CFP 100G Transponder
Product Overview
HYD Technologyhas designed this CFP 100G Transponder, which offers a perfect option for optical fiber links helping to release the output power and wavelength of CFP coherent transceiver modules.
It can convert the output power and wavelength of ITU-T G.694.1 to the DWDM optical signal for wavelength. It also cooperates with the multiplexer, demultiplexer, or DWDM to divide the wavelength.
This module offers an impeccable solution to the problem of loss of transmission lines or the need for more fiber resources.
- Thai module supports one channel or 103.125Gbit/s to 111.81Gbit/s in unidirectional or bidirectional service.
- It can also offer line-side support for CFP 100G, a coherent transceiver module, or the 4*25G module.
- Its other functions comprise TX power turnoff function, hot-swappable and transparent transmission.
- The FEC function is also supported, offering an optimized output and signal monitoring of DDM with link detection.
- Multiple network management methods are supported, followed by SNMP unified network platform.
- If any enquiry ,please contact HYD TECHNOLOGY .
System Parameter | Technical Index |
Maximum capacity | 1*100G bidirectional/unidirectional transmission |
Wavelength (frequency) range | DWDM: 1529.16nm-1567.14nm(191.3THz-196.05THz) |
CFP DCO 100G/200G Optical Transmitter Specifications | |
Modulation | DP-QPSK@100G, DP-16QAM@200G, DP-QPSK@200G |
Transmitter output power range | +2~-15dBm |
Transmitter OSNR | 38dB/0.1nm(OSNR at transmitter output (in-band)) |
Channel spacing | 50GHz |
Optical return loss | 27dB |
Max. -3dB spectral width | 0.4nm |
Min. SMSR (side mode suppression ratio) | 45dB(Measured over +/-2.5nm range around the target frequency with 0.06nm RBW without modulation.) |
Laser line width | 100~300kHz(FWHM-full width at half maximum of power density spectrum of CW.) |
CFP DCO 100G/200G Optical Receiver Specifications | |
Input power range | -18~+5dBm(Signal power of the selected channel) |
OSNR Sensitivity | 14.5dB/0.1nm(At internal FEC threshold (post FEC BER < 10-15), at optimum input power as specified above.) |
Receiver sensitivity | -22dBm(Minimum input power needed to achieve post FEC BER < 10-15 when OSNR > 35dB and internal HDFEC enabled.) |
CD tolerance | 12000ps/nm(With less than 0.3dB OSNR penalty at HDFEC threshold.) |
PDL tolerance | 3dB PDL tolerance under the following conditions: 1) No additional PDL from the source 2) With additional 0.5 dB OSNR from OSNR sensitivity spec 3) Change in PSP is < =1 rad/millisecond |
Input power transient tolerance | 5dB Tolerance to variation in received power under the following conditions: 1) less than 0.5 dB OSNR penalty if the received power is within range defined in “input power range” and rise/fall times of power change (defined by 20-80%) of 50ms or slower. 2) The OSNR penalty is defined at SD- FEC threshold. |
Channel spacing | 50GHz |
Optical return loss | 27dB |
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Service access types | 100GE, OTU4 |
Dimensions (mm) | 177(W)*40(H)*225(D) |
Working temperature | -10℃~70℃ |
Storage temperature | -40℃~80℃ |
Relative humidity | 5%~95% no condensation |
Safety and EMC | Compliance with FCC, UL, CE, TUV, CSA standards |
Power consumption | <36W |
Application 1:
The 100G rates need more dispersion, and the DWDM multiplexer of 100 GHZ is used to create a combination of the 100G rates, which leads to dispersing the compensation and amplifying the signals. This transponder allows the interchange of the 100G services, and the data rate is used to extend at a longer wavelength repeatedly.
In such cases, the CFP modules create such a network architecture that the amplification stages suffice well, making it cost-effective as the existing infrastructure is reused repeatedly.
Application 2:
In some places, the switch is tested with the OEO transponders due to the requirement of long-distance extension. The 100G signals that come out of the switch are converted into DWDM signals to transmit over a longer distance due to the implementation of the CFP transponder. The limitation of distance covered in the fiber optic can easily be eliminated.
