User's Manual
Table Of Contents
- SECTION 1 General Information
- SECTION 2 InterReach Fusion Wideband System Description
- SECTION 3 Fusion Wideband Main Hub
- SECTION 4 Fusion Wideband Expansion Hub
- SECTION 5 Remote Access Unit
- SECTION 6 Designing a Fusion Wideband Solution
- SECTION 7 Installing Fusion Wideband
- 7.1 Installation Requirements
- 7.2 Safety Precautions
- 7.3 Preparing for System Installation
- 7.4 Fusion Wideband Installation Procedures
- 7.5 Splicing Fiber Optic Cable
- 7.6 Interfacing the Fusion Wideband Main Hub to an RF Source
- 7.7 Connecting Contact Alarms to a Fusion Wideband System
- 7.8 Alarm Monitoring Connectivity Options
- SECTION 8 Replacing Fusion Wideband Components
- SECTION 9 Maintenance, Troubleshooting, and Technical Assistance
- APPENDIX A Cables and Connectors
- A.1 75 Ohm CATV Cable
- A.2 Fiber Optical Cables
- A.3 Coaxial Cable
- A.4 Standard Modem Cable
- A.5 TCP/IP Cross-over Cable
- A.6 DB-9 to DB-9 Null Modem Cable
- APPENDIX B Compliance
- B.1 Fusion Wideband System Approval Status
- B.2 Human Exposure to RF
- APPENDIX C Faults, Warnings, Status Tables for Fusion, Fusion Wideband, Fusion SingleStar
- C.1 Faults Reported by Main Hubs
- C.2 Faults Reported for System CPU
- C.3 Faults for Expansion Hubs
- C.4 Faults for RAUs
- C.5 Messages for Main Hubs
- C.6 Messages for System CPUs
- C.7 Messages for Expansion Hubs
- C.8 Messages for RAUs
Link Budget Analysis
6-30 InterReach Fusion Wideband Installation, Operation, and Reference Manual
CONFIDENTIAL D-620616-0-20 Rev F
The open-loop power control equation is
P
TX
+ P
RX
= –73 dBm (for Cellular, IS-95)
P
TX
+ P
RX
= –76 dBm (for PCS, J-STD-008)
where P
TX
is the mobile’s transmitted power and P
RX
is the power received by the
mobile.
The power level transmitted under closed-loop power control is adjusted by the base
station to achieve a certain E
b
/N
0
(explained in Table 6-29 on page 6-30). The differ-
ence between these power levels,
P
, can be estimated by comparing the power radi-
ated from the RAU, P
downink
, to the minimum received signal, P
uplink
, at the RAU:
P
= P
downink
+ P
uplink
+ 73 dBm (for Cellular)
P
= P
downink
+ P
uplink
+ 76 dBm (for PCS)
It’s a good idea to keep –12 dB <
P
< 12 dB.
Table 6-29 provides link budget considerations for CDMA systems.
Table 6-29 Additional Link Budget Considerations for CDMA
Consideration Description
Multipath Fade
Margin
The multipath fade margin can be reduced (by at least 3 dB) by using different lengths of optical fiber (this
is called “delay diversity”). The delay over fiber is approximately 5µS/km. If the difference in fiber
lengths to Expansion Hubs with overlapping coverage areas produces at least 1 chip (0.8µS) delay of one
path relative to the other, then the multipaths’ signals can be resolved and processed independently by the
base station’s rake receiver. A CDMA signal traveling through 163 meters of MMF cable is delayed by
approximately one chip.
Power per car-
rier, downlink
This depends on how many channels are active. For example, the signal is about 7 dB lower if only the
pilot, sync, and paging channels are active compared to a fully-loaded CDMA signal. Furthermore, in the
CDMA forward link, voice channels are turned off when the user is not speaking. On average this is
assumed to be about 50% of the time. So, in the spreadsheet, both the power per Walsh code channel (rep-
resenting how much signal a mobile will receive on the Walsh code that it is de-spreading) and the total
power are used.
The channel power is needed to determine the maximum path loss, and the total power is needed to deter-
mine how hard the Fusion Wideband system is being driven.
The total power for a fully-loaded CDMA signal is given by (approximately):
total power =
voice channel power + 13 dB + 10log
10
(50%)
= voice channel power + 10 dB
Information Rate This is simply
10log
10
(9.6 Kbps) = 40 dB for rate set 1
10log
10
(14.4 Kbps) = 42 dB for rate set 2