RFoG Radio Frequency Over Glass 1.1GHz Fiber Coax Hybrid for DAVIC And DOCSIS
| Place of Origin: | Zhejiang |
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Company Profile
| Location: | Nanjing, Jiangsu, China (Mainland) |
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| Business Type: | Manufacturer |
| Main Products: | DOCSIS Devices, EOC Master, EOC Slave |
Product Detail
| Model No.: | MN 100S |
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Product Description
RFoG Radio Frequency Over Glass 1.1GHz Fiber Coax Hybrid for DAVIC And DOCSIS
Overview
Lootom MN100S RF PON Transceiver offer the operators competitive advantage and enormous flexibility over the traditional HFC architectures --- avail enough the existing RF and DOCSIS technology to deploy a fiber optic distribution network.
Lootom MN100 operate over a standard Passive Optical Network(PON) ODN architectures using a standard HFC optical wavelength, connect to cable modems, televisions and set-top boxes through the existing coaxial cable, don’t need the neighboring HFC nodes and the annual testing and maintenance.
Lootom MN100 allows PON, RFoG and mixed PON network to extend the bi-directional and interactive RF business through the passive optic distribution network, it could be used at the same optic cable which PON access to support the voice, video and data business. Lootom MN100 RF transceiver provides bi-directional services over extended RF frequencies (up to 1.1GHz) while being agnostic to head-end equipment, customer equipment, and compatible with today’s operating processes.
Features:
- Local or remote power supply
- Die-casting aluminum housing, excellent heat dissipation performance
- It is compatible with DAVIC and DOCSIS
- For FTTH
- Using the low noise pHEMT GaAs FET as the first RF amplify module, fit to low optic power input
- Support the universal HFC set-top box, cable modem and head-end equipment
- Transparent return path capability (protocol and modulation format are transparent)
- Optical AGC function ( reach the positive RF level)
- Reduce the convergence noise
Diagram
Technical parameters
|
No |
Item |
Unit |
Description |
Remark |
||||||
|
Physical |
||||||||||
|
1 |
dimension |
mm |
31×128×78 |
H×W×D |
||||||
|
Optic connector |
||||||||||
|
5 |
optic connector |
|
SC/APC |
|
||||||
|
|
||||||||||
|
8 |
input wavelength |
nm |
15251565 |
|
||||||
|
9 |
input power range |
dBm |
-80 |
|
||||||
|
10 |
Loss of signal alarm threshold |
dBm |
<-8 |
|
||||||
|
11 |
bandwidth |
MHz |
54/87862(1000) |
|
||||||
|
12 |
flatness |
dB |
±0.75 |
at the worst condition |
||||||
|
13 |
impedance |
Ω |
75 |
|
||||||
|
14 |
RF output level |
dBmV |
24±2 |
OMI=3.7, %, at -4dBm input power |
||||||
|
15 |
RF return loss |
dB |
16 |
at the worst condition |
||||||
|
16 |
RF output test point |
-dB |
20±0.75 |
|
||||||
|
17 |
CNR |
dBc |
48 |
-4dBm input power |
||||||
|
18 |
CTB |
dBc |
70 |
-4dBm input power |
||||||
|
19 |
CSO |
dBc |
65 |
-4dBm input power |
||||||
|
return path parameter |
|
|||||||||
|
20 |
bandwidth |
MHz |
1042/65 |
at the worst condition |
||||||
|
21 |
Flatness |
± dB |
0.75 |
|
||||||
|
22 |
impedance |
Ω |
75 |
|
||||||
|
23 |
RF return loss |
- dB |
16 |
at the worst condition |
||||||
|
24 |
RF input level |
dBmV |
20 |
|
||||||
|
25 |
RF input test point |
-dB |
20±0.75 |
|
||||||
|
26 |
laser |
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