10Gb/S 1310nm Duplex LC Single Mode SFP Optical Transceiver
10Gb/S 1310nm Duplex LC Single Mode SFP Optical Transceiver
10Gb/s 10km SFP+ Transceiver Hot Pluggable, Duplex LC, +3.3V, 1310nm DFB-LD, Single mode
Features:
- Supports 9.95 to 11.3Gb/s bit rates
- Hot-Pluggable
- Duplex LC connector
- 1310nm DFB transmitter, PIN photo-detector
- SMF links up to 10km
- 2-wire interface for management specifications compliant with SFF 8472 digital diagnostic monitoring interface
- Power Supply :+3.3V
- Power consumption<1.5W
- Temperature Range: 0~ 70°C
- RoHS compliant
Applications:
- 10GBASE-LR/LW Ethernet
- SONET OC-192 / SDH
- 10G Fibre Channel
Description:
SFP+ 10G LR is a very compact 10Gb/s optical transceiver module for serial optical communication applications at 10Gb/s. The SFP converts a 10Gb/s serial electrical data stream to 10Gb/s optical output signal and a 10Gb/s optical input signal to 10Gb/s serial electrical data streams. The high speed 10Gb/s electrical interface is fully compliant with SFI specification.
The high performance 1310nm DFB transmitter and high sensitivity PIN receiver provide superior performance for Ethernet applications at up to 10km links.
The SFP+ Module compliants with SFF-8431, SFF-8432 and IEEE 802.3ae 10GBASE-LR. Digital diagnostics functions are available via a 2-wire serial interface, as specified in SFF-8472.
The fully SFP compliant form factor provides hot pluggability, easy optical port upgrades and low EMI emission.
Absolute Maximum Ratings
| Parameter | Symbol | Min. | Typical | Max. | Unit |
| Storage Temperature | TS | -40 | +85 | °C | |
| Case Operating Temperature | TA | 0 | 70 | °C | |
| Maximum Supply Voltage | Vcc | -0.5 | 4 | V | |
| Relative Humidity | RH | 0 | 85 | % |
Electrical Characteristics (TOP = 0 to 70 °C, VCC = 3.135 to 3.465 Volts)
| Parameter | Symbol | Min. | Typical | Max. | Unit | Note |
| Supply Voltage | Vcc | 3.135 | 3.465 | V | ||
| Supply Current | Icc | 430 | mA | |||
| Power Consumption | P | 1.5 | W | |||
| Transmitter Section: | ||||||
| Input differential impedance | Rin | 100 | Ω | 1 | ||
| Tx Input Single Ended DC Voltage Tolerance (Ref VeeT) | V | -0.3 | 4 | V | ||
| Differential input voltage swing | Vin,pp | 180 | 700 | mV | 2 | |
| Transmit Disable Voltage | VD | 2 | Vcc | V | 3 | |
| Transmit Enable Voltage | VEN | Vee | Vee+0.8 | V | ||
| Receiver Section: | ||||||
| Single Ended Output Voltage Tolerance | V | -0.3 | 4 | V | ||
| Rx Output Diff Voltage | Vo | 300 | 850 | mV | ||
| Rx Output Rise and Fall Time | Tr/Tf | 30 | ps | 4 | ||
| LOS Fault | VLOS fault | 2 | VccHOST | V | 5 | |
| LOS Normal | VLOS norm | Vee | Vee+0.8 | V | 5 | |
Note:
1. Connected directly to TX data input pins. AC coupling from pins into laser driver IC.
2. Per SFF-8431 Rev 3.0
3. Into 100 ohms differential termination.
4. 20%~80%
5. LOS is an open collector output. Should be pulled up with 4.7k – 10kΩ on the host board. Normal operation is logic 0; loss of signal is logic 1. Maximum pull-up voltage is 5.5V.
Optical Parameters(TOP = 0 to 70°C, VCC = 3.135 to 3.465 Volts)
| Parameter | Symbol | Min. | Typical | Max. | Unit | Note |
| Transmitter Section: | ||||||
| Center Wavelength | λt | 1290 | 1310 | 1330 | nm | |
| spectral width | △λ | 1 | nm | |||
| Average Optical Power | Pavg | -8.2 | 0.5 | dBm | 1 | |
| Optical Power OMA | Poma | -5.2 | dBm | |||
| Laser Off Power | Poff | -30 | dBm | |||
| Extinction Ratio | ER | 3.5 | dB | |||
| Transmitter Dispersion Penalty | TDP | 3.2 | dB | 2 | ||
| Relative Intensity Noise | Rin | -128 | dB/Hz | 3 | ||
| Optical Return Loss Tolerance | 20 | dB | ||||
| Receiver Section: | ||||||
| Center Wavelength | λr | 1260 | 1355 | nm | ||
| Receiver Sensitivity | Sen | -14.5 | dBm | 4 | ||
| Stressed Sensitivity (OMA) | SenST | -10.3 | dBm | 4 | ||
| Los Assert | LOSA | -25 | - | dBm | ||
| Los Dessert | LOSD | -15 | dBm | |||
| Los Hysteresis | LOSH | 0.5 | dB | |||
| Overload | Sat | 0 | dBm | 5 | ||
| Receiver Reflectance | Rrx | -12 | dB | |||
Note:
1. Average power figures are informative only, per IEEE802.3ae.
2. TWDP figure requires the host board to be SFF-8431compliant. TWDP is calculated using the Matlab code provided in clause 68.6.6.2 of IEEE802.3ae.
3. 12dB reflection.
4. Conditions of stressed receiver tests per IEEE802.3ae. CSRS testing requires the host board to be SFF-8431 compliant.
5. Receiver overload specified in OMA and under the worst comprehensive stressed condition.
Mechanical Dimensions:
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