $PSOLILHU 70$ The TMA compensates for signal loss in the receiver antenna cables, reduces system noise and improves uplink sensitivity. The TMA can consist of a duplex filter. Duplex is the function that allows communication in two directions (sending and receiving) on one channel. The TMA used for 12 TRX products is Dual Duplex TMA (ddTMA). Some configurations can use a TMA designed for reception only (rTMA).
Radio Configurations RBS 2106 and RBS 2206 %DVH 7UDQVFHLYHU 6WDWLRQ %76 A BTS is a unit operating on a set of frequencies in one cell. %DVLF &RQILJXUDWLRQ A basic configuration is a specified set of transceivers, CDUs, and in some cases, TMAs, connected to one antenna system. A basic configuration can be multiplied or used in combination with other basic configurations to build the needed site equipment. Variations of a basic configuration may exist, differing in cable lengths.
RBS 2106 and RBS 2206 Radio Configurations &RQILJXUDWLRQV ,GHQWLW\ The figure below shows how a basic configuration identity is constructed. G9dht_3.6(5)\a Variant indication, lower case letter a-z Number of used transceivers Max number of transceivers Number of antennas dd TMA used Hybrid in dTRU; used Duplexer in CDU; used Frequency band CDU-type P007365B )LJXUH EN/LZT 720 0318 Uen R1A %DVLF FRQILJXUDWLRQ LGHQWLW\ 7 (90)
Radio Configurations 4 RBS 2106 and RBS 2206 Frequency Bands GSM 800 P-GSM 900 E-GSM 900 GSM 1800 GSM 1900 Uplink: 824 – 849 MHz Downlink: 869 – 894 MHz Uplink: 890 – 915 MHz Downlink: 935 – 960 MHz Uplink: 880 – 915 MHz Downlink: 925 – 960 MHz Uplink: 1710 – 1785 MHz Downlink: 1805 – 1880 MHz Uplink: 1850 – 1910 MHz Downlink: 1930 – 1990 MHz These frequency bands are supported by the configurations described in this document.
RBS 2106 and RBS 2206 5 Radio Configurations Basic Configurations The GSM 800, GSM 900, GSM 1800 and GSM 1900 configurations meet the GSM requirements, except where otherwise stated. The capacity of a configuration is defined at the TX and RX antenna reference points at the RBS border. There is an X close to every reference point in the following figures. The RBS border is not included in the figures.
Radio Configurations RBS 2106 and RBS 2206 G758 7RSRORJ\ &RQILJXUDWLRQ RI +\EULG &RPELQHU The dTRU can be configured with or without the hybrid combiner, using two external cables. 5; 6LJQDOV 'LVWULEXWHG IURP 7ZR 3RUWV The RX signals can be distributed from the RX1 and RX2 ports to all four receivers when both transceivers are connected to the same antenna system.
RBS 2106 and RBS 2206 Radio Configurations &'8 ) &RQILJXUDWLRQV %DVLF &RQILJXUDWLRQ ) GB DQG ) GB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 X TX/ RXA FCOMB TX1 Ant. RX1 RX2 RX1 TX2 RX2 LNA RXB LNA X CXU P007376A )LJXUH ) GB DQG ) GB &KDUDFWHULVWLFV Number of CDUs 1 Frequency band E-GSM (F9d_2.4) GSM 1800 (F18d_2.4) Max.
Radio Configurations RBS 2106 and RBS 2206 %DVLF &RQILJXUDWLRQ ) GWB DQG ) GWB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU TX2 DPX DPX TX1 TX2 LNA DPX X TX/ RXA FCOMB TX1 RX1 Ant. RX2 RX1 TX2 RX2 LNA RXB LNA DPX LNA DPX X CXU P007377A )LJXUH ) GWB DQG ) GWB &KDUDFWHULVWLFV 12 (90) Number of CDUs 1 Frequency band E-GSM (F9dt_2.4) GSM 1800 (F18dt_2.4) Max.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ ) GB DQG ) GB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 X TX/ RXA FCOMB TX1 Ant. RX1 RX2 RX1 TX2 RX2 LNA LNA X RXB dTRU TX1 RX1 dTRU RX2 TX1 TX2 TX2 TX1 TX1 RX1 TX2 RX2 CDU-F FCOMB BTS1 BTS2 FCOMB TX2 CDU-F TX1 dTRU TX1 RX1 TX2 FCOMB RX2 dTRU DPX TX1 TX2 TX2 X TX/ RXA FCOMB TX1 Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2* Frequency band E-GSM (F9d_2.6) GSM 1800 (F18d_2.6) Max. number of TRXs 6 Number of feeders 2 Number of antennas 2 Antenna configuration TX/RX + RX * Three CDU-Fs support two sectors. 1RWH 14 (90) The second BTS is only shown to illustrate a 2 x 6 configuration. BTS1 and BTS2 are two different physical implementations of the same basic configuration.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ ) GWB DQG ) GWB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 DPX LNA DPX X DPX LNA DPX X TX/ RXA FCOMB TX1 RX1 RX2 RX1 TX2 RX2 LNA LNA RXB dTRU TX1 RX1 dTRU RX2 TX1 TX2 TX2 TX1 TX1 RX1 TX2 RX2 CDU-F FCOMB BTS1 BTS2 FCOMB TX2 CDU-F TX1 dTRU TX1 RX1 TX2 FCOMB RX2 dTRU DPX TX1 TX2 TX2 DPX LNA DPX X DPX LNA DPX X TX/ RXA FCOMB TX1 RX1 RX2 RX1 TX2 RX2 LNA LNA RXB CXU P0
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2* Frequency band E-GSM (F9dt_2.6) GSM 1800 (F18dt_2.6) Max. number of TRXs 6 Number of feeders 2 Number of antennas 2 Antenna configuration TX/RX + RX TMA configuration ddTMA + ddTMA or ddTMA + rTMA * Three CDU-Fs support two sectors. 1RWH 16 (90) The second BTS is only shown to illustrate a 2 x 6 configuration. BTS1 and BTS2 are two different physical implementations of the same basic configuration.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ ) GB DQG ) GB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 X TX/ RXA FCOMB TX1 RX1 RX1 RX2 LNA TX2 Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV 18 (90) Number of CDUs 2 Frequency band E-GSM (F9d_2.8) GSM 1800 (F18d_2.8) Max.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ ) GWB DQG ) GWB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 DPX LNA DPX TX/ RXA X FCOMB TX1 Ant. RX1 RX1 RX2 LNA TX2 dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 dTRU DPX TX1 TX2 TX2 DPX LNA DPX TX/ RXB X FCOMB TX1 Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV 20 (90) Number of CDUs 2 Frequency band E-GSM (F9dt_2.8) GSM 1800 (F18dt_2.8) Max.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ ) GB DQG ) GB CXU dTRU TX1 RX2 dTRU CDU-F RX1 TX1 TX2 TX2 TX1 TX1 RX1 TX2 FCOMB DPX X TX/ RXA Ant. FCOMB RX2 TX2 dTRU dTRU RX1 LNA TX1 RX1 RX2 TX1 TX2 TX2 TX1 TX1 RX1 TX2 CDU-F FCOMB FCOMB RX2 TX2 dTRU dTRU TX1 CDU-F RX1 RX2 TX1 TX2 TX2 TX1 TX1 RX1 TX2 FCOMB FCOMB RX2 TX2 RX1 TX/ RXB DPX X Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV 22 (90) Number of CDUs 3 Frequency band E-GSM (F9d_2.12) GSM 1800 (F18d_2.12) Max.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ ) GWB DQG ) GWB dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB RX2 TX1 TX2 dTRU DPX TX2 DPX LNA DPX TX/ RXA X FCOMB TX1 Ant. RX1 RX1 RX2 LNA TX2 dTRU TX1 RX1 dTRU RX2 TX1 TX2 TX2 TX1 TX1 RX1 TX2 RX2 CDU-F FCOMB FCOMB TX2 dTRU TX1 TX1 RX1 TX2 CDU-F FCOMB TX/ RXB RX2 TX1 TX2 dTRU DPX TX2 DPX LNA DPX X FCOMB TX1 Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV 24 (90) Number of CDUs 3 Frequency band E-GSM (F9dt_2.12) GSM 1800 (F18dt_2.12) Max.
RBS 2106 and RBS 2206 Radio Configurations &'8 * &RQILJXUDWLRQV %DVLF &RQILJXUDWLRQ * GB * GB * GB DQG * GB Ant S2 Ant S1 dTRU TX1 TX1 CDU-G RX1 RX1 RX2 LNA DPX X RX3 TX/ RXA Ant. RX4 TX2 TX2 RX2 LNA DPX X RXB CDU-G RX1 LNA TX/ RXA DPX X Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2 (2 CDUs support two sectors) Frequency band GSM 800 (G8d_2.1) E-GSM (G9d_2.1) GSM 1800 (G18d_2.1) GSM 1900 (G19d_2.1) Max. number of TRXs 1 (1 dTRU supports two sectors) Number of feeders 2 Number of antennas 2 Antenna configuration TX/RX + RX 1RWH 26 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GWB * GWB * GWB DQG * GWB Ant S2 Ant S1 dTRU TX1 TX1 CDU-G RX1 RX1 RX2 LNA DPX DPX LNA DPX X RX3 RX4 TX2 Ant. ddTMA TX2 RX2 LNA DPX DPX LNA TX/ RXA DPX X TX/ RXA ddTMA CDU-G RX1 LNA RXB DPX DPX LNA DPX X Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2 (2 CDUs support two sectors) Frequency band GSM 800 (G8dt_2.1) E-GSM (G9dt_212) GSM 1800 (G18dt_2.1) GSM 1900 (G19dt_2.1) Max. number of TRXs 1 (1 dTRU supports two sectors) Number of feeders 2 Number of antennas 2 Antenna configuration TX/RX + RX TMA configuration ddTMA + ddTMA 1RWH 28 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GB * GB * GB DQG * GB Ant S1(3,5) TX1 TX1 RX1 RX1 LNA DPX X RX2 TX/ RXA Ant. TX2 TX2 RX2 dTRU CXU ASU LNA DPX X TX/ RXB CDU-G Ant S2(4,6) P007384B )LJXUH *G B * GB * GB DQG * GB &KDUDFWHULVWLFV Number of CDUs 1 Frequency band GSM 800 (G8d_2.2) E-GSM (G9d_2.2) GSM 1800 (G18d_2.2) GSM 1900 (G19d_2.2) Max.
Radio Configurations RBS 2106 and RBS 2206 %DVLF &RQILJXUDWLRQ * GWB * GWB * GWB DQG * GWB Ant S1(3,5) TX1 TX1 RX1 RX1 DPX LNA DPX LNA DPX X RX2 TX/ RXA Ant. TX2 TX2 RX2 dTRU CXU ASU DPX LNA DPX CDU-G LNA DPX X TX/ RXB ddTMA Ant S2(4,6) P007385B )LJXUH * GWB * GWB * GWB DQG * GWB &KDUDFWHULVWLFV Number of CDUs 1 Frequency band GSM 800 (G8dt_2.2) E-GSM (G9dt_2.2) GSM 1800 (G18dt_2.2) GSM 1900 (G19dt_2.2) Max.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GB * GB * GB DQG * GB Ant S1 (3) dTRU TX1 CDU-G TX1 RX1 RX1 RX2 LNA DPX X TX/ RXA Ant. TX2 TX2 LNA dTRU TX1 TX1 CDU-G RX1 RX1 LNA DPX DPX TX X X RX2 TX/ RXB Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2 Frequency band GSM 800 (G8d_4.4) E-GSM (G9d_4.4) GSM 1800 (G18d_4.4) GSM 1900 (G19d_4.4) Max. number of TRXs 4 Number of feeders 4 Number of antennas 4 Antenna configuration TX/RX + TX + TX/RX + TX 1RWH 32 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GWB * GWB * GWB DQG * GWB Ant S1 (3) dTRU TX1 TX1 CDU-G RX1 RX1 RX2 LNA DPX DPX LNA DPX X Ant. ddTMA TX2 TX2 LNA dTRU TX1 TX1 CDU-G RX1 RX1 LNA DPX TX/ RXA TX X DPX DPX LNA DPX X TX/ RXB RX2 ddTMA Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2 Frequency band GSM 800 (G8dt_4.4) E-GSM (G9dt_4.4) GSM 1800 (G18dt_4.4) GSM 1900 (G19dt_4.4) Max. number of TRXs 4 Number of feeders 4 Number of antennas 4 Antenna configuration TX/RX + TX + TX/RX + TX TMA configuration ddTMA + ddTMA 1RWH 34 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GB * GB * GB DQG * GB Ant S1 dTRU TX1 CDU-G TX1 RX1 RX1 RX2 LNA DPX X TX/ RXA Ant. TX2 TX2 LNA dTRU TX1 TX1 CDU-G RX1 LNA DPX TX X TX DPX X RX2 Ant. TX2 TX TX2 LNA dTRU TX1 TX1 CDU-G RX1 RX1 LNA DPX DPX X X RX2 TX/ RXB Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 3 Frequency band GSM 800 (G8d_6.6) E-GSM (G9d_6.6) GSM 1800 (G18d_6.6) GSM 1900 (G19d_6.6) Max. number of TRXs 6 Number of feeders 6 Number of antennas 6 Antenna configuration TX/RX + TX + TX + TX + TX/RX + TX 1RWH 36 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GWB * GWB * GWB DQG * GWB Ant S1 dTRU TX1 TX1 CDU-G RX1 RX1 RX2 LNA DPX DPX LNA DPX X Ant. ddTMA TX2 TX2 LNA dTRU TX1 TX1 CDU-G RX1 LNA DPX TX/ RXA TX X TX DPX X RX2 Ant. TX2 TX TX2 LNA dTRU TX1 TX1 CDU-G RX1 RX1 LNA DPX X DPX DPX LNA DPX X TX/ RXB RX2 ddTMA Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 3 Frequency band GSM 800 (G8dt_6.6) E-GSM (G9dt_6.6) GSM 1800 (G18dt_6.6) GSM 1900 (G19dt_6.6) Max. number of TRXs 6 Number of feeders 6 Number of antennas 6 Antenna configuration TX/RX + TX + TX + TX + TX/RX + TX TMA configuration ddTMA + ddTMA 1RWH 38 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKB * GKB * GKB DQG * GKB Ant S1(3,5) dTRU TX1+TX2 TX1 RX1 CDU-G RX1 LNA DPX X TX/ RXA RX2 Ant. TX1+ dTRU TX2 TX2 RX1 RX2 LNA RX2 DPX X TX/ RXB ASU CXU Ant S2(4,6) P007386B )LJXUH * GKB * GKB * GKB DQG * GKB &KDUDFWHULVWLFV Number of CDUs 1 Frequency band GSM 800 (G8dh_2.4) E-GSM (G9dh_2.4) GSM 1800 (G18dh_2.4) GSM 1900 (G19dh_2.4) Max.
Radio Configurations RBS 2106 and RBS 2206 %DVLF &RQILJXUDWLRQ * GKWB * GKWB * GKWB DQG * GKWB Ant S1(3,5) dTRU TX1+TX2 TX1 RX1 RX1 CDU-G DPX LNA DPX LNA DPX X RX2 TX/ RXA Ant. TX1+ dTRU TX2 TX2 RX1 RX2 RX2 CXU DPX LNA DPX LNA DPX X TX/ RXB ddTMA ASU Ant S2(4,6) P007387B )LJXUH * GKWB * GKWB * GKWB DQG * GKWB &KDUDFWHULVWLFV Number of CDUs 1 Frequency band GSM 800 (G8dht_2.4) E-GSM (G9dht_2.4) GSM 1800 (G18dht_2.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKB * GKB * GKB DQG * GKB Ant S2 Ant S1 dTRU TX1+TX2 TX1 CDU-G RX1 RX1 RX2 LNA DPX TX/ RXA X Ant. dTRU TX1+ TX2 TX2 RX1 RX2 RX2 dTRU TX1+ TX2 LNA DPX TX/ RXB X TX TX1 CDU-G RX1 LNA RX2 DPX X Ant. BTS1 TX1+ dTRU TX2 RX1 LNA RX2 dTRU BTS2 TX2 TX1+ TX2 DPX X DPX X TX1 CDU-G RX1 RX1 RX2 LNA TX TX/ RXA Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2* Frequency band GSM 800 (G8dh_3.6) E-GSM (G9dh_3.6) GSM 1800 (G18dh_3.6) GSM 1900 (G19dh_3.6) Max. number of TRXs 6 Number of feeders 3 Number of antennas 3 Antenna configuration TX/RX + TX/RX + TX * Three CDU-Gs support two sectors. 42 (90) 1RWH The second BTS is only shown to illustrate a 2 x 6 configuration. BTS1 and BTS2 are two different physical implementations of the same basic configuration.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKWB * GKWB * GKWB DQG * GKWB Ant S2 Ant S1 dTRU TX1+TX2 TX1 CDU-G RX1 RX1 RX2 LNA DPX DPX LNA DPX X TX/ RXA Ant. dTRU TX1+ TX2 TX2 RX1 RX2 RX2 LNA DPX DPX LNA DPX X TX/ RXB ddTMA TX1+ TX2 dTRU TX1 CDU-G RX1 LNA RX2 X Ant. BTS1 TX1+ dTRU TX2 BTS2 TX2 RX1 LNA RX2 dTRU TX DPX TX1+ TX2 TX1 CDU-G RX1 RX1 RX2 LNA DPX DPX TX X DPX LNA DPX X TX/ RXA Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2* Frequency band GSM 800 (G8dht_3.6) E-GSM (G9dht_3.6) GSM 1800 (G18dht_3.6) GSM 1900 (G19dht_3.6) Max. number of TRXs 6 Number of feeders 3 Number of antennas 3 Antenna configuration TX/RX + TX/RX + TX TMA configuration ddTMA + ddTMA * Three CDU-Gs support two sectors. 44 (90) 1RWH The second BTS is only shown to illustrate a 2 x 6 configuration.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKB * GKB * GKB DQG * GKB Ant S1(3) dTRU TX1+TX2 TX1 RX1 RX1 TX/ RXB CDU-G LNA DPX X RX2 Ant. TX1+ dTRU TX2 RX1 LNA RX2 dTRU TX TX2 TX1+ TX2 TX1 RX1 RX1 DPX X TX/ RXB CDU-G LNA DPX X RX2 Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2 Frequency band GSM 800 (G8dh_4.8) E-GSM (G9dh_4.8) GSM 1800 (G18dh_4.8) GSM 1900 (G19dh_4.8) Max. number of TRXs 8 Number of feeders 4 Number of antennas 4 Antenna configuration TX/RX + TX + TX/RX + TX 1RWH 46 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKWB * GKWB * GKWB DQG * GKWB Ant S1(3) dTRU TX1+TX2 TX1 RX1 RX1 CDU-G LNA DPX DPX LNA DPX X TX/ RXA RX2 Ant. ddTMA TX1+ dTRU TX2 RX1 LNA RX2 dTRU TX TX2 TX1+ TX2 TX1 RX1 RX1 DPX X CDU-G LNA DPX DPX LNA RX2 ddTMA TX1+ dTRU TX2 LNA RX2 CXU X Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 2 Frequency band GSM 800 (G8dht_4.8) E-GSM (G9dht_4.8) GSM 1800 (G18dht_4.8) GSM 1900 (G19dht_4.8) Max. number of TRXs 8 Number of feeders 4 Number of antennas 4 Antenna configuration TX/RX + TX + TX/RX + TX TMA configuration ddTMA + ddTMA 1RWH 48 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKB * GKB * GKB DQG * GKB Ant S1 dTRU TX1+TX2 TX1 CDU-G RX1 RX1 RX2 TX1+ dTRU TX2 RX1 LNA DPX TX/ RXA X TX2 TX LNA RX2 TX1+ dTRU TX2 DPX X TX1 CDU-G RX1 LNA RX2 TX DPX X Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 3 Frequency band GSM 800 (G8dh_6.12) E-GSM (G9dh_6.12) GSM 1800 (G18dh_6.12) GSM 1900 (G19dh_6.12) Max. number of TRXs 12 Number of feeders 6 Number of antennas 6 Antenna configuration 2 x TX/RX + 4 x TX 1RWH 50 (90) The ASU is optional equipment.
RBS 2106 and RBS 2206 Radio Configurations %DVLF &RQILJXUDWLRQ * GKWB * GKWB * GKWB DQG * GKWB Ant S1 dTRU TX1+TX2 TX1 RX1 RX1 RX2 CDU-G LNA DPX DPX LNA DPX X TX/ RXA ddTMA TX1+ dTRU TX2 RX1 TX2 TX LNA RX2 TX1+ dTRU TX2 RX1 TX1 X CDU-G LNA RX2 DPX TX DPX X Ant.
Radio Configurations RBS 2106 and RBS 2206 &KDUDFWHULVWLFV Number of CDUs 3 Frequency band GSM 800 (G8dht_6.12) E-GSM (G9dht_6.12) GSM 1800 (G18dht_6.12) GSM 1900 (G19dht_612) Max. number of TRXs 12 Number of feeders 6 Number of antennas 6 Antenna configuration 2 x TX/RX + 4 x TX TMA configuration ddTMA + ddTMA 1RWH The ASU is optional equipment. 5; &RQQHFWLRQ IURP $QWHQQD WR G758 Connection in the RX path is performed using the CXU.
RBS 2106 and RBS 2206 Radio Configurations 7DEOH [ FRPELQHG DQG [ XQFRPELQHG FRQILJXUDWLRQV ZLWK &'8 * &'8 $QWHQQD 6KDULQJ &RQQHFWRU 1R &RQQHFWRU &R VLWLQJ RQO\ 70$ $QWHQQD 1R 70$ FRQILJ RQO\ 1 / TX/RX1 1 1 TX/RXA 3 / TX/RX1 5 5 TX/RXB 7DEOH &HOO 1 2 3 7DEOH &HOO 1 2 EN/LZT 720 0318 Uen R1A FRQILJXUDWLRQV ZLWK &'8 * &'8 $QWHQQD 6KDULQJ &RQQHFWRU 70$ $QWHQQD 1R &RQQHFWRU &R VLWLQJ RQO\ 1 / TX/RX1 1 1 TX/RXA 2 / TX/RX1 3 3 RXB 1 / TX/RX2
Radio Configurations RBS 2106 and RBS 2206 7DEOH &HOO 1 2 7DEOH &HOO 1 2 3 54 (90) [ FRQILJXUDWLRQV ZLWK &'8 * &'8 $QWHQQD 6KDULQJ &RQQHFWRU 70$ $QWHQQD 1R &RQQHFWRU &R VLWLQJ RQO\ 1R 70$ FRQILJ RQO\ 1 / TX/RX1 1 1 TX/RXA 1 / TX/RX2 2 2 TX/RXB 3 / TX/RX1 5 5 TX/RXA 3 / TX/RX2 6 6 TX/RXB [ FRQILJXUDWLRQV ZLWK &'8 ) &'8 70$ $QWHQQD 1R &RQQHFWRU 1R 70$ FRQILJ RQO\ 1 / TX/RX 1 TX/RXA 1 / RX 2 RXB 2 / TX/RX 3 TX/RXA 2 / RX 4 RXB 3 / TX/RX 5 T
RBS 2106 and RBS 2206 Radio Configurations 7DEOH &HOO 1 2 3 7DEOH &HOO 1 Alt. 1 EN/LZT 720 0318 Uen R1A [ FRPELQHG DQG [ XQFRPELQHG FRQILJXUDWLRQV ZLWK &'8 * &'8 $QWHQQD 6KDULQJ &RQQHFWRU 70$ $Q WHQQD 1R &RQQHFWRU &R VLWLQJ RQO\ 1R 70$ FRQILJ RQO\ 1 / TX/RX1 1 1 TX/RXA 1 / TX/RX2 2 2 TX/RXB 2 / TX/RX1 3 3 TX/RXA 2 / TX/RX2 4 4 TX/RXB 3 / TX/RX1 5 5 TX/RXA 3 / TX/RX2 6 6 TX/RXB [ FRQILJXUDWLRQV ZLWK &'8 ) &'8 70$ $QWHQQD 1R &RQQHFWRU 1R 70$
Radio Configurations RBS 2106 and RBS 2206 7DEOH &HOO 1 Alt.1 1RWH 56 (90) [ FRPELQHG DQG [ XQFRPELQHG FRQILJXUDWLRQV ZLWK &'8 * &'8 $QWHQQD 6KDULQJ &RQQHFWRU 70$ $QWHQQD 1R &RQQHFWRU &R VLWLQJ RQO\ 1R 70$ FRQILJ RQO\ 1 / TX/RX1 1 1 TX/RXA 2 / TX/RX1 3 3 TX/RXB 2 / TX/RX1 3 3 TX/RXA 3 / TX/RX1 5 5 TX/RXB It is only possible to have one 1 x 8 configuration in the cabinet. One 1 x 8 configuration can be combined with one 1 x 4 configuration.
RBS 2106 and RBS 2206 6 Radio Configurations Site Cell Configurations (SCC) The following section shows SCCs in one RBS. More RBSs can be combined to form larger configurations at a site. Possible expansions, where different RBSs are connected using TG-synchronization, are described in 6HFWLRQ RQ SDJH . The following SCCs are supported by the RBS: • specified basic radio configurations • the RBS with any number of dTRUs within the specified range inserted in the specified position order.
Radio Configurations RBS 2106 and RBS 2206 5%6 DQG 5%6 &RQILJXUDWLRQV &'8 ) 6LQJOH %DQG &RQILJXUDWLRQV 7DEOH &'8 ) FRQILJXUDWLRQV ZLWK D IXOO\ HTXLSSHG FDELQHW 6&& 1 x 12 2x6 3x4 1x8+1x4 1x4+1x8 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU F9d_2.12 No N/A N/A 2 N/A F9dt_2.12 M N/A N/A 2 F18d_2.12 No N/A N/A F18dt_2.12 M N/A 2 x F9d_2.6 No 2 x F9dt_2.
RBS 2106 and RBS 2206 Radio Configurations N/A = Not Applicable The following configurations are also possible: 6&& [ SCC 1 x 2 can be achieved as a subset of SCC 3 x 4 or 2 x 6. It requires one CDU-F. 6&& [ SCC 2 x 2 can be achieved as a subset of SCC 3 x 4 or 2 x 6. It requires two CDU-Fs. 6&& [ SCC 2 x 4 can be achieved as a subset of SCC 3 x 4 or 2 x 6. It requires two CDU-Fs. 6&& [ SCC 3 x 2 can be achieved as a subset of SCC 3 x 4. It requires three CDU-Fs.
Radio Configurations 7DEOH 6&& 1x4 2x4 1x8 RBS 2106 and RBS 2206 &'8 ) FRQILJXUDWLRQV ZLWK D SDUWO\ HTXLSSHG FDELQHW 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU F9d_2.4 No No No 2 0 0 0–2 0 0 F9dt_2.4 M M M 2 0 0 0–2 0 0 F18d_2.4 No No No 2 0 0 0–2 0 0 F18dt_2.4 M M M 2 0 0 0–2 0 0 2 x F9d_2.4 No No No 2 2 0 0–2 0–2 0 2 x F9dt_2.
RBS 2106 and RBS 2206 Radio Configurations &'8 * 6LQJOH %DQG &RQILJXUDWLRQV ZLWKRXW +\EULG &RPELQHU 7DEOH 6&& 3x2 &'8 * FRQILJXUDWLRQV ZLWKRXW K\EULG FRPELQHU LQ D IXOO\ RU SDUWO\ HTXLSSHG FDELQHW 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU 3 x G8d_2.2 No No No 2 2 2 0–1 0–1 0–1 3 x G8dt_2.2 M M M 2 2 2 0–1 0–1 0–1 3 x G9d_2.2 No No No 2 2 2 0–1 0–1 0–1 3 x G9dt_2.
Radio Configurations 7DEOH 6&& RBS 2106 and RBS 2206 &'8 * FRQILJXUDWLRQV ZLWKRXW K\EULG FRPELQHU LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ &RQILJXUDWLRQ 70$ 1RXPEHU RI $QWHQQDV $OORZHG 1R RI G758V &HOO RU 6HFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU 1+1 2 x G8d_2.1 No No No 2 2 0 0 or 1 0 0 2 x G8dt_2.1 M M M 2 2 0 0 or 1 0 0 2 x G9d_2.1 No No No 2 2 0 0 or 1 0 0 2 x G9dt_2.1 M M M 2 2 0 0 or 1 0 0 2 x G18d_2.
RBS 2106 and RBS 2206 7DEOH 6&& Radio Configurations &'8 * FRQILJXUDWLRQV ZLWKRXW K\EULG FRPELQHU LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ &RQILJXUDWLRQ 70$ 1RXPEHU RI $QWHQQDV $OORZHG 1R RI G758V &HOO RU 6HFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU 1x2 1x4 2x2 G8d_2.2 No No No 2 0 0 0 or 1 0 0 G8dt_2.2 M M M 2 0 0 0 or 1 0 0 G9d_2.2 No No No 2 0 0 0 or 1 0 0 G9dt_2.2 M M M 2 0 0 0 or 1 0 0 G18d_2.
Radio Configurations RBS 2106 and RBS 2206 N/A = Not Applicable 1) ‘‘0’’ in these columns indicates that antennas can be added if the site is expanded with more sectors. 2) ‘‘0’’ in these columns indicates that space exists in the cabinet for future site expansion. 3) 64 (90) It is possible to mix cells with TMA and cells without TMA at the same site.
RBS 2106 and RBS 2206 Radio Configurations &'8 * 6LQJOH %DQG &RQILJXUDWLRQ ZLWK +\EULG &RPELQHU 7DEOH 6&& 3x4 &'8 * FRQILJXUDWLRQV ZLWK K\EULG FRPELQHU LQ D IXOO\ RU SDUWO\ HTXLSSHG FDELQHW 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU 6HFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU 3 x G8dh_2.4 No No No 2 2 2 0–2 0–2 0–2 3 x G8dht_2.4 M M M 2 2 2 0–2 0–2 0–2 3 x G9dh_2.4 No No No 2 2 2 0–2 0–2 0–2 3 x G9dht_2.
Radio Configurations RBS 2106 and RBS 2206 N/A = Not Applicable 1) It is possible to mix cells with TMA and cells without TMA at the same site. The following configurations are also possible: 66 (90) 6&& [ This can be achieved as a subset of SCC 3 x 4. It requires one CDU-G. 6&& [ This can be achieved as a subset of SCC 3 x 4. It requires two CDU-Gs. 6&& [ This can be achieved as a subset of SCC 3 x 4. It requires three CDU-Gs.
RBS 2106 and RBS 2206 7DEOH 6&& 1x4 2x4 &'8 * FRQILJXUDWLRQV ZLWK K\EULG FRPELQHU LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWLRQ &HOO RU VHFWLRQ &HOO RU VHFWLRQ G8dh_2.4 No No No 2 0 0 0–2 0 0 G8dht_2.4 M M M 2 0 0 0–2 0 0 G9dh_2.4 No No No 2 0 0 0–2 0 0 G9dht_2.4 M M M 2 0 0 0–2 0 0 G18dh_2.4 No No No 2 0 0 0–2 0 0 G18dht_2.
Radio Configurations RBS 2106 and RBS 2206 1) ‘‘0’’ in these columns indicates that antennas can be added if the site is expanded with more sectors. 2) ‘‘0’’ in these columns indicates that space exists in the cabinet for future site expansion. 3) It is possible to mix cells with TMA and cells without TMA at the same site.
RBS 2106 and RBS 2206 Radio Configurations &'8 ) &RQILJXUDWLRQV IRU *60 DQG *60 7DEOH 6&& 1x4 | 1x8 1x8 | 1x4 1x4 | 2x4 2x4 | 1x4 'XDO EDQG FRQILJXUDWLRQV ZLWK &'8 ) LQ D IXOO\ RU SDUWO\ HTXLSSHG FDELQHW )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQ QDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU F9d_2.4 | F18d_2.8 900 1800 — F9dt_2.4 | F18dt_2.8 900 1800 F9d_2.8 | F18d_2.4 900 F9dt_2.8 | F18dt_2.
Radio Configurations 7DEOH 6&& 1x4 | 1x4 RBS 2106 and RBS 2206 'XDO EDQG FRQILJXUDWLRQV ZLWK &'8 ) LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU F9d_2.4 | F18d_2.4 900 1800 — No No — 2 2 — 0–2 0–2 — F9dt_2.4 | F18dt_2.
RBS 2106 and RBS 2206 Radio Configurations &'8 * &RQILJXUDWLRQV IRU *60 DQG *60 7DEOH 6&& 1x8 | 1x4 1x4 | 1x8 2x4 | 1x4 1x4 | 2x4 'XDO EDQG FRQILJXUDWLRQV &'8 * ZLWK K\EULG LQ D IXOO\ RU SDUWO\ HTXLSSHG FDELQHW )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU G9dh_4.8 | G18dh_2.4 900 1800 — G9dht_4.8 | G18dht_2.4 900 1800 G9dh_2.4 | G18dh_4.8 900 G9dht_2.4 | G18dht_4.
Radio Configurations 7DEOH 6&& 1x4 | 1x4 RBS 2106 and RBS 2206 'XDO EDQG FRQILJXUDWLRQV &'8 * ZLWK K\EULG LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU G9dh_2.4 | G18dh_2.4 900 1800 — No G9dht_2.4 | G18dht_2.
RBS 2106 and RBS 2206 Radio Configurations &'8 * &RQILJXUDWLRQV IRU *60 DQG *60 7DEOH 6&& 1x8 | 1x4 1x4 | 1x8 2x4 | 1x4 1x4 | 2x4 'XDO EDQG FRQILJXUDWLRQV &'8 * ZLWK K\EULG LQ D IXOO\ RU SDUWO\ HTXLSSHG FDELQHW )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU G8dh_4.8 | G18dh_2.4 800 1800 — No No — 4 2 — 0–4 0–2 — G8dht_4.8 | G18dht_2.
Radio Configurations 7DEOH 6&& 1x4 | 1x4 RBS 2106 and RBS 2206 'XDO EDQG FRQILJXUDWLRQV &'8 * ZLWK K\EULG LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU &HOO RU VHFWRU G8dh_2.4 | G18dh_2.4 800 1800 — No G8dht_2.4 | G18dht_2.
RBS 2106 and RBS 2206 Radio Configurations &'8 * &RQILJXUDWLRQV IRU *60 DQG *60 7DEOH 6&& 1x8 | 1x4 1x4 | 1x8 2x4 | 1x4 1x4 | 2x4 'XDO EDQG FRQILJXUDWLRQV &'8 * ZLWK K\EULG LQ D IXOO\ DQG SDUWO\ HTXLSSHG FDELQHW )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU 6HFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU G8dh_4.8 | G19dh_2.4 800 1900 — No No — 4 2 — 0–4 0–2 — G8dht_4.8 | G19dht_2.
Radio Configurations 7DEOH 6&& 1x4 | 1x4 RBS 2106 and RBS 2206 'XDO EDQG FRQILJXUDWLRQV &'8 * ZLWK K\EULG LQ D SDUWO\ HTXLSSHG FDELQHW RQO\ )UHTXHQF\ %DQG 70$ 1XPEHU RI $QWHQQDV $OORZHG 1XPEHU RI G758V &HOO RU VHFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU &HOO RU 6HFWRU 1 2 1 G8dh_2.4 | G19dh_2.4 800 1900 — G8dht_2.4 | G19dht_2.
RBS 2106 and RBS 2206 • Radio Configurations The configurations have TRX connected to different antennas in the same antenna system. One possible application using SPB together with hybrid combiner is creating overlaid and underlaid cells during cell planning, as described below: 1 One underlaid cell consists of the second TRX in the first dTRU and the first TRX in the second dTRU. SPB is used in this cell. 2 One overlaid cell consists of the two other TRXs. SPB is not used in this cell.
Radio Configurations 7 RBS 2106 and RBS 2206 Co-Siting with RBS 200 or RBS 2000 Macro Cabinets This section shows expansions where RBSs, forming an original SCC, are co-sited and use TG-synchronization to form one new resulting SCC. Antennas are not shared.
RBS 2106 and RBS 2206 7DEOH Radio Configurations ([SDQVLRQ XVLQJ ILOWHU FRPELQHU 5H VXOW 6&& 2ULJLQDO &RQILJXUDWLRQ 2ULJ LQDO 6&& &DEL QHW &RPEL QHU $QWHQ QDV 70$ 2ULJ LQDO 6&& %DVLF &RQILJX UDWLRQ $QWHQQDV 1 x 16 * 1x4 RBS 200 FCOMB (3) No 1x12 F9d_2.12 (2) RBS 205 FCOMB (3) No F18d_2.12 (2) RBS 205 FCOMB (3) M F18dt_2.12 (2) RBS 205 FCOMB &DPX (2) No F18d_2.12 RBS 205 FCOMB (2) M F18dt_2.
Radio Configurations RBS 2106 and RBS 2206 ** 1 x 10, 1 x 12, 1 x 14, 1 x 16 and 1 x 18 can be accomplished with a partly-equipped expansion configuration. *** 3 x 6 can be accomplished with a partly-equipped expansion configuration. **** When using TG-synchronization, only one RBS 200/RBS 205 can act as master. Therefore the 3 x 4 configuration, which contains three separate RBSs, must be rebuilt to one single RBS; that is, all three sectors of the RBS 200 must be connected to the same TMCB.
RBS 2106 and RBS 2206 Radio Configurations 75; 5%6 0DFUR &DELQHWV ([SDQGHG ZLWK 75; &DELQHW &R 6LWLQJ ZLWK 6LQJOH 758 %DVHG 5%6 8VLQJ )LOWHU &RPELQHU 7DEOH ([SDQVLRQ XVLQJ ILOWHU FRPELQHU 5%6 5%6 5HVXOW 6&& 2ULJLQDO 6&& %DVLF &RQ ILJXUDWLRQ $QWHQQDV 2ULJLQDO 6&& %DVLF &RQ ILJXUDWLRQ $QWHQQDV 1 x 18 * 1x6 D9d_2.6 (2) 1 x 12 F9de_2.12 (2) D18d_2.6 (2) F18d_2.12 (2) D18_2.6 (2) F18dt_2.12 (2) D9d_2.12 (2) F9de_2.12 (2) D18d_2.12 (2) F18d_2.
Radio Configurations RBS 2106 and RBS 2206 &R 6LWLQJ ZLWK 6LQJOH 758 %DVHG 5%6 8VLQJ +\EULG &RPELQHU 7DEOH ([SDQVLRQ XVLQJ K\EULG FRPELQHU 5%6 5%6 5H VXOW 6&& 2ULJ LQDO 6&& %DVLF &RQILJXUDWLRQ $QWHQ QDV 2ULJ LQDO 6&& %DVLF &RQILJXUDWLRQ $QWHQ QDV 3x8* 3x4 3 x C+ 9d_2.4 (2) (2) (2) 3x4 3 x G9dh_2.4 (2) (2) (2) 3 x C+ 9d_2.4 (2) (2) (2) 3 x G9dht_2.4 (2) (2) (2) 3 x C+ 18d_2.4 (2) (2) (2) 3 x G18dh_2.4 (2) (2) (2) 3 x C+ 18_2.4 (2) (2) (2) 3 x G18dht_2.
RBS 2106 and RBS 2206 Radio Configurations 75; 5%6 0DFUR &DELQHW ([SDQGHG ZLWK 75; &DELQHW &R 6LWLQJ ZLWK G758 %DVHG 5%6 0DFUR &DELQHW 8VLQJ )LOWHU &RPELQHU 7DEOH ([SDQVLRQ XVLQJ ILOWHU FRPELQHU 5%6 5%6 5HVXOW 6&& 2ULJLQDO 6&& %DVLF &RQILJXUDWLRQ $QWHQ QDV 2ULJLQDO 6&& %DVLF &RQILJXUDWLRQ $QWHQ QDV 3x8* 8+4 F9d_2.8 + F9d_2.4 (2) (2) (-) 4+8 F9d_2.4 + F9d_2.8 (-) (2) (2) F9dt_2.4 + F9dt_2.4 (2) (2) (-) F9dt_2.4 + F9dt_2.8 (-) (2) (2) F18d_2.8 + F18d_2.
Radio Configurations RBS 2106 and RBS 2206 &R 6LWLQJ ZLWK G758 %DVHG 5%6 8VLQJ +\EULG &RPELQHU 7DEOH ([SDQVLRQ XVLQJ K\EULG FRPELQHU 5%6 5%6 5HVXOW 6&& 2ULJ LQDO 6&& %DVLF &RQILJXUDWLRQ $QWHQ QDV 2ULJLQDO 6&& %DVLF &RQILJXUDWLRQ $QWHQ QDV 3x8* 3x4 3 x G9dh_2.4 (2) (2) (2) 3x4 3 x G9dh_2.4 (2) (2) (2) 3 x G9dht_2.4 (2) (2) (2) 3 x G9dht_2.4 (2) (2) (2) 3 x G18dh_2.4 (2) (2) (2) 3 x G18dh_2.4 (2) (2) (2) 3 x G18dht_2.4 (2) (2) (2) 3 x G18dht_2.
RBS 2106 and RBS 2206 8 Radio Configurations Co-Siting with TDMA RBS Using an ASU The ASU is used for co-siting with a TDMA RBS, more specifically RBS 884 for 800 MHz and 1900 MHz, and RBS 882 for 800 MHz only. The unit allows a TDMA cabinet to share receiver antennas with a GSM cabinet. The ASU is installed in a dTRU based GSM cabinet. The implementation is for 800 and 1900 MHz. The end configuration differs for different site configurations of the TDMA RBS.
Radio Configurations RBS 2106 and RBS 2206 TMA TDMA RBS TX TX/RX TX/RX Co-sited TDMA RBS RX A RX B ddTMA RX ddTMA RX TMA TX dTRU Based RBS P008527A )LJXUH 6HSDUDWH 7; DQG WZR VHSDUDWH 5; DQWHQQDV ZLWK 70$V No new antennas are required. 2QH 'XSOH[ $QWHQQD 5; 7; The TDMA RBS may be equipped with only one TX/RX antenna. The recommendation in this case is to add two antennas for the dTRU based RBS.
RBS 2106 and RBS 2206 Radio Configurations TX/RX TX/RX TX/RX TDMA RBS TX/RX TX/RX TX/RX TDMA RBS TDMA RBS TDMA RBS dTRU Based RBS Recommendation: No Co-siting! P008504B )LJXUH 7ZR VHSDUDWH GXSOH[ DQWHQQDV 2QH 5; DQG 2QH 'XSOH[ $QWHQQD If the original antenna arrangement is TX/RX + RX, the recommendation differs for configurations where the duplex filter is mounted internally, without the possibility to access the TX and RX ports separately, and configurations where the RX path is access
Radio Configurations RBS 2106 and RBS 2206 TX/RX RX TDMA RBS ddTMA TMA TDMA RBS RX A RX B TX dTRU Based RBS TX/RX TX/RX Co-sited TDMA RBS RX A RX B ddTMA RX Co-sited TDMA RBS ddTMA TX/RX TX/RX TX/RX TX dTRU Based RBS P008528A )LJXUH ,QWHUQDO GXSOH[ ILOWHU A special case is where only one TX/RX and one RX port are accessible from the outside of the cabinet. In that case the solution stated below can be used.
RBS 2106 and RBS 2206 Radio Configurations TX/RX RX TX/RX DPX DPX TDMA RBS Co-sited TDMA RBS Max 2 GSM TRX per sector RX RX A RX B TX/RX Co-sited TDMA RBS TX/RX dTRU Based RBS TX/RX RX B TX/RX dTRU Based RBS P008529A )LJXUH EN/LZT 720 0318 Uen R1A ,QWHUQDO GXSOH[ ILOWHU DQG RQO\ WZR DQWHQQD SRUWV DFFHVVLEOH 89 (90)
Radio Configurations RBS 2106 and RBS 2206 ([WHUQDO 'XSOH[ )LOWHU If an external duplex filter is used, it is possible to expand the configuration in two steps. The first step does not require any new antennas, but limits the number of GSM TRXs to two (that is, one dTRU) for each sector. Support of more GSM TRXs requires additional antennas.
EN/LZT 720 0319 Uen R1A RBS 2106 Antenna Configurations Description This document describes the antenna configurations that are possible for the RBS 2106.
Antenna Configurations RBS 2106 Contents ,QWURGXFWLRQ $QWHQQD &RQQHFWLRQ )LHOG &'8 ) $QWHQQD &RQQHFWLRQV &'8 ) &RQILJXUDWLRQV 4.1 3x2 CDU-F and 3x4 CDU-F 8 4.2 1x8 CDU-F 10 4.3 1x12 CDU-F 11 4.4 2x6 CDU-F 13 4.5 1x4 + 1x8 CDU-F 14 4.6 1x8 + 1x4 CDU-F 16 &'8 * $QWHQQD &RQQHFWLRQV &'8 * &RQILJXUDWLRQV 6.1 3x2 CDU-G and 3x4 CDU-G 19 6.2 1+1+2 CDU-G 21 6.
RBS 2106 1 Antenna Configurations Introduction The various configurations available for cabinets are described according to the following example: 3 x 2 CDU-F Number of cells Type of CDU Number of TRX/cell P008245B )LJXUH &'8 FRQILJXUDWLRQ NH\ In the example above, the cabinet is configured for three cells, each using two TRXs. The total number TRXs is thus six in this case. The CDU is type CDU-F. 1RWH EN/LZT 720 0319 Uen R1A If TMA is used the bias injectors must be installed.
Antenna Configurations 2 RBS 2106 Antenna Connection Field Each CDU uses a set of standard RF wiring patterns for connection between each CDU and the antenna connection field. The figures below provide an overview of the antenna sharing connectors and cabling from the ASU and CDU.
RBS 2106 Antenna Configurations CDU-F A2 A1 CDU-G A4 A3 A6 A5 A2 A3 A1 CDU-F A4 A5 A6 CDU-G CDU-F 900 CDU-G CDU-F 900 CDU-G 900 Fault Open Fault Open RX1 Fault Open RX1 RX2 RX1 RX2 RX2 CDU bus CDU bus CDU bus DC in TX1 DC in TX2 TX1 DC in TX2 TX1 TX2 1 (x6) A1 A2 A3 A4 A5 A6 P008594C )LJXUH ,QWHUQDO FDEOLQJ EHWZHHQ &'8V DQG DQWHQQD FRQQHFWLRQ ILHOG EN/LZT 720 0319 Uen R1A 5 (26)
Antenna Configurations RBS 2106 Ant. S2 Ant. S1 Ant. S3 Ant. S4 Ant. S5 Ant.
RBS 2106 3 Antenna Configurations CDU-F Antenna Connections The antenna connectors are located on the top of the CDU, VHH ILJXUHV EHORZ Antenna connectors CDU-F P007450D )LJXUH &'8 ) OD\RXW TX/RX RX CDU-F CDU-F CDU-F P008356B )LJXUH EN/LZT 720 0319 Uen R1A &'8 ) DQWHQQD IHHGHU FRQQHFWRUV 7 (26)
Antenna Configurations 4 RBS 2106 CDU-F Configurations 1RWH In the figures and tables that follow, only cabinets that are fully-equipped are shown. Configurations consisting of part of the fully-equipped cabinet are also possible to extract from the following figures and tables. 6HH )LJXUH RQ SDJH )LJXUH RQ SDJH and )LJXUH RQ SDJH for a description of the column headers in the tables below.
RBS 2106 Antenna Configurations Cell A TMA TMA DX1 RXB TMA DX1 Cell B RXB Cell C TMA TMA DX1 RXB TMA P008260B )LJXUH &RQILJXUDWLRQ ZLWK 70$ 7DEOH [ &'8 ) DQG [ &'8 ) &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO A 1 B C 2 3 &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU CellA: DX1 TX/RX A1 TX/RX A S1 CellA: RXB RX A2 RX B S2 CellB: DX1 TX/RX A3 TX/RX A S3 CellB: RXB RX A4 RX B S4 CellC: DX1 TX/RX A5 TX/RX A S5 CellC: RXB RX A6 RX B S6 From the configuratio
Antenna Configurations RBS 2106 [ &'8 ) Cell A DX1 DX2 P008229C )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ TMA DX1 Cell A TMA DX2 P008255C )LJXUH 10 (26) &RQILJXUDWLRQ ZLWK 70$ EN/LZT 720 0319 Uen R1A
RBS 2106 Antenna Configurations 7DEOH [ &'8 ) &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX A1 TX/RX A S1 2 CellA: DX2 TX/RX A3 TX/RX B S3 [ &'8 ) Cell A DX1 DX2 P008228B )LJXUH EN/LZT 720 0319 Uen R1A &RQILJXUDWLRQ ZLWKRXW 70$ 11 (26)
Antenna Configurations RBS 2106 TMA Cell A DX1 TMA DX2 P008256B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ &'8 ) &'8 &RQQHFWRU 12 (26) &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX A1 TX/RX A S1 3 CellA: DX2 TX/RX A5 TX/RX B S5 EN/LZT 720 0319 Uen R1A
RBS 2106 Antenna Configurations [ &'8 ) Cell A DX1 Cell B RXB RXB DX1 P008232B )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell B Cell A TMA TMA DX1 RXB TMA DX1 TMA RXB P008257B )LJXUH EN/LZT 720 0319 Uen R1A &RQILJXUDWLRQ ZLWK 70$ 13 (26)
Antenna Configurations RBS 2106 7DEOH [ &'8 ) &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX A1 TX/RX A S1 CellA: RXB RX A2 RX B S2 CellB: DX1 TX/RX A5 TX/RX A S5 CellB: RXB RX A6 RX B S6 B 3 [ [ &'8 ) Cell A DX1 RXB Cell B DX1 DX2 P008230B )LJXUH 14 (26) &RQILJXUDWLRQ ZLWKRXW 70$ EN/LZT 720 0319 Uen R1A
RBS 2106 Antenna Configurations Cell B Cell A TMA TMA TMA DX1 RXB DX1 TMA DX2 P008259B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ [ &'8 ) &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX A1 TX/RX A S1 CellA: RXB RX A2 RX B S2 2 CellB: DX1 TX/RX A3 TX/RX B S3 3 CellB: DX2 TX/RX A5 TX/RX B S5 B EN/LZT 720 0319 Uen R1A 15 (26)
Antenna Configurations RBS 2106 [ [ &'8 ) Cell A DX1 Cell B DX2 DX1 RXB P008231B )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell B Cell A TMA DX1 TMA DX2 TMA DX1 TMA RXB P008258B )LJXUH 16 (26) &RQILJXUDWLRQ ZLWK 70$ EN/LZT 720 0319 Uen R1A
RBS 2106 Antenna Configurations 7DEOH [ [ &'8 ) &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX A1 TX/RX A S1 2 CellA: DX2 TX/RX A3 TX/RX B S3 3 CellB: DX1 TX/RX A5 TX/RX A S5 CellB: RXB RX A6 RX B S6 B EN/LZT 720 0319 Uen R1A 17 (26)
Antenna Configurations 5 RBS 2106 CDU-G Antenna Connections The antenna connectors are located on the top of the CDU, VHH ILJXUHV EHORZ Antenna connectors CDU-G 900 Fault Open RX1 RX2 CDU bus DC in TX1 TX2 P007448B )LJXUH &'8 * OD\RXW TX/RX 1 TX/RX 2 CDU-G CDU-G CDU-G P008357B )LJXUH 18 (26) &'8 * DQWHQQD IHHGHU FRQQHFWRUV EN/LZT 720 0319 Uen R1A
RBS 2106 6 Antenna Configurations CDU-G Configurations 1RWH In the figures and tables that follow, only cabinets that are fully-equipped are shown. Configurations consisting of part of the fully-equipped cabinet are also possible to extract from the following figures and tables. 6HH )LJXUH RQ SDJH )LJXUH RQ SDJH and )LJXUH RQ SDJH for a description of the column headers in the tables below.
Antenna Configurations RBS 2106 Cell A TMA TMA DX1 TMA Cell B DX1 DX2 DX2 Cell C TMA DX1 TMA TMA DX2 P008261B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ 5%6 [ &'8 * DQG [ &'8 * &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 A1 TX/RX A S1 CellA: DX2 TX/RX2 A2 TX/RX B S2 CellB: DX1 TX/RX1 A3 TX/RX A S3 CellB: DX2 TX/RX2 A4 TX/RX B S4 CellC: DX1 TX/RX1 A5 TX/RX A S5 CellC: DX2 TX/RX2 A6 TX/RX B S6
RBS 2106 Antenna Configurations &'8 * Cell A DX1 RXB Cell C Cell B DX1 RXB DX1 DX2 P009496A )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell A TMA TMA TMA Cell B DX1 DX1 RXB RXB Cell C TMA DX1 TMA TMA DX2 P009497A )LJXUH EN/LZT 720 0319 Uen R1A &RQILJXUDWLRQ ZLWK 70$ 21 (26)
Antenna Configurations RBS 2106 7DEOH &'8 * &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 A1 TX/RX A S1 2 CellA: RXB TX/RX1 A3 RX B S3 1 CellB: DX1 TX/RX2 A2 TX/RX A S2 2 CellB: RXB TX/RX2 A4 RX B S4 3 CellC: DX1 TX/RX1 A5 TX/RX A S5 CellC: DX2 TX/RX2 A6 TX/RX B S6 B C [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG FRPELQHU Cell A DX1 TX1 DX2 TX2 P008225C )LJXUH 22 (26) &RQ
RBS 2106 Antenna Configurations Cell A TMA TMA DX1 TX1 DX2 TX2 P008233C )LJXUH &RQILJXUDWLRQ ZLWK 70$ 7DEOH [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG FRPELQHU &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO A 1 2 EN/LZT 720 0319 Uen R1A &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU CellA: DX1 TX/RX1 A1 TX/RX A S1 CellA: TX1 TX/RX2 A2 RX B CellA: DX2 TX/RX1 A3 TX/RX A CellA: TX2 TX/RX2 A4 RX B S3 23 (26)
Antenna Configurations RBS 2106 [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG FRPELQHU Cell A DX1 TX1 TX2 TX3 DX2 TX4 P008226B )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell A TMA DX1 TX1 TMA TX2 TX3 DX2 TX4 P008262B )LJXUH 24 (26) &RQILJXUDWLRQ ZLWK 70$ EN/LZT 720 0319 Uen R1A
RBS 2106 Antenna Configurations 7DEOH FRPELQHU [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 A1 TX/RX A S1 CellA: TX1 TX/RX2 A2 TX CellA: TX2 TX/RX1 A3 TX CellA: TX3 TX/RX2 A4 TX CellA: DX2 TX/RX1 A5 TX/RX B CellA: TX4 TX/RX2 A6 TX 2 3 S5 [ &'8 * Cell B Cell A DX1 DX2 TX1 TX2 DX1 DX2 P008224B )LJXUH EN/LZT 720 0319 Uen R1A &RQILJXUDWLR
Antenna Configurations RBS 2106 TMA Cell A Cell B TMA TMA DX1 DX2 TX1 TX2 TMA DX1 DX2 P008263B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ &'8 * &'8 &RQQHFWRU &HOO &'8 1R )HHGHU ODEHO &'8 &RQQ ILHOG 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 A1 TX/RX A S1 CellA: DX2 TX/RX2 A2 TX/RX B S2 CellA: TX1 TX/RX1 A3 TX CellB: TX2 TX/RX2 A4 TX CellB: DX1 TX/RX1 A5 TX/RX A S5 CellB: DX2 TX/RX2 A6 TX/RX B S6 2 B 3 Ericsson AB SE-164 80 Stockholm Sweden 26 (26) T
EN/LZT 720 0320 Uen R1A RBS 2206 Antenna Configurations Description This document describes the antenna configurations that are possible for the RBS 2206.
Antenna Configurations RBS 2206 Contents ,QWURGXFWLRQ $QWHQQD &RQQHFWLRQ )LHOG &'8 ) $QWHQQD &RQQHFWLRQV &'8 ) &RQILJXUDWLRQV 4.1 3x2 CDU-F and 3x4 CDU-F 6 4.2 1x8 CDU-F 8 4.3 1x12 CDU-F 9 4.4 2x6 CDU-F 11 4.5 1x4 + 1x8 CDU-F 12 4.6 1x8 + 1x4 CDU-F 14 &'8 * $QWHQQD &RQQHFWLRQV &'8 * &RQILJXUDWLRQV 6.1 3x2 CDU-G and 3x4 CDU-G 17 6.2 1+1+2 CDU-G 19 6.
RBS 2206 1 Antenna Configurations Introduction The various configurations available for cabinets are described according to the following example: 3 x 2 CDU-F Number of cells Type of CDU Number of TRX/cell P008245B )LJXUH &'8 FRQILJXUDWLRQ NH\ In the example above, the cabinet is configured for three cells, each using two TRXs. The total number TRXs is thus six in this case. The CDU is type CDU-F. 1RWH EN/LZT 720 0320 Uen R1A If TMA is used the bias injectors must be installed.
Antenna Configurations 2 RBS 2206 Antenna Connection Field This section describes the cabling from the antenna connection field to the ASU. The RF cables between each CDU and its associated TRUs are standardised and do not normally change. 7KH ILJXUH EHORZ gives an overview of the antenna sharing connectors and cabling from the ASU. 2 1 5 3 6 4 ASU Ant. S1 Ant. S3 Ant. S2 Ant. S5 Ant. S6 Ant.
RBS 2206 3 Antenna Configurations CDU-F Antenna Connections The antenna connectors are located on the top of the CDU, VHH ILJXUHV EHORZ Antenna connectors CDU-F P007450D )LJXUH &'8 ) OD\RXW TX/RX RX CDU-F CDU-F CDU-F P008356B )LJXUH EN/LZT 720 0320 Uen R1A &'8 ) DQWHQQD IHHGHU FRQQHFWRUV 5 (24)
Antenna Configurations 4 RBS 2206 CDU-F Configurations 1RWH In the figures and tables that follow, only cabinets that are fully-equipped are shown. Configurations consisting of part of the fully-equipped cabinet are also possible to extract from the following figures and tables. 6HH )LJXUH RQ SDJH and )LJXUH RQ SDJH for a description of the column headers in the tables below.
RBS 2206 Antenna Configurations Cell A TMA TMA DX1 RXB TMA DX1 Cell B RXB Cell C TMA TMA DX1 RXB TMA P008260B )LJXUH &RQILJXUDWLRQ ZLWK 70$ 7DEOH [ &'8 ) DQG [ &'8 ) &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX TX/RX A 1 CellA: RXB RX RX B 2 CellB: DX1 TX/RX TX/RX A 3 CellB: RXB RX RX B 4 CellC: DX1 TX/RX TX/RX A 5 CellC: RXB RX RX B 6 B C 2 3 From the configuration shown in the figures and tables above, th
Antenna Configurations RBS 2206 [ &'8 ) Cell A DX1 DX2 P008229C )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ TMA DX1 Cell A TMA DX2 P008255C )LJXUH 8 (24) &RQILJXUDWLRQ ZLWK 70$ EN/LZT 720 0320 Uen R1A
RBS 2206 Antenna Configurations 7DEOH [ &'8 ) &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX TX/RX A 1 2 CellA: DX2 TX/RX TX/RX B 3 [ &'8 ) Cell A DX1 DX2 P008228B )LJXUH EN/LZT 720 0320 Uen R1A &RQILJXUDWLRQ ZLWKRXW 70$ 9 (24)
Antenna Configurations RBS 2206 TMA Cell A TMA DX1 DX2 P008256B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ &'8 ) &'8 10 (24) &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX TX/RX A 1 3 CellA: DX2 TX/RX TX/RX B 5 EN/LZT 720 0320 Uen R1A
RBS 2206 Antenna Configurations [ &'8 ) Cell A DX1 Cell B RXB RXB DX1 P008232B )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell B Cell A TMA TMA DX1 RXB TMA DX1 TMA RXB P008257B )LJXUH EN/LZT 720 0320 Uen R1A &RQILJXUDWLRQ ZLWK 70$ 11 (24)
Antenna Configurations RBS 2206 7DEOH [ &'8 ) &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX TX/RX A 1 CellA: RXB RX RX B 2 CellB: DX1 TX/RX TX/RX A 5 CellB: RXB RX RX B 6 B 3 [ [ &'8 ) Cell A DX1 RXB Cell B DX1 DX2 P008230B )LJXUH 12 (24) &RQILJXUDWLRQ ZLWKRXW 70$ EN/LZT 720 0320 Uen R1A
RBS 2206 Antenna Configurations Cell B Cell A TMA TMA DX1 RXB DX1 TMA TMA DX2 P008259B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ [ &'8 ) &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX TX/RX A 1 CellA: RXB RX RX B 2 2 CellB: DX1 TX/RX TX/RX B 3 3 CellB: DX2 TX/RX TX/RX B 5 B EN/LZT 720 0320 Uen R1A 13 (24)
Antenna Configurations RBS 2206 [ [ &'8 ) Cell A DX1 Cell B DX2 DX1 RXB P008231B )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell B Cell A TMA DX1 TMA DX2 TMA DX1 TMA RXB P008258B )LJXUH 14 (24) &RQILJXUDWLRQ ZLWK 70$ EN/LZT 720 0320 Uen R1A
RBS 2206 Antenna Configurations 7DEOH [ [ &'8 ) &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX TX/RX A 1 2 CellA: DX2 TX/RX TX/RX B 3 3 CellB: DX1 TX/RX TX/RX A 5 CellB: RXB RX RX B 6 B EN/LZT 720 0320 Uen R1A 15 (24)
Antenna Configurations 5 RBS 2206 CDU-G Antenna Connections The antenna connectors are located on the top of the CDU, VHH ILJXUHV EHORZ Antenna connectors CDU-G 900 Fault Open RX1 RX2 CDU bus DC in TX1 TX2 P007448B )LJXUH &'8 * OD\RXW TX/RX 1 TX/RX 2 CDU-G CDU-G CDU-G P008357B )LJXUH 16 (24) &'8 * DQWHQQD IHHGHU FRQQHFWRUV EN/LZT 720 0320 Uen R1A
RBS 2206 6 Antenna Configurations CDU-G Configurations 1RWH In the figures and tables that follow, only cabinets that are fully-equipped are shown. Configurations consisting of part of the fully-equipped cabinet are also possible to extract from the following figures and tables. 6HH )LJXUH RQ SDJH and )LJXUH RQ SDJH for a description of the column headers in the tables below.
Antenna Configurations RBS 2206 Cell A TMA TMA DX1 TMA Cell B DX1 DX2 DX2 Cell C TMA DX1 TMA TMA DX2 P008261B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ &'8 * DQG [ &'8 * &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 TX/RX A 1 CellA: DX2 TX/RX2 TX/RX B 2 CellB: DX1 TX/RX1 TX/RX A 3 CellB: DX2 TX/RX2 TX/RX B 4 CellC: DX1 TX/RX1 TX/RX A 5 CellC: DX2 TX/RX2 TX/RX B 6 B C 2 3 From the configuration in the figures and
RBS 2206 Antenna Configurations &'8 * Cell A DX1 RXB Cell C Cell B DX1 RXB DX1 DX2 P009496A )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell A TMA TMA TMA Cell B DX1 DX1 RXB RXB Cell C TMA DX1 TMA TMA DX2 P009497A )LJXUH EN/LZT 720 0320 Uen R1A &RQILJXUDWLRQ ZLWK 70$ 19 (24)
Antenna Configurations RBS 2206 7DEOH &'8 * &'8 &'8 FRQ QHFWRU 6LJQDO $68 &RQQHFWRU 1 CellA: DX1 TX/RX1 TX/RX A 1 2 CellA: RXB TX/RX1 RX B 3 1 CellB: DX1 TX/RX2 TX/RX A 2 2 CellB: RXB TX/RX2 RX B 4 3 CellC: DX1 TX/RX1 TX/RX A 5 CellC: DX2 TX/RX2 TX/RX B 6 &'8 1R A B C )HHGHU ODEHO &HOO [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG FRPELQHU Cell A DX1 TX1 DX2 TX2 P008225C )LJXUH 20 (24) &RQILJXUDWLRQ ZLWKRXW 70$ EN/LZT 720 0320 U
RBS 2206 Antenna Configurations Cell A TMA DX1 TX1 TMA DX2 TX2 P008233C )LJXUH &RQILJXUDWLRQ ZLWK 70$ 7DEOH [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG FRPELQHU &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 TX/RX A 1 CellA: TX1 TX/RX2 TX CellA: DX2 TX/RX1 TX/RX B CellA: TX2 TX/RX2 TX 2 EN/LZT 720 0320 Uen R1A 3 21 (24)
Antenna Configurations RBS 2206 [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG FRPELQHU Cell A DX1 TX1 TX2 TX3 DX2 TX4 P008226B )LJXUH &RQILJXUDWLRQ ZLWKRXW 70$ Cell A TMA DX1 TX1 TMA TX2 TX3 DX2 TX4 P008262B )LJXUH 22 (24) &RQILJXUDWLRQ ZLWK 70$ EN/LZT 720 0320 Uen R1A
RBS 2206 Antenna Configurations 7DEOH FRPELQHU [ &'8 * ZLWKRXW K\EULG FRPELQHU DQG [ &'8 * ZLWK K\EULG &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 TX/RX A 1 CellA: TX1 TX/RX2 TX CellA: TX2 TX/RX1 TX CellA: TX3 TX/RX2 TX CellA: DX2 TX/RX1 TX/RX B CellA: TX4 TX/RX2 TX 2 3 5 [ &'8 * Cell B Cell A DX1 DX2 TX1 TX2 DX1 DX2 P008224B )LJXUH EN/LZT 720 0320 Uen R1A &RQILJXUDWLRQ ZLWKRXW 70$ 23 (24)
Antenna Configurations RBS 2206 TMA Cell A Cell B TMA TMA DX1 DX2 TX1 TX2 TMA DX1 DX2 P008263B )LJXUH 7DEOH &RQILJXUDWLRQ ZLWK 70$ [ &'8 * &'8 &HOO &'8 1R )HHGHU ODEHO &'8 FRQQHFWRU 6LJQDO $68 &RQQHFWRU A 1 CellA: DX1 TX/RX1 TX/RX A 1 CellA: DX2 TX/RX2 TX/RX B 2 CellA: TX1 TX/RX1 TX CellB: TX2 TX/RX2 TX CellB: DX1 TX/RX1 TX/RX A 5 CellB: DX2 TX/RX2 TX/RX B 6 2 B 3 Ericsson AB SE-164 80 Stockholm Sweden 24 (24) The contents of this document are subject
1(6) ACCU-01 AC Connection Unit Unit Description EN/LZT 720 0229 R1A The AC Connection Unit (ACCU) distributes primary power to the Power Supply Units (PSU).
2(6) Contents EN/LZT 720 0229 R1A 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Function Description 3 4 4.1 4.
3(6) 1 Product Overview The ACCU distributes primary power to the PSUs. There is only one ACCU in the cabinet, depending on the type of incoming power. 1.1 Main Functions The ACCU has the following functions: 2 • Terminates incoming AC mains cables • Disconnects incoming AC mains • Filters EMC Dimensions The dimensions of the ACCU are shown in the table below. 3 Table 1 Size and weight Height Width Depth Weight 293.
4(6) 4 Interfaces ACCU P006805A Figure 1 ACCU interfaces The ACCU has the following interfaces: EN/LZT 720 0229 R1A • Terminal block for incoming AC mains cables • Four connection points for outgoing cables to the PSUs
5(6) 4.1 Signal and Power Interfaces Input Data Table 2 Input data Frequency 45 – 65 Hz Voltage 90 – 275 V AC External fuses 4 pcs, max. 16 A Cable diameter 8.5 – 12.5 mm Conductor area 1.5 – 2.5 mm2 Number of conductors 3 (L, N, PE) Output Data Four cables with connectors according to IEC 320 and for connection to the PSU AC inlet. 4.2 Operator Interface The mains switch on the ACCU that has two states, on (position 1) and off (position 0).
6(6) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(6) ACCU-02 AC Connection Unit Unit Description EN/LZT 720 0230 R1A The AC Connection Unit (ACCU-02) distributes and supervises the incoming AC mains to the units in the RBS cabinet.
2(6) Contents EN/LZT 720 0230 R1A 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 3.1 3.2 Function Description Connection Unit Distribution Unit 3 4 4 4 4.1 4.
3(6) 1 Product Overview ACCU-02 distributes and supervises the incoming AC mains to the units in the RBS. It consists of two units, a Connection Unit and a Distribution Unit. The units are connected together with a power cable and a signal cable. 1.1 Main Functions ACCU-02 has the following main functions: 2 • Distributes AC power to the PSUs and makes it possible to connect and disconnect the PSUs through the EPC bus. • Distributes AC power to the Climate Unit.
Distribution Unit EPC BUS PSU 4 PSU 3 PSU 2 PSU 1 Climate Unit Service outlet 4(6) Control Board = = EMC filter Overvoltage protection Connection Unit Mains Switch +24V DC Internal light +24/-48V DC = +24V DC AUX AC Mains P008483A Figure 1 Block diagram of ACCU-02 3.1 Connection Unit The Connection Unit consists of: 3.
5(6) • One service outlet, protected by a 10 A circuit breaker with earth fault breaker • Two DC outputs for cabinet lighting and auxiliary equipment, protected by 1 A circuit breakers • Rectifier for supply of Control Unit • Voltage Regulator for supply of Control Unit and DC outputs from +24 or -48 V DC • Relays which provide the possibility to turn off and on the PSU outputs • Control Unit 4 Interfaces 4.
6(6) Table 4 Priority DC supply to control unit Option Voltage Range Max. Current +24 V DC +18 to +32 V DC 1 A (1) -48 V DC -39 to -60 V DC 0.6 A (1) (1) mA excluding internal lighting. Output Data Table 5 Output voltages PSU 1 – 4 180 – 275 V AC Climate Unit 180 – 275 V AC Service Outlet Same as input (line to neutral) Internal lighting +24 V DC +18 to +32 V DC Auxiliary +24 V DC +18 to +32 V DC Note: The DC output voltages require DC input voltage. Table 6 4.
EN/LZT 720 0300 R1A ADM-01 Auxiliary Distribution Module Description The ADM distributes DC power through circuit breakers to the TM and to the DC-out 100 W in the RBS 2106.
Auxiliary Distribution Module ADM-01 Contents 2 (8) 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Function Description 4 4 4.1 4.
ADM-01 1 Auxiliary Distribution Module Product Overview The ADM-01 distributes +24 V DC or –48 V DC to the Transport Module (TM) compartment and to the DC out 100 W connection in the DF box. 1.1 Main Functions The ADM-01 has the following main functions: 2 • Two inputs for +24 V DC • Two inputs for –48 V DC • Ten distribution outputs which can be selected for +24 V DC or –48 V DC, protected by 6 A fuses. • One output for +24 V DC, designated “Out 100 W”, protected by a 6 A fuse.
Auxiliary Distribution Module 3 ADM-01 Function Description +24 V TM2 +24 V TM1 -48 V TM1 + TM2 OV (24 V) OV (48 V) 1 OV (24 V) +24 V/-48 V OV (48 V) DC out TM1 OV (24 V) +24 V/-48 V OV (48 V) 5 6 DC out TM2 10 +24 V DC Out 100 W +24 V DC -48 V DC P009814A Figure 1 ADM circuit diagram 4 (8) EN/LZT 720 0300 R1A
ADM-01 Auxiliary Distribution Module The ten outputs on the ADM-01 are divided into two groups: DC out TM1 and DC out TM2. The outputs are protected by circuit breakers that function both as fuses and manual disconnect switches. It is possible to feed the ADM with either +24 V DC or –48 V DC, or both. The feed used is shown by two indicators on the front panel. One +24 V DC input is connected to the TM1 output group. The second +24 V DC input is connected to the TM2 output group.
Auxiliary Distribution Module 4 ADM-01 Interface ADM-01 6A Fuses -48VDC -48 VDC In TM1 & TM2 Max total input power: 500W Max input power: +24VDC: 2x250W, -48VDC: 2x200W 24VDC + 48VDC + DC out TM1 24VDC + 48VDC + 24VDC + 48VDC + 24VDC + 48VDC + 24VDC + 48VDC + +24 VDC In TM1 +24 VDC In TM2 +24VDC 24VDC + 48VDC + On 6A 24VDC + 48VDC + DC out TM2 Off 24VDC + 48VDC + +24VDC Out 100 W 24VDC + 48VDC + 24VDC + 48VDC + Off -48V On +24V P009813A Figure 2 ADM interfaces 4.
ADM-01 Auxiliary Distribution Module Table 3 Input power Nominal voltages Input power Input fuse rating +24 V DC 2 x 250 W 2 x 15 A -48 V DC 2 x 200 W 2 x 10 A +24 and -48 V DC 250 + 200 W 15 A and 10 A Note: The total input power to the ADM must not exceed 500 W. Output Data Table 4 4.2 Output connections Output Connection Fuse DC out TM1, pos 1 – pos 5 Screw terminals 0.5 – 2.5 mm2 6A DC out TM2, pos 1 – pos 5 Screw terminals 0.5 – 2.
Auxiliary Distribution Module Ericsson AB SE-164 80 Stockholm Sweden implementation.GSMsupport@era.ericsson.se 8 (8) ADM-01 Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(8) ASU Antenna Sharing Unit Unit Description EN/LZT 720 0232 R1A The Antenna Sharing Unit (ASU) is used as a part of co-siting, where a cabinet, operating on another standard, shares antennas with a GSM cabinet in the same sector. Ant. S1 CDU1 RX1 RX1 CXU RX2 CDU1 RX2 Ant. S2 Ant. S3 CDU2 RX1 RX1 CXU RX2 CDU2 RX2 Ant. S4 Ant. S5 CDU3 RX1 RX1 CXU RX2 CDU3 RX2 Ant.
2(8) &RQWHQWV EN/LZT 720 0232 R1A 1.1 3URGXFW 2YHUYLHZ Main Functions 3 'LPHQVLRQV 3RZHU &RQVXPSWLRQ DQG +HDW *HQHUDWLRQ 4.1 4.2 )XQFWLRQ 'HVFULSWLRQ RX Signal Path Cable Path and Supervision 4 5 5.1 5.
3(8) 1 Product Overview 0DLQ )XQFWLRQV Antenna sharing is part of co-siting, that is, using a cabinet operating on another standard together with a GSM cabinet in the same sector. The ASU allows a TDMA (or other) cabinet and a GSM cabinet to share RX antennas. It does this by sharing the RX signals between both cabinets. The ASU is a broadband product, which means that it covers 800 –1910 MHz. 2 Dimensions 7DEOH 6L]H DQG ZHLJKW +HLJKW :LGWK 22 mm 437.
4(8) Ant. S1 Coupler 1 CXU-RX1 (CDU1) CDU1-RX1 Ant. S2 Coupler 2 CXU-RX2 (CDU1) CDU1-RX2 Ant. S3 Coupler 3 CXU-RX1 (CDU2) CDU2-RX1 Ant. S4 Coupler 4 CXU-RX2 (CDU2) CDU2-RX2 Ant. S5 Coupler 5 CXU-RX1 (CDU3) CDU3-RX1 Ant. S6 Coupler 6 CXU-RX1 (CDU3) CDU3-RX2 TMA Atten. control DC/DC converter + 24 V No TMA P008480A )LJXUH $68 EORFN GLDJUDP 5; 6LJQDO 3DWK The RX signal path is fed from the antennas through the feeders to the Antenna Reference Point (ARP).
5(8) TX/RX TX TX/RX CDU ASU CXU RXA RXB TX dTRU RBS 2206/2106 Co-sited RBS P008373A )LJXUH 5; VLJQDO SDWK &DEOH 3DWK DQG 6XSHUYLVLRQ The RF cables between the ASU and the co-sited RBSs can be supervised by the TMA support function in the TDMA cabinet.
6(8) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 P008470A )LJXUH &RQQHFWLRQ SRUWV 7DEOH EN/LZT 720 0232 R1A &RQQHFWLRQ SRUWV 3RV $68 ODEHO &RQQHFWV WR 1 Ant.S1 Antenna sharing connectors 7\SH RI FRQQHFWRU QMA 2 CDU1 RX1 CDU 1, port RX1 QMA 3 RX1 CXU, port 3 QMA 4 RX2 CXU, port 4 QMA 5 CDU1 RX2 CDU 1, port RX2 QMA 6 Ant.S2 Antenna sharing connectors QMA 7 Ant.
7(8) 2SHUDWRU ,QWHUIDFH There is one switch on the front panel to set the internal attenuators for TMA or no TMA. There are two indicators on the front inducating the status of the ASU.
8(8) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(8) BFU-21 Battery Fuse Unit Unit Description EN/LZT 720 0234 R1A The Battery Fuse Unit (BFU) monitors and controls the battery. It cuts off the load (the RBS) at low battery voltage, when the temperature of the battery is too high or if there is a short circuit between the distribution cables.
2(8) &RQWHQWV EN/LZT 720 0234 R1A 1.1 3URGXFW 2YHUYLHZ Main Functions 3 'LPHQVLRQV 3.1 3.2 3.3 3.4 )XQFWLRQ 'HVFULSWLRQ Contactor Circuit Breaker Shunt TM and EC Supply 4 5 5 5 4.1 4.
3(8) 1 Product Overview The BFU-21 supplies battery back-up system voltage to the RBS and disconnects the battery when it has reached its lower discharge limit. The contactor can disconnect and connect the battery with a control signal from the Supervision Module (SM). 0DLQ )XQFWLRQV The BFU has the following functions: 2 • Supplies priority power to transmission equipment. Power to transmission equipment can be distributed even if a battery is not present.
4(8) 3 Function Description Shunt Contactor 200A Battery RBS DC distribution TM and EC supply Contactor 15A 15A 2A Supervision Module TM1 TM2 EC EPC bus (opto) P008643B )LJXUH %ORFN GLDJUDP RI %)8 The BFU consists of the following blocks: • Contactors • Circuit breakers • Shunt • TM and EC supply • Supervision module &RQWDFWRU The Contactor is used to disconnect the batteries from the system. The Supervision Module controls the Contactor.
5(8) &LUFXLW %UHDNHU The circuit breaker disconnects the batteries if the current becomes too high. It can also be manually operated on the front of the BFU to connect or disconnect the batteries from the DC distribution. 6KXQW The shunt is used to sense the input current. The SM senses the value, which is used for control of the BFU. 70 DQG (& 6XSSO\ There are two TM outputs for supply of transmission equipment and one EC output for priority supply of the Control Board in the ACCU.
6(8) 7DEOH 1RPLQDO LQSXW YROWDJH +24 V DC negative ground 3HUPLWWHG YDULDWLRQ LQSXW YROWDJH +18.0 to +29.0 V DC 1RQ GHVWUXFWLRQ LQSXW YROWDJH 0.0 to +32.0 V DC 3RZHU 4800 W 1RPLQDO LQSXW FXUUHQW 185 A 0D[LPXP LQSXW FXUUHQW 0D[LPXP FXUUHQW ULSSOH +] N+] 205 A 7DEOH ,QSXW GDWD 24 Arms 2XWSXW FXUUHQWV 5%6 '& GLVWULEXWLRQ QRPLQDO 160 A 5%6 '& GLVWULEXWLRQ PD[LPXP 180 A (during 3 hrs) 70 VXSSO\ 12 A 70 VXSSO\ 12 A (& VXSSO\ 1.
7(8) 6ZLWFKHV • Battery Disconnect - on/off • DC out 1 - on/off • DC out 2 - on/off • EC - on/off EN/LZT 720 0234 R1A
8(8) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(6) BFU-22 Battery Fuse Unit Unit Description EN/LZT 720 0276 R1A The Battery Fuse Unit (BFU) monitors and controls the battery. It cuts off the load (the RBS) at low battery voltage, when the temperature of the battery is too high or if there is a short circuit between the distribution cables.
2(6) Contents EN/LZT 720 0276 R1A 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 3.1 3.2 3.3 3.4 Function Description Contactor Circuit Breaker Shunt TM Supply 4 4 5 5 5 4 4.1 4.
3(6) 1 Product Overview The BFU-22 supplies battery back-up system voltage to the RBS and disconnects the battery when it has reached its lower discharge limit. The contactor can disconnect and connect the battery with a control signal from the Supervision Module (SM). 1.1 Main Functions The BFU can supply priority power to transmission equipment. Power to transmission equipment can be distributed even if a battery is not present. The relay can select the power source with a control signal from the SM.
4(6) 3 Function Description Shunt 200A Battery Contactor RBS DC distribution TM and EC Contactor supply 50A Supervision Module TM EPC bus (opto) P008644B Figure 1 Block diagram of BFU-22 The BFU consists of the following blocks: 3.1 • Contactors • Circuit breakers • Shunt • TM and EC supply • Supervision module Contactor The contactor is used to disconnect the batteries from the system. The SM controls the contactor.
5(6) 3.2 Circuit Breaker The circuit breaker disconnects the batteries if the current becomes too high. It can also be manually operated on the front of the BFU to connect or disconnect the batteries from the DC distribution. 3.3 Shunt The shunt is used to sense the input current. The SM senses the value, which is used for control of the BFU. 3.4 TM Supply One high-power TM output exists for supply of transmission equipment. 4 Interfaces The BFU has the following interfaces: 4.
6(6) Table 3 4.2 Output currents RBS DC distribution (nominal) 160 A RBS DC distribution (maximum) 180 A (during 3 hrs) TM supply 40 A Operator Interface Indicators Table 4 Indicators Indicator Colour Fault Red Operational Green EPC bus fault Yellow Battery disconnected Yellow Switches • Battery Disconnect - on/off • DC out - on/off Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.
1(8) CDU-F Combining and Distribution Unit Product Description EN/LZT 720 0237 R1A The Combining and Distribution Unit (CDU) is the interface between the transceivers (TRUs) and the antenna system.
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3(8) 1 Product Overview A range of CDU types have been developed to support different configurations. The choice depends on operator’s initial and future requirements. The following factors should be taken into consideration when selecting CDU type: • Initial cost • Capacity and coverage requirements • Number of antennas. CDU-F handles one to six dTRUs. CDU-F is used in high capacity, medium output power configurations. It supports both synthesiser and baseband frequency hopping.
4(8) 7DEOH &'8 ) 6L]H DQG ZHLJKW +HLJKW :LGWK 400 mm 142 mm (9 HE x 44.45 mm) (28 TE x 5.08 mm) 1) The upper part protrudes 90 mm 3 'HSWK :HLJKW 239 + 90 mm1) 15 kg Power Consumption and Heat Generation Figures for power consumption and heat generation are shown in the table below.
5(8) 7; SDUW GHVFULSWLRQ CDU-F has four filter cavities grouped internally two and two. The two filters form a combiner for two TX signals and can be combined with a Combining Network Unit (CNU) to a combiner for four signals, or connected to another CDU-F to form a combining network for six signals. The combined signals are fed through a lowpass TX filter to a duplex filter. The duplex filter allows the use of a single antenna both for transmitting and receiving.
6(8) 5 Interfaces The external interfaces of CDU-F are listed in the table below. 7DEOH ,QWHUIDFHV RQ &'8 ) ,QWHUIDFH 7\SH RI FRQQHFWRU TX/RX, RX 7-16 female RX1, RX2 QMA female TX1 − TX4 TNC female Pf in1, PF in2, Pr in1, Pr in2 SMA female Pf out1, Pf out2, Pr out1, Pr out2 SMA female FC N female CDU bus 9-pin male, D-sub DC in 2-pin male Molex Mini-Fit CDU-F has the following indicators on the front panel. CDU-F Fault Oper. Fault Oper.
7(8) 7DEOH ,QGLFDWRUV RQ &'8 ) &RORXU /DEHO Red, Fault 0RGH ,QGLFDWLRQ Off No fault is localised in the unit On One or more faults are localised in the unit The unit has detected lost communication to a superior unit.
8(8) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(6) CDU-G Combining and Distribution Unit Product Description EN/LZT 720 0236 R1A The Combining and Distribution Unit (CDU) is the interface between the transceivers (TRUs) and the antenna system. CDU-G 900 Fault Oper.
2(6) Contents EN/LZT 720 0236 R1A 1 1.1 1.2 Product Overview Main Functions Variants 3 3 3 2 Dimensions 3 3 Power Consumption and Heat Generation 4 4 4.1 4.
3(6) 1 Product Overview A range of CDU types have been developed to support different configurations. The choice depends on operator’s initial and future requirements. The following factors should be taken into consideration when selecting CDU type: • Initial cost • Capacity and coverage requirements • Number of antennas. CDU-G handles one or two dTRUs. Connected to one dTRU, it provides a low capacity, high output power configuration.
4(6) Table 1 CDU Size and weight Height 400 mm (9 HE x 44.45 mm) 1) 3 Depth Weight 239 + 90 mm1) 15 kg The upper part protrudes 90 mm Power Consumption and Heat Generation Table 2 4 Width 142 mm (28 TE x 5.08 mm) Power consumption and heat generation Max power consumption Max heat generation 30 W 30 W Function Description TXLP Tx 1 DPX MCU T Filter unit 1 C Rx 1 MR Rx 2 D Filter unit 2 Tx 2 TXLP DPX MCU T P007449A Figure 1 Block diagram of CDU-G 4.
5(6) The TX part contains a lowpass filter and a duplex filter. The lowpass filter (TXLP) secures the required reverse isolation. It also reduces spuriouses from the transmitter on frequencies higher than the TX band. The duplex filter (DPX) enables the use of a single antenna for both transmitting and receiving. There is a Measurement Coupler Unit (MCU) between the DPX and antenna connector.
6(6) CDU-G has the following indicators on the front panel. CDU-G 900 Fault Oper. Fault Oper. CDU bus P008387A Figure 2 CDU-G indicators Table 4 CDU-G indicators Colour, Label Red, Fault Mode Indicates Off No fault is localised in the unit On One or more faults are localised in the unit The unit has detected lost communication to a superior unit.
EN/LZT 720 0239 R1B Combined Climate Unit Climate Unit for RBS 2106 Description The climate unit maintains the internal environment regarding temperature and humidity within allowed ranges for the units inside the cabinet. The climate unit is mounted in the door of the cabinet.
Climate Unit for RBS 2106 Combined Climate Unit Contents 2 (8) 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Power Consumption 3 4 4.1 4.2 4.3 4.4 4.5 4.6 4.7 Function Description Heat Exchanger Active Cooler Heater Climate Control Unit DC/DC Converter AC/DC Converter Transformer 4 4 5 5 5 6 6 6 5 5.1 5.
Combined Climate Unit Climate Unit for RBS 2106 1 Product Overview 1.1 Main Functions The Combined Climate Unit for the RBS 2106 has the following main functions: • 2 Provides the RBS cabinet with cooling or heating to maintain the operating temperature within specified limits.
Climate Unit for RBS 2106 4 Combined Climate Unit Function Description Combined Climate Unit RBS CCU DC/DC AC/DC Transformer Return Air Heat Exchanger Sub Racks Heater Active Cooler Condensor Evaporator Supply Air P008419A Figure 1 Block diagram The Combined Climate Unit consists of the following units: 4.
Combined Climate Unit Climate Unit for RBS 2106 The outside air circulates through one side of the heat exchanger and the inside air circulates through the other side. DC-powered fans force the air through the heat exchanger. The inside air is cooled by the outside air. 4.2 Active Cooler This unit consists of a compressor, reducing valve, condenser, evaporator and an AC-powered condenser fan. The liquid coolant passes through a reducing valve, where it evaporates to a cold low-pressure gas.
Climate Unit for RBS 2106 Combined Climate Unit contain the climate unit internal interfaces to DC power, AC power, fans, compressor, temperature sensors, and so on. The front panel contains indicators, connectors for the EPC bus and a 25-pole D-sub connector for test and control.
Combined Climate Unit Climate Unit for RBS 2106 5 Interfaces 5.1 Signal and Power Interfaces The Combined Climate Unit has the following external interfaces: 5.2 • DC power • AC mains power • EPC bus (on CCU) • Test and general signals (25-pole D-sub on CCU) Operator Interfaces CCU FA ULT View of Backplane OPER ATION HEAT FAUL T INT.FA N EXT.F AN PWR.F AULT EPC BU S ACT.C OOLFAN ACT.
Climate Unit for RBS 2106 Combined Climate Unit The CCU front panel has the following MMI interfaces: • Indicators • Test button • Test and control connector Indicators Table 3 Indicators Indicator Colour CCU Fault Red Operation Green Heater fault Yellow Heat exchanger internal fan fault Yellow Heat exchanger external fan fault Yellow Power fault Yellow EPC bus fault Yellow Active cooler fan fault Yellow Active cooler fault Yellow Ericsson AB SE-164 80 Stockholm Sweden implemen
1(6) CXU-10 Configuration Switch Unit Unit Description EN/LZT 720 0240 R1A The Configuration Switch Unit (CXU) distributes the RX signals from the CDU to the dTRU within the same RBS.
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3(6) 1 Product Overview The CXU cross-connects the CDU and the dTRU in the RX path. The CXU makes it possible to expand or reconfigure a cabinet with a minimum of moving or replacing of RX cables. The CXU is a multi-band product for GSM 800, GSM 900, GSM 1800 and GSM 1900.
4(6) 4 Function Description CXU CDU bus RX1_TRU1 RX2_TRU1 Powersupply RX1_CDU1 RX2_CDU1 RX1_TRU2 RX2_TRU2 RX1_CDU2 RX1_TRU3 RX2_TRU3 RX2_CDU2 RX1_TRU4 RX2_TRU4 RX1_TRU5 RX2_TRU5 RX1_CDU3 RX2_CDU3 RX1_TRU6 RX2_TRU6 P007459A )LJXUH %ORFN GLDJUDP RI WKH &;8 )XQFWLRQV The CXU has six different switches. By setting the switches in different positions, the CXU can be configured to connect radio signals from a specific CDU to a specific RX input on a dTRU.
5(6) The RF cables between the CDU and CXU and the CXU and dTRU are supervised by the CXU. 5 Interfaces 6LJQDO DQG 3RZHU ,QWHUIDFHV 7DEOH &RQQHFWRUV )XQFWLRQ 4W\ Input for RX signal from CDU 6 Output for RX signal to dTRU 12 CDU Bus connector for alarm and configuration setting 1 Power supply connector 1 2SHUDWRU ,QWHUIDFH 7DEOH ,QGLFDWRUV ,QGLFDWRU &RORXU Operational Green Fault Red EN/LZT 720 0240 R1A
6(6) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(4) DCCU DC Connection Unit Unit Description EN/LZT 720 0224 R1A The DC Connection Unit (DCCU) distributes primary power to the Power Supply Units.
2(4) Contents EN/LZT 720 0224 R1A 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Function Description 3 4 4.
3(4) 1 Product Overview 1.1 Main Functions The DCCU distributes primary power to the PSUs and it has the following functions: 2 • Terminates incoming DC supply cables • Disconnects incoming DC supply • Filters EMC Dimensions The DCCU has the following physical characteristics: Table 1 Size and weight Height Width Depth Weight 293.
4(4) 4.1 Signal and Power Interfaces The tables below show input and output data. Table 2 Input Data Voltage -40 – -72 V DC External fuses 4 pcs, max. 40 A Cable diameter 4.5 – 7 mm Conductor area 6 – 10 mm2 Number of conductors 2 Table 3 Output Data Conductor area 6 mm2 Number of conductors 2 Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.
EN/LZT 720 0301 R1A DC/DC Converter +24 V DC to -48 V DC/DC Converter for RBS 2106 Description The DC/DC Converter converts +24 V DC into regulated –48 V DC with an output power of 200 W. DC/DC Stop adjust Start test Stop test U in test Input OK fail U out test I out test U Input stop Alarm In 10 A Fail Out adj.
+24 V DC to -48 V DC/DC Converter for RBS 2106 DC/DC Converter Contents 2 (8) 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Power Consumption and Heat Generation 3 4 Function Description 4 5 5.1 5.
DC/DC Converter 1 +24 V DC to -48 V DC/DC Converter for RBS 2106 Product Overview The DC/DC converter converts +24 V DC battery voltage to regulated –48 V DC. The output power capacity is 200 W. 1.1 Main Functions The DC/DC Converter has the following main functions: 2 • Voltage converter • Current limitation • Voltage regulation • Overvoltage and undervoltage protection • Switch on the front for switching on and off. The switch also serves as a circuit breaker for input voltage.
+24 V DC to -48 V DC/DC Converter for RBS 2106 4 DC/DC Converter Function Description Input +24 V DC = = Output -48 V DC Output -48 V DC Input ALARM Input Stop U in test Start test Stop test Control Circuit Output FAIL U out test I out test P009809A Figure 1 Block diagram The unit is a switched converter, that converts +24 V DC battery voltage to regulated –48 V DC. The converter can be connected in parallel with other converters to operate continuously in current limitation mode.
DC/DC Converter +24 V DC to -48 V DC/DC Converter for RBS 2106 A red indicator on the front is active when the output voltage is out of limits due to either overload, overvoltage, or failure.
+24 V DC to -48 V DC/DC Converter for RBS 2106 5.1 DC/DC Converter Signal and Power Interfaces Input data Table 3 Input power data Nominal voltage +24 V DC Permitted variations +18.0 to 31.0 V DC Undervoltage protection +18.0 to 21.0 V DC Default start level +23.5 ±0.2 V DC Default stop level +18.5 ±0.2 V DC Rated power 200 W Output data Table 4 Output power data Rated voltage -48 V DC Setting range -46.0 to –57.0 V DC Default output 54 V DC Overvoltage protection -57.5 to 59.
DC/DC Converter +24 V DC to -48 V DC/DC Converter for RBS 2106 • Uin test port • Uout test port • Iout test port Indicators Table 5 EN/LZT 720 0301 R1A Indicators Indication Colour Input OK Green Output fail Red 7 (8)
+24 V DC to -48 V DC/DC Converter for RBS 2106 Ericsson AB SE-164 80 Stockholm Sweden implementation.GSMsupport@era.ericsson.se 8 (8) DC/DC Converter Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
EN/LZT 720 0302 R1A DC Filter for RBS 2106 Filter for External Batteries Description The DC Filter Unit is the RBS 2106’s interface for external +24 V DC power supply.
Filter for External Batteries DC Filter for RBS 2106 Contents 2 (4) 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Function Description 3 4 4.
DC Filter for RBS 2106 1 Filter for External Batteries Product Overview The DC Filter is the interface between a +24 V DC external power source, such as a battery, and the IDM inside the RBS 2106. 1.
Filter for External Batteries DC Filter for RBS 2106 The DC Filter serves as an EMC barrier against the outside electrical environment and a mechanical barrier against the outside climatic environment. 4 Interface 4.1 Signal and Power Interface The DC Filter has the following external interfaces: • Two input terminals for 70 – 185 mm2 cables. The input terminals are of semi-enclosed clamp type. • Strain-relief clamps for cables with diameter 14 – 26 mm.
EN/LZT 720 0241 R1B DC Filter 01 for RBS 2206 Description The DC filter is the interface for +24 V DC supply to the cabinet.
DC Filter 01 for RBS 2206 Contents 2 (4) 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Function Description 3 4 4.
DC Filter 01 for RBS 2206 Product Overview 1.1 Main Functions The DC filter has the following main functions: 2 • Provides the interface for +24 V DC supply to the cabinet • Distributes +24 V DC to the Internal Distribution Module (IDM). Dimensions The DC filter has the following dimensions: Table 1 3 Dimensions Height Width Depth Weight 293.5 mm 164 mm 70 mm 6 kg (incl.
DC Filter 01 for RBS 2206 Table 2 Input data Non-destructive range Nominal +24 V DC Range 20.0 – 29.0 V DC 0.0 - +32.0 V DC Max input current 200 A Input voltage Ericsson AB SE-164 80 Stockholm Sweden implementation.GSMsupport@era.ericsson.se 4 (4) Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(6) dTRU Double Transceiver Unit Unit Description EN/LZT 720 0242 R1A The double Transceiver Unit (dTRU) is a 2-TRX replaceable unit. A TRX is a transmitter/receiver and signal-processing unit, which transmits and receives one carrier.
2(6) Contents EN/LZT 720 0242 R1A 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Power Consumption and Heat Generation 3 4 4.1 4.2 4.3 4.4 Function Description CPU System DSP System Radio Control System Radio System 4 5 5 5 5 5 5.1 5.
3(6) 1 Product Overview The dTRU is a 2-TRX replaceable unit. A TRX is a transmitter/receiver and signal-processing unit, which transmits and receives one carrier. There are different versions of dTRU depending on the frequency band and modulation capability, that is, both GMSK and 8PSK (EDGE) or GMSK only. The dTRU has two TX antenna terminals and four RX antenna terminals. The dTRU features a built-in hybrid combiner.
4(6) 4 Function Description CPU system RC system Radio system TX ctrl TX data DSP system Y-link RX ctrl RX data B RX data A TX1 Radio transmitter B Radio A receiver RX1 RX2 HC1 Hybrid comb CDU-TX ctrl bus TX1+TX2 HC2 DSP system Y-link RC system RX ctrl RX data B RX data A TX ctrl TX data B Radio receiver A Radio transmitter RX3 RX4 TX2 Radio System P007395A Figure 1 Block diagram of the dTRU The TRU consists of the following main blocks: EN/LZT 720 0242 R1A • CPU system • DS
5(6) 4.1 CPU System The CPU system is a control unit in the RBS. It consists of a CPU, support logic, memory and logic for handling the interfaces. 4.2 DSP System The DSP system performs all baseband signal processing necessary for one TRX. For downlink, this includes Terrestrial Protocol Handling (TPH), encoding, ciphering and burst generation. For uplink it includes equalization, combining, decoding and TPH. 4.
6(6) 5.1 • RX (front) • TX (front) • Y link Signal and Power Interfaces The Y link, CDU TX control bus, system voltage and connectors are located on the backplane. 5.
1(10) DXU-21 Distribution Switch Unit Unit Description EN/LZT 720 0244 R1A The Distribution Switch Unit (DXU) is a CPU, which acts as an interface between the transmission network and the transceivers. It also extracts timing information from the PCM link and generates a timing reference for the RBS.
2(10) Contents EN/LZT 720 0244 R1A 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Power Consumption and Heat Generation 3 4 4.1 4.2 4.3 4.4 4.5 4.6 4.7 Function Description CPU System Communication Switch System Transmission Interface Controller Power Supply Timing System Miscellaneous Logic Compact Flash Card 4 5 5 5 6 6 6 6 5 5.1 5.
3(10) 1 Product Overview The DXU-21 is a CPU, which acts as an interface between the transmission network and the transceivers. It also extracts timing information from the PCM link and generates a timing reference for the RBS. The DXU also performs supervisory tasks. The DXU-21 transmission interface has long-haul capability and can be run on both 1.544 Mbit/s (T1) and 2.048 Mbit/s (E1) PCM links. 1.
4(10) 4 Function Description DXU 13 MHz test Part of timing system OVCXO+DAC Compact Flash Card Interface CPU System OPT-inputs OPT-outputs External alarms Vcc for backplane memory MMI IOM-bus Ext. Sync. Source (GPS) Cabinet LEDs Ext. Sync. Source (ESB) Rack/Shelf/unit pos Ext. Ref source Ext. O&M (EOM) O&M Terminal (OMT) Timing bus EPC bus Transm. lines G.703-A G.703-B G.703-C Local bus Transm. Interface Controller Communication switch system G.
5(10) Electrically, the DXU-21 consists of the following main blocks: 4.1 • CPU system • Communication switch system • Transmission interface controller • Power supply • Timing system • Miscellaneous logic • Compact Flash Card CPU System The heart of the DXU-21 is a 32-bit embedded controller with a PPC 405 processor core with interfaces to a wide range of peripherals. The CPU system consists of: 4.
6(10) 4.4 Power Supply The power supply delivers all the voltages necessary for the DXU-21. The input voltage, +24 V DC, is supplied through backplane connectors. 4.5 Timing System The timing system is used for generating a 13 MHz clock signal. 4.6 Miscellaneous Logic This function contains the following: 4.7 • System voltage measurement • Temperature measurement • Power on reset Compact Flash Card The removable Compact Flash Card permits quick and easy change of the SW and IDB in the DXU.
7(10) The equipment connected to the terminals should be insulated relay contacts. A closed contact (logic zero) is required to be below 2 kΩ, and an open contact (logic one) is required to be above 100 kΩ. The current through a closed 0 contact is 1.2 mA. The alarm contacts connected to the external alarm inputs should be insulated and have a current range above 1.2 mA. The voltage between terminals with an open contact is +24 V DC.
8(10) An I2C bus is reserved for reading a memory device which identifies the source for the system. The interface is accessed through the lower backplane connector. Y Links This interface is used for communication with the dTRUs and sTRUs. The Y interface consists of 12 separate Y links. The Y links are accessed through connectors located on the front of the DXU. EPC Bus (Optical Cable) This interface is used for communication with the power supply equipment in the RBS, such as PSUs and BFU.
9(10) ESB This interface is used to synchronize several transceiver groups in the same cell, for example when one cell is built up by more than one RBS, or one cell is split between two RBSs. Note: A master-slave configuration, as in RBS 2202, is regarded as one transceiver group. The interface is accessed on the front of the DXU through a D-sub 9-pin male connector marked "ESB". 5.2 Operator Interface OMT The OMT port is used to communicate with the Operation and Maintenance Terminal.
10(10) The test interface has an SMB connector. Indicators and Buttons There are 11 indicators located on the front panel (as shown in the table below) and two buttons for DXU Reset and Local/remote.
1(6) FCU-01 Fan Control Unit Unit Description EN/LZT 720 0246 R1A The Fan Control Unit (FCU) controls and supervises the fans in the RBS 2206. It has indicators that show fan status information.
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3(6) 1 Product Overview The Fan Control Unit (FCU) controls and supervises the fans in an RBS cabinet. 0DLQ )XQFWLRQV The FCU-01 has the following main functions: 2 • Controls and supervises fans • Generates alarm • MMI for the fans Dimensions The FCU-01 has the following physical characteristics: 3 7DEOH 6L]H DQG ZHLJKW +HLJKW :LGWK 'HSWK :HLJKW 195 mm 98 mm 45 mm 0.
4(6) 4 Interface The FCU has the following interfaces: • Power in • EPC bus in • EPC bus out • Fan power and alarm (1 – 4) 6LJQDO DQG 3RZHU ,QWHUIDFH The tables below show input and output data. 7DEOH 1RPLQDO LQSXW YROWDJH +24.0 V DC ,QSXW YROWDJH 5DQJH +19.0 – +29.0 V DC 1RQ GHVWUXFWLYH YROWDJH 0.9 – +32.0 V DC ,QSXW SRZHU 4 x 45 W 7DEOH ,QSXW GDWD 2XWSXW GDWD 2XWSXW YROWDJH 9 – 28.3 V DC 2XWSXW &XUUHQW Min 1.8 A at 9 – 28.
5(6) 7DEOH $ODUP $ODUP SRV 8SRV 5 – 30 V DC $ODUP QHJ 8QHJ < 2 V DC &XUUHQW ,DODUP < 5 mA ,QGLFDWRUV 7DEOH ,QGLFDWRUV ,QGLFDWRU &RORXU Fault Red Operational Green EPC bus fault Yellow Fan 1 fault Red Fan 2 fault Red Fan 3 fault Red Fan 4 fault Red EN/LZT 720 0246 R1A
6(6) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
EN/LZT 720 0311 R1A Heat Exchanger Climate Unit Climate Unit for RBS 2106 Description The Heat Exchanger Climate Unit provides the RBS 2106 with cooling or heating to keep the operating temperature within specified limits. The unit contains a heat exchanger, a heater, air-ducts and fans.
Climate Unit for RBS 2106 Heat Exchanger Climate Unit Contents 2 (8) 1 1.1 Product Overview Main Functions 3 3 2 Dimensions 3 3 Power Consumption 3 4 4.1 4.2 4.3 4.4 4.5 Function Description Heat Exchanger Heater Climate Control Unit AC/DC Converter Autotransformer 4 4 5 5 6 6 5 5.1 5.
Heat Exchanger Climate Unit 1 Climate Unit for RBS 2106 Product Overview The Heat Exchanger Climate Unit provides the RBS 2106 with cooling or heating to keep the operating temperature within specified limits. The unit contains a heat exchanger, a heater, air-ducts and fans. 1.1 Main Functions The Heat Exchanger Climate Unit maintains the cabinet operating temperature within specified limits by heating or cooling.
Climate Unit for RBS 2106 4 Heat Exchanger Climate Unit Function Description Heat Exchanger CCU RBS AC/DC Transformer Return Air Sub Racks Heat Exchanger Heater Supply Air P008418B Figure 1 Block diagram The Heat Exchanger Climate Unit consists of the following units: 4.1 • Heat Exchanger • Heater • Climate Control Unit (CCU) • AC/DC Converter • Transformer Heat Exchanger The heat exchanger consists of a cross-flow heat exchanger and internal and external air circuit fans.
Heat Exchanger Climate Unit Climate Unit for RBS 2106 Because ambient air is used on the ‘cool’ side of the heat exchanger, cooling capacity is limited to the temperature outside the cabinet. If the ambient temperature is higher than the cabinet return air temperature, the external air circulation fan will stop to prevent the outside air warming the cabinet. 4.2 Heater The heater is placed in the internal air circuit.
Climate Unit for RBS 2106 Heat Exchanger Climate Unit Backplane and Front Panel The backplane connectors contain the climate unit internal interfaces to DC power, AC power, fans, temperature sensors, and so on. The front panel contains indicators, connectors for the EPC bus and for test and control. 4.4 AC/DC Converter The AC/DC converter is used when +24 V DC supply is shut off.
Heat Exchanger Climate Unit 5.2 Climate Unit for RBS 2106 Operator Interface CCU FAUL T View of Backplane OPER ATION HEAT FAUL T INT.FA N EXT.F AN PWR.F AULT EPC BU S TEST P009912A Figure 2 CCU The CCU front panel has the following MMI interfaces: • Test and general signals connector • EPC bus connectors • Test button • Indicators Test and Control Connector The test and general signals connector is a 25-pole D-sub connector.
Climate Unit for RBS 2106 Heat Exchanger Climate Unit Indicators Table 3 CCU front panel indicators Indicator Description Colour CCU FAULT Fault Red OPERATION Operational Green EPC BUS EPC-bus fault Yellow HEAT FAULT Heater fault Yellow HE.INT.FAN Heat exchanger internal fan fault Yellow HE.EXT.FAN Heat exchanger external fan fault Yellow PWR. FAULT Power fault Yellow EPC-bus Connectors The EPC-bus is an optical communication bus used for RBS communication.
1(6) IDM Internal Distribution Module Unit Description EN/LZT 720 0247 R1A The Distribution Module (IDM) distributes +24 V DC to all DC powered units in the RBS. IDM-0 1 DC ou t Clim ate 15A 30A Fan 1 5A Fan 2 5A Fan 3 5A Fan4 5A TRU 1 30A TRU 2 30A CDU 1 5A TRU 3 30A TRU 4 30A CDU 2 5A TRU 5 30A TRU 6 30A CDU 3 CXU 1-2 5A DXU/S DXU 5 ys. OX U1 Volt.S ens.
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3(6) 1 Product Overview The Internal Distribution Module distributes +24 V DC to all DC powered units in the RBS. Distribution circuits are protected by circuit breakers. 0DLQ )XQFWLRQV The IDM consists of a unit with 21 circuit breakers, four PSU cables and connectors to the different DC powered units.
4(6) 4 Interface 6LJQDO DQG 3RZHU ,QWHUIDFH ,QSXW 'DWD 7DEOH ,QSXW GDWD 1RPLQDO LQSXW YROWDJH UDQJH ,QSXW YROWDJH 24 V DC +20.0 – +29.0 V DC 1RQ GHVWUXFWLYH UDQJH 0.0 – +32.0 V DC ,QSXW SRZHU 4800 W 2XWSXW 'DWD Maximum voltage drop from the input to the output of the IDM is 0.3 V DC. 7DEOH EN/LZT 720 0247 R1A &LUFXLW EUHDNHU FDSDFLW\ &LUFXLW EUHDNHU &DSDFLW\ 4XDQWLW\ CXU 1 – 2, OXU 5 5A 1 Fan 1 – 4 5A 4 OXU 1 – 4 5A 4 DXU 5A 1 CDU 1 – 3 5A 3 DC out 15A 1 TRU 1 –
5(6) 3RZHU 'LVWULEXWLRQ &RQQHFWRUV 7DEOH &RQQHFWRUV &RQQHFWRU )XQFWLRQ P3 DC out P4 Climate unit P5 Fan 1 – 4 P6 TRU 1 P7 TRU 2 P8 CDU 1 P9 TRU 3 P10 TRU 4 P11 CDU 2 P12 TRU 5 P13 TRU 6 P14 CDU 3 P15 CXU 1 P16 CXU 2 P17 OXU 5 P18 DXU/System voltage sensor/OXU 1 – 4 P19 Test connector P20 Indicator 2SHUDWRU ,QWHUIDFH ,QGLFDWRU 7DEOH ,QGLFDWRU ,QGLFDWRU &RORXU Operational Green EN/LZT 720 0247 R1A
6(6) Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
1(8) PSU AC Power Supply Unit Unit Description EN/LZT 123 0249 R1A The Power Supply Unit (PSUs) constantly regulate and deliver 1200 W power over the whole output range from 22 to 29 V DC. PSU-AC OUTPUT +27.
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3(8) 1 Product Overview The PSU rectifies the incoming AC power to the regulated DC voltage required. 0DLQ )XQFWLRQV The PSU AC does the following: • Communicates with the DXU • Handles alarms • Adjusts voltage • Provides power limitation 9DULDQWV PSU 1200 W is available in two versions: PSU 230 AC and PSU -48 DC. 2 Dimensions The PSU AC has the following physical characteristics. 7DEOH 3 368 $& GLPHQVLRQV +HLJKW :LGWK 'HSWK :HLJKW 262 mm 61 mm 225 mm 3.
4(8) AC Mains Bridge Boost DC/DC Output Filter Function Description Input Filter 4 DC Output Control and Supervision Indicators Opto Interface Control Alarm P007804A The PSU AC consists of the following main units: • Input filter (EMC filter) • Bridge • Boost converter • DC/DC converter • Output filter (EMC filter) • Control and supervision circuits ,QSXW ILOWHU (0& ILOWHU The incoming sine voltage first passes through an internal fuse and then the input filter, where it is
5(8) '& '& FRQYHUWHU The DC/DC Converter is a phase-shifted, soft-switched, full-bridge converter that converts the incoming 400 V DC to 24 V DC output voltage. The output provides constant power regulation, rather than the more common current limited, and delivers 1200 W over the whole output range from 22 to 29 V DC. 2XWSXW ILOWHU (0& ILOWHU The output voltage is filtered to prevent unwanted signals from being radiated from the PSU.
6(8) 5 Interfaces PSU-AC OUTPUT +27.
7(8) 6LJQDO DQG 3RZHU ,QWHUIDFHV ,QSXW 'DWD 7DEOH ,QSXW GDWD 1RPLQDO LQSXW YROWDJH 120 to 250 V AC (1) 9DULDWLRQ LQSXW YROWDJH 108 to 275 V AC )UHTXHQF\ &XUUHQW 45 – 65 Hz < 8A at 180 – 275 V AC) < 12 A (at 108 – 140 V AC) < 30 A peak 15 A (slow) >83% cos ϕ > 0.95 0 – 300 V AC 300 V AC ,QUXVK FXUUHQW ,QWHUQDO IXVH (IILFLHQF\ 3RZHU IDFWRU 1RQ GHVWUXFWLYH YROWDJH 3XOVHV PV 1RW DOO EDVH VWDWLRQV DUH SUHSDUHG IRU 9 $& 2XWSXW 'DWD 7DEOH 2XWSXW GDWD 1RPLQDO RXWSXW GDWD +24 V
8(8) ,QGLFDWRUV 7DEOH ,QGLFDWRUV ,QGLFDWLRQ &RORXU Fault Red Operational Green EPC Bus Fault Yellow Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
EN/LZT 720 0248 R1B PSU DC Power Supply Unit Description The PSU DC converts incoming voltage ranging from -39 V to -72 V DC to the regulated DC voltage that is required. PSU-DC OUTPUT +27.
Power Supply Unit PSU DC Contents 2 (6) 1 1.1 Product Overview Main functions 3 3 2 Dimensions 3 3 Power Consumption and Heat Generation 3 4 4.1 4.2 4.3 4.4 FunctionDescription Input filter DC/DC Converter Output filter (EMC filter) Control and supervision circuits 4 4 4 5 5 5 5.1 5.
PSU DC 1 Power Supply Unit Product Overview The PSU DC converts incoming voltage ranging from -39 V to -72 V DC to the regulated DC voltage that is required. 1.1 Main functions The PSU DC has the following functions: 2 • Communication • Handles alarms • Adjusts voltage • Provides power limitation Dimensions Table 1 3 Height Width Depth Weight 262 mm 61 mm 225 mm 3.
Power Supply Unit DC Input DC/DC Output Filter FunctionDescription Input Filter 4 PSU DC DC Output Control and Supervision Indicators Opto Interface Control Alarm P007805A Figure 1 PSU –DC block diagram The PSU DC consists of the following main units: 4.
PSU DC 4.3 Power Supply Unit Output filter (EMC filter) The ouput filter filters the output voltage to prevent unwanted signals from being radiated from the PSU. 4.4 Control and supervision circuits The control and supervision circuits support: • Load sharing between parallel units • Remote on/off • Alarms The output voltage can be adjusted between 22 V to 29 V DC. The control and supervision is achieved through an optical signal interface connector on the front of the PSU. 5 Interface 5.
6(6) Output Data Table 4 5.2 Output data Nominal output voltage +24 V DC Factory set value +27.2 ± 0.1 V DC Voltage range 22.0 – 29.0 V DC Output power 1200 W Output current at 27.2 44.
1(6) TMA-CM Tower Mounted Amplifier - Control Module Unit Description EN/LZT 720 0250 R1A The Tower Mounted Amplifier Control Module (TMA-CM), together with the bias injectors, supply power to the TMA. It also monitors and controls the TMAs. TMA CM-01 Fault Oper. TMA oper.
2(6) Contents EN/LZT 720 0250 R1A 1 1.1 Product Overview Main Functions 3 3 2 Function Description 4 3 3.1 3.
3(6) 1 Product Overview 1.
4(6) 2 Function Description IOM Bus Indicator Control TMA Support x x x x x x x x Fault Oper. TMA1 TMA2 TMA3 TMA4 TMA5 TMA6 DC/DC Converter Indicators TMA1 TMA2 TMA3 TMA4 TMA5 TMA6 Measurement +24V DC P008456B Figure 1 Block diagram The TMA-CM supplies up to six TMAs with 15 V DC and maximum 500 mA to each TMA. The power output is a 15-pole d-sub connector on the front of the TMA-CM. A TMA consumes in general 70 − 200 mA. The TMAs can be individually switched on and off by commands from the DXU.
5(6) The power cable to the bias injector is supervised and an alarm is generated if the cable is not connected. The alarm is transmitted on the IOM bus. 3 Interface 3.1 Signal and Power Interface Table 1 Nominal input voltage +24 V DC Input voltage range +20.0 – 29.5 V DC Non-destructive voltage 0 – +32 V DC Maximum input power 60 W Table 2 Output data Voltage per output (1 – 6) +15 V DC (1) Current per output Maximum 500 mA (1) 3.2 Input data Tolerance ±1.
6(6) Table 3 Indicators Indicator Colour Fault Red Operational Green TMA1 operating Green TMA2 operating Green TMA3 operating Green TMA4 operating Green TMA5 operating Green TMA6 operating Green Ericsson Radio Systems AB Mobile Telephone Systems Division Mobile Systems SE-164 80 Stockholm, Sweden Implementation.GSM support@era.ericsson.se Due to continued progress in methodology, design and manufacturing, the contents of this document are subject to change without notice.
EN/LZT 720 0283 Uen R1A RBS 2000 Glossary This document provides a glossary of terms and abbreviations used in RBS 2000 Customer Product Information (CPI).
Glossary RBS 2000 Contents 2 (22) 7HUPV DQG $EEUHYLDWLRQV EN/LZT 720 0283 Uen R1A
RBS 2000 1 Glossary Terms and Abbreviations This glossary lists abbreviations and acronyms used in texts dealing with RBS 2000 cabinets. Some basic terms and acronyms needed for cross-reference are included in the list. An arrow ⇒ is used to indicate a reference to another entry in the list.
Glossary RBS 2000 $5$( Antenna Related Auxiliary Equipment $5)&1 Absolute Radio Frequency Channel Number $53 Antenna Reference Point $58 Active Replaceable Unit $6,& Application Specific Integrated Circuit $VWUD ASIC in the TRU $68 Antenna Sharing Unit $7 Alphanumeric Terminal $758 Adaptive Transceiver Unit $765 Air Time Slot Resource $8 Antenna Unit GSM 900 = CEU + Passive Antenna GSM 1800/1900 = AAU %$/81 BALance and UNbalance transformer %DWW Battery %% Battery Box %%6 Batt
RBS 2000 Glossary %)8 Battery Fuse Unit %LDV LQMHFWRU A unit which injects DC power into the coaxial cable to feed the TMA. Isolates the DC power from the RF signal fed to the CDU. %P Denotes a full-rate traffic channel %3& Basic Physical Channel Denotes the air interface transport vehicle formed by repetition of one time slot on one or more radio frequency channels. %6 Base Station %6& Base Station Controller GSM network node for control of one or more BTSs.
Glossary RBS 2000 &%&+ Cell Broadcast CHannel This is a downlink only channel used by the GSM defined SMSCB function. &&&+ Common Control CHannel Channel combining the following common control channels: • PCH Paging CHannel • RACH Random Access CHannel • AGCH Access Grant CHannel &&8 Climate Control Unit &'8 Combining and Distribution Unit &( Conformité Européenne FHOO An area of radio coverage identified by the GSM network by means of the cell identity.
RBS 2000 Glossary &058 Central Main Replaceable Unit. The RBS is physically connected to the Base Station Controller (BSC) via the CMRU. There is only one CMRU in each RBS. 0DFUR CMRU = DXU 0LFUR CMRU = The whole RBS &18 Combining Network Unit &RPSU Compressor &21 LAPD concentrator LAPD concentration is used to reduce the number of required physical links between the BSC and BTS.
Glossary RBS 2000 '&& Digital Cross Connector '&&+ Dedicated Control CHannel Dedicated control channels carry signalling data. '&&8 DC Connection Unit GG70$ dual duplex Tower Mounted Amplifier This type needs only one combined TX/RX feeder from the BTS to the TMA. ⇒ dTMA ⇒ rTMA ⇒ TMA ⇒ BTS ') Distribution Frame ') Disturbance Frequency ')8 Distribution and Fuse Unit ',3 DIgital Path The name of the function used for supervision of the connected PCM lines.
RBS 2000 Glossary '7) Distance To Fault G70$ duplex TMA dTMA is similar to the old ALNA except for different characteristics. ⇒ ddTMA ⇒ rTMA ⇒ TMA G758 double TRansceiver Unit '8 Distribution Unit (RU in CDU-D) '87 Device Under Test '; Direct Exchange ';% Distribution Switch Board ';& Digital Cross Connector ';8 Distribution Switch Unit ';; Ericsson Cellular Transmission System including NMS ( Transmission standard, G.
Glossary RBS 2000 (0) ElectroMagnetic Field (0, Electromagnetic Interference (19 Environmental (2& Embedded Operations Channel (3& Environmental and Power Control (6 Errored Second (6% External Synchronization Bus (6' ElectroStatic Discharge (6) Extended Superframe Format (62 Ericsson Support Office (76 European Telecommunication Standard (;7 External )$&&+ Fast Associated Control CHannel Main signalling channel in association with a TCH.
RBS 2000 Glossary );8 Future Expansion Unit * MO model for RBS 200 * MO model for RBS 2000 * Physical/electrical characteristics of hierarchical digital interfaces, as defined by the ITU. * Synchronous frame structures used at 1544, 6312, 2048, 8448 and 44 736 kbit/s, as defined by the ITU.
Glossary RBS 2000 +06 Heat Management System +XP Humidity +: HardWare +:8 HardWare Unit An HWU consists of one or more SEs. An HWU is a functional unit within the RBS. The HWU is either active (equipped with a processor) or passive (without processor).
RBS 2000 Glossary -7& Joint Technical Committee /$3' Link Access Procedures on D-channel LAPD is the data link layer (layer 2) protocol used for communication between the BSC and the BTS on the Abis interface. Abis layer 2 is sometimes used synonymously with LAPD. /%2 Line Build Out /(' Light Emitting Diode //% Line Loop Back /1$ Low Noise Amplifier /RFDO EXV The local bus offers communication between a central main RU (DXU) and distributed main RUs (TRU and ECU).
Glossary RBS 2000 /26 Loss Of Signal /9' Low Voltage Directive /9) Low Voltage Filter 0$& Medium Access Controller 0$'7 Mean Accumulated DownTime PDJD]LQH A magazine is a reserved space in the cabinet, which may hold one or more RUs. 0DLQ 58 Contains one or more processors, to which software can be downloaded from the BSC. A Main RU is either Central (CMRU) or Distributed (DMRU). A Main RU may or may not have a direct signalling link to the BSC.
RBS 2000 Glossary 0XOWLGURS Two or more RBSs connected in a chain to the same transmission system. All the relevant time slots are dropped out by each RBS. (This function is sometimes called cascading.) 1&6 National Colour System 1(%6 Network Equipment Building System 106 Ericsson Network Management System in DXX 1RPLQDO 3RZHU The nominal power is the power level defined when configuring the transceiver.
Glossary RBS 2000 3$ Power Amplifier 3$0 Power Amplifier Module 3DVVLYH 58 A passive replaceable unit has a very low level of intelligence and is independent of the processor system. 3%$ Printed Board Assembly 3%& Power and Battery Cabinet 3& Personal Computer 3&$7 Product CATalogue A web-based ordering system on Ericsson’s Intranet. 3&% Printed Circuit Board 3&+ Paging CHannel Downlink only subchannel of CCCH for system paging of MSs.
RBS 2000 Glossary 3/01 Public Land Mobile Network A network, established and operated by an administration or its licensed operator(s), for the specific purpose of providing land mobile communication services to the public. It provides communication possibilities for mobile users. For communication between mobile and fixed users, interworking with a fixed network is necessary.
Glossary RBS 2000 5) Radio Frequency 5)&+ Radio Frequency CHannel A radio frequency carrier with its associated bandwidth. 5)7/ Radio Frequency Test Loop 5/& Radio Link Control 5/& Repair Logistic Centre 56/ Radio Signalling Link 5 VWDWH Release state 56 American standard for term/MODEM interconnection. U70$ Receiver TMA rTMA has no duplexers. It is used for amplification of the RX signal. ⇒ ddTMA ⇒ dTMA ⇒ TMA 571 Return 58 Replaceable Unit An RU consists of one or more HWUs.
RBS 2000 Glossary 6$&&+ Slow Associated Control CHannel 6&+ Synchronization CHannel 6'&&+ Stand alone Dedicated Control CHannel Main dedicated signalling channel on the air interface, mainly used for call locating and establishment.
Glossary RBS 2000 7$ Timing Advance A signal sent by the BTS to the MS which the MS uses to advance its timing of transmissions to the BTS to compensate for propagation delay. 7& Transaction Capabilities 7&% Transceiver Control Board 7&+ Traffic CHannel The traffic channels carry either encoded speech or user data.
RBS 2000 Glossary 70 Transport Module The Transport module is non-RBS equipment belonging to the transport network. 70$ Tower Mounted Amplifier There are three types of TMAs: dTMA, rTMA and ddTMA.
Glossary RBS 2000 7;% Transmitter Antenna B 7;%3 Transmitter BandPass filter 7;8 Radio Transmitter Unit 8$6 Unavailable Seconds 8$67 UnAvailable STate supervision 8/ Underwriter Laboratories XSOLQN Signalling direction from the MS to the system. 836 Uninterrupted Power Supply 9&2 Voltage Controlled Oscillator 96:5 Voltage Standing Wave Ratio RF signal measure. The quotient between transmitted and reflected voltage. ; EXV The X bus carries transmit air data frames between transceivers.