User's Manual
Table Of Contents
- Document History
- Revision History
- GENERAL SAFETY PRECAUTIONS
- TABLE OF CONTENTS
- LIST OF FIGURES
- LIST OF TABLES
- Introduction
- Figure 1Block Diagram of Host Unit
- Figure 2 Block Diagram of Remote Node
- Safety
- System Overview and Unit Description
- Figure 3mBSC System Functional Overview
- Figure 4 Host Unit
- Figure 5BIU
- Figure 6FIU
- Figure 7 PSU
- Figure 8RCU
- Table 1 Host Unit User Interface
- Front Panel
- Rear Panel
- Figure 10Fiber BCM Enclosure Outline
- Figure 11Fiber BCM Interior Layout
- Table 3BCM Enclosure User Interface
- Figure 12BCM Enclosure User Interface
- Table 4 Single-band RUM Enclosure User Interface
- Figure 14 Single-band RU Enclosure User Interface
- Table 5 Indicator Description
- Table 9Fiber RTM Enclosure User Interface
- Table 10 Indicator Description
- System Installation
- Figure 20 Mounting Brackets for 19” Rack Installation
- Figure 21Host Unit-19” Rack Mounting View
- Figure 22Host Unit Grounding Stud
- Figure 23 Grounded Host Unit
- Figure 24 BTS QMA Coaxial Cable Connection
- Figure 26E2000 Fiber Optic Port on Host Unit FIU
- Figure 27 48VDC Host Power Connection
- Figure 28IP Connection for local GUI Control
- Figure 29Modem Port on RCU (DB9 male)
- Figure 32 Fiber Optic Cable Connection to RTM Enclosure
- Figure 33 RPM
- Figure 36 Flow Chart of System Debugging
- System Monitoring &Configuration
- Figure 37– EMS Local GUI Login
- Figure 38- Main Page Expanded Topology
- Figure 39- Main Page Summary View
- Figure 40- RCU Component View
- Figure 41- Main Page Equipment Status
- Figure 42- FIU Optical Power Levels
- Figure 43- CM Optical Power Levels
- Table 16System Alarms
- Maintenance
- Figure 53Host Unit Trouble Shooting
- Figure 54Remote Unit Trouble Shooting
- Terms, Acronyms & Abbreviations
- IC Radiation Exposure Statement
- IC Déclaration sur la radio exposition
mBSC-C RU
mBSC0850i-040-RUC11 April 15, 2013
Page 60
5.4.4 Link Verification
The MBSC2100-005-RUCM11 system is equipped with features that enable the downlink and uplink link to
be fine-tuned from the head-end location using common test equipment (RF signal generator and RF power
detector).
5.4.4.1 Verify End-to-End Downlink Gain
Each RU in the remote node is equipped with a calibrated Downlink Power Detector which will display the
average power at the output of the RU. By injecting an RF CW signal at each TXin port of the BIU the
end-to-end downlink system gain can be verified without additional test equipment required at the Remote
Node.
Verify the end-to-end Downlink Gain for each frequency band as follows:
1. Using an RF Signal generator inject a CW RF signal to the TXin port of the BIU
a. Set the frequency to the center of the spectrum to be used in the system (if the operator
licensed bands are not known set the frequency to center of the band – e.g. 2132.5 MHz for
AWS band)
b. Set the input RF power level to be 3 – 5 dB below the expected RF level to product
maximum output power at the RU to avoid accidental overdrive (e.g. if the gain is set so that
0dBm input will produce +43 dBm at the output then start with -5dBm)
2. The resultant Downlink output power of the RU can be observed in two ways:
a. In the topology window the Downlink Output power is displayed next to the specific RU (e.g.
30.7 dBm indicated in the topology diagram by the 800MHz RU in Figure 52 – Up/Down Link
Verification)
b. Downlink Output Power: In the component window
3. Variations in filtering, amplifiers, and optical loss may cause the actual system gain to vary +/- 6 dB.
All paths can be normalized by adjusting downlink attenuation settings in the BIU.
4. This procedure should be repeated for each frequency band in the system