Features
Ø Supports up to 10.7Gbps bit rates
Ø Hot-pluggable SFP+ footprint
Ø 1550nm Cooled EML laser and APD photodiode, Up to 80km for SMF transmission
Ø Compliant with SFP+ MSA and SFF-8472 with duplex LC receptacle
Ø Compatible with RoHS
Ø Single +3.3V power supply
Ø Real Time Digital Diagnostic Monitoring
Ø Operating case temperature:
Commercial : -5 to +70°C
Extended: -20~+80℃
Industrial : -40 to +85°C
Applications
Ø 10Gbps Optical systems
Ø 10GBASE-ZR at 10.3125Gbps
Ø 10GBASE-ZW at 9.953Gbps
Ø LTE systems
Ø Other Optical links
Description
The SFP+ transceivers are high performance, cost effective modules supporting data rate of 10Gbps and 80km transmission distance with SMF.
The transceiver consists of three sections: a Cooled EML laser transmitter, a APD photodiode integrated with a trans-impedance preamplifier (TIA) and MCU control unit. All modules satisfy class I laser safety requirements.
The transceivers are compatible with SFP Multi-Source Agreement and SFF-8472 digital diagnostics functions.
Absolute Maximum Ratings
|
Parameter |
Symbol |
Min |
Max |
Unit |
|
Supply Voltage |
Vcc |
-0.5 |
4.5 |
V |
|
Storage Temperature |
Ts |
-40 |
+85 |
°C |
|
Operating Humidity |
- |
5 |
85 |
% |
Recommended Operating Conditions
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Operating Case Temperature |
Tc |
0 |
|
+70 |
°C |
|
Power Supply Voltage |
Vcc |
3.135 |
3.30 |
3.465 |
V |
|
Power Supply Current |
Icc |
|
|
600 |
mA |
|
Data Rate |
|
1.0 |
10.3 |
10.7 |
Gbps |
Optical and Electrical Characteristics
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
Notes |
||
|
Transmitter |
||||||||
|
Centre Wavelength |
λc |
1530 |
1550 |
1565 |
nm |
|
||
|
Spectral Width(-20dB) |
Δλ |
|
|
1 |
nm |
|
||
|
Side-Mode Suppression Ratio |
SMSR |
30 |
- |
|
dB |
|
||
|
Average Output Power |
Pout |
0 |
|
+4 |
dBm |
1 |
||
|
Extinction Ratio |
ER |
6.0 |
|
|
dB |
|
||
|
Data Input Swing Differential |
VIN |
180 |
|
850 |
mV |
2 |
||
|
Input Differential Impedance |
ZIN |
90 |
100 |
110 |
Ω |
|
||
|
TX Disable |
Disable |
|
2.0 |
|
Vcc |
V |
|
|
|
Enable |
|
0 |
|
0.8 |
V |
|
||
|
TX Fault |
Fault |
|
2.0 |
|
Vcc |
V |
|
|
|
Normal |
|
0 |
|
0.8 |
V |
|
||
|
Receiver |
||||||||
|
Centre Wavelength |
λc |
1260 |
|
1600 |
nm |
|
||
|
Receiver Sensitivity |
|
|
|
-23 |
dBm |
3 |
||
|
Receiver Overload |
|
-7 |
|
|
dBm |
3 |
||
|
LOS De-Assert |
LOSD |
|
|
-24 |
dBm |
|
||
|
LOS Assert |
LOSA |
-35 |
|
|
dBm |
|
||
|
LOS Hysteresis |
|
0.5 |
|
4 |
dB |
|
||
|
Data Output Swing Differential |
Vout |
300 |
|
900 |
mV |
4 |
||
|
LOS |
High |
2.0 |
|
Vcc |
V |
|
||
|
Low |
|
|
0.8 |
V |
|
|||
Notes:
1. The optical power is launched into SMF.
2. PECL input, internally AC-coupled and terminated.
3. Measured with a PRBS 231-1 test pattern @10312Mbps, BER ≤1×10-12.
4. Internally AC-coupled.
Timing and Electrical
|
Parameter |
Symbol |
Min |
Typical |
Max |
Unit |
|
Tx Disable Negate Time |
t_on |
|
|
2 |
ms |
|
Tx Disable Assert Time |
t_off |
|
|
100 |
µs |
|
Time To Initialize, including Reset of Tx Fault |
t_init |
|
|
300 |
ms |
|
Tx Fault Assert Time |
t_fault |
|
|
100 |
µs |
|
Tx Disable To Reset |
t_reset |
10 |
|
|
µs |
|
LOS Assert Time |
t_loss_on |
|
|
100 |
µs |
|
LOS De-assert Time |
t_loss_off |
|
|
100 |
µs |
|
Serial ID Clock Rate |
f_serial_clock |
|
100 |
400 |
KHz |
|
MOD_DEF (0:2)-High |
VH |
2 |
|
Vcc |
V |
|
MOD_DEF (0:2)-Low |
VL |
|
|
0.8 |
V |
Diagnostics
|
Parameter |
Range |
Unit |
Accuracy |
Calibration |
|
Temperature |
0 to +70 |
°C |
±3°C |
Internal |
|
Voltage |
3.0 to 3.6 |
V |
±3% |
Internal |
|
Bias Current |
0 to 100 |
mA |
±10% |
Internal |
|
TX Power |
-1 to +4 |
dBm |
±3dB |
Internal |
|
RX Power |
-23 to -6 |
dBm |
±3dB |
Internal |
Ordering information
|
Part Number |
Product Description |
|
HD-SFP+/10G-ZR |
1550nm, 10.3Gbps, LC, 80km, 0°C~+70°C, with DDM |
|
HD-SFP+/10G-ZR-I |
1550nm, 10.3Gbps, LC, 80km, -40°C~+85°C, with DDM |
Need Help? Contact Our Product Experts or Sales Team Today!
Related Products
Latest News & Blog
-
2025-08-05
Application and Advantages of 1×9 Optical Transceivers in Industrial Printing Systems
As industrial automation and smart manufacturing continue to evolve, communication systems within industrial printing equipment are shifting from traditional copper-based connections to more reliable fiber-optic solutions. Among various optical transmissi
-
2025-08-05
Application of Optical Modules in Mesh Network Topology
Consider employing a mesh network topology to meet your communication and data transmission needs. In this article, we will focus on the application of optical modules in mesh networks to help you better understand this critical technology. 1. High-Speed
-
2025-08-05
Unlocking the Future of Connectivity with OTN Technology
In todays rapidly evolving digital landscape, the need for reliable and efficient data transmission has never been more crucial. Enter Optical Transport Networks (OTN), a technology that is poised to revolutionize the way we connect and communicate. In th
