Part Number: QSFP-40G-ER4-FLT QSFP-40G-ER4-FLT-EXT QSFP-40G-ER4-FLT-IND
Form Factor: QSFP
TX Wavelength: CWDM 1270nm-1330nm
Reach: 40km
Cable Type: SMF
Rate Category: 40GBase
Interface Type: ER4
DDM: Yes
Connector Type: Dual-LC
Optical Power Budget: 16.5dB
TX Power Min/Max: -3.70 to 4.50 dBm
RX Power Min/Max: -20.2 to -1.5 dBm
Cisco Compatible QSFP-40G-ER4-FLT Product Features
Compliant with 40G Ethernet IEEE802.3ba and 40GBASE-ER4 Standard
QSFP+ MSA compliant
Compliant with QDR/DDR Infiniband data rates
Up to 11.2Gb/s data rate per wavelength
4 CWDM lanes MUX/DEMUX design
Up to 40km transmission on single mode fiber (SMF)
Operating case temperature:
Standard 0 to 70oC
Extended -5 to +85 oC
Industrial -40 to +85 oC
Maximum power consumption 3.5W
LC duplex connector
RoHS compliant
Cisco Compatible QSFP-40G-ER4-FLT Applications
40GBASE-ER4 Ethernet Links
Infiniband QDR and DDR interconnects
Client-side 40G Telecom connections
Cisco Compatible QSFP-40G-ER4-FLT Overview
The QSFP-40G-ER4-FLT is a transceiver module designed for 30km optical communication applications. The design is compliant to 40GBASE-ER4 of the IEEE P802.3ba standard. The module converts 4 inputs channels of 10 Gbps electrical data to 4 CWDM optical signals and multiplexes them into a single channel for 40 Gbps optical transmission. Reversely, on the receiver side, the module optically demultiplexes a 40Gbps input into 4 CWDM channels signals and converts them to 4 channel output electrical data. The central wavelengths of the 4 CWDM channels are 1271, 1291, 1311 and 1331 nm as members of the CWDM wavelength grid defined in ITU- T G694.2. It contains a duplex LC connector for the optical interface and a 148-pin connector for the electrical interface. To minimize the optical dispersion in the long-haul system, single-mode fiber (SMF) has to be used.
The product is designed with form factor, optical/electrical connection and digital diagnostic interface according to the QSFP+ Multi-Source Agreement (MSA). It has been designed to meet the harshest external operating conditions including temperature, humidity and EMI interference.
Cisco Compatible QSFP-40G-ER4-FLT Functional Diagram
This product converts the 4-channel 10 Gbps electrical input data into CWDM optical signals (light), by a driven 4- wavelength Distributed Feedback Laser (DFB) array. The light is combined by the MUX parts as a 40 Gbps data, propagating out of the transmitter module from the SMF. The receiver module accepts the 40 Gbps CWDM optical signals input, and de-multiplexes it into 4 individual 10Gbps channels with different wavelengths. Each wavelength is collected by a discrete avalanche photodiode (APD), and then outputted as electric data after amplified first by a TIA and then by a post amplifier. Figure 1 shows the functional block diagram of this product.
A single +3.3V power supply is required to power up this product. Both power supply pins VccTx and VccRx are internally connected and should be applied concurrently. As per MSA specifications the module offers 7 low speed hardware control pins (including the 2-wire serial interface): ModSelL, SCL, SDA, ResetL, LPMode, ModPrsL and IntL.
Module Select (ModSelL) is an input pin. When held low by the host, this product responds to 2-wire serial communication commands. The ModSelL allows the use of this product on a single 2-wire interface bus – individual ModSelL lines must be used.
Laser Driver | DFB Laser | Micro- |
Array (4ch) | Array (4ch) | optics |
Tx3 Tx2 Tx1 Tx0
Rx3 Rx2 Rx1 Rx0
Serial Clock (SCL) and Serial Data (SDA) are required for the 2-wire serial bus communication interface and enable the host to access the QSFP+ memory map.
The ResetL pin enables a complete reset, returning the settings to their default state, when a low level on the ResetL pin is held for longer than the minimum pulse length. During the execution of a reset the host shall disregard all status bits until it indicates a completion of the reset interrupt. The product indicates this by posting an IntL (Interrupt) signal with the Data_Not_Ready bit negated in the memory map. Note that on power up (including hot insertion) the module should post this completion of reset interrupt without requiring a reset.
Low Power Mode (LPMode) pin is used to set the maximum power consumption for the product in order to protect hosts that are not capable of cooling higher power modules, should such modules be accidentally inserted.
Module Present (ModPrsL) is a signal local to the host board which, in the absence of a product, is normally pulled up to the host Vcc. When the product is inserted into the connector, it completes the path to ground though a resistor on the host board and asserts the signal. ModPrsL then indicates its present by setting ModPrsL to a “Low” state.
Interrupt (IntL) is an output pin. “Low” indicates a possible operational fault or a status critical to the host system. The host identifies the source of the interrupt using the 2-wire serial interface. The IntL pin is an open collector output and must be pulled to the Host Vcc voltage on the Host board.
Absolute Maximum Ratings
Parameter | Symbol | Min | Max | Unit |
Storage Temperature | Ts | -40 | +85 | oC |
Power Supply Voltage | Vcc | -0.5 | 3.6 | V |
Relative Humidity (non- condensation) | RH | 0 | 85 | % |
Damage Threshold, each Lane | TH d | 3.8 | dBm |
Recommended Operating Conditions
Parameter | Symbol | Min | Typ | Max | Unit |
Operating Case Temp (Standard) | TOP | 0 | 70 | oC | |
Operating Case Temp (Industrial) | TOP | -40 | 85 | oC | |
Power Supply Voltage | Vcc | 3.135 | 3.3 | 3.465 | V |
Data Rate, each Lane | 10.3125 | 11.2 | Gb/s | ||
Control Input Voltage High | 2 | Vcc | V | ||
Control Input Voltage Low | 0 | 0.8 | V | ||
Link Distance with G652 | D | 30 | km |
Recommended Power Supply Filter
Electrical Characteristics
Parameter | Symbol | Min | Typ | Max | Unit |
Power Consumption | 3.5 | W | |||
Supply Current | Icc | 1.1 | A | ||
Transceiver Power-on Initialization Time (Note 1) | 200 0 | ms |
Electrical Characteristics – Transmitter (each lane)
Parameter | Symbol | Min Typ Max | Unit | Notes | ||
Single-ended Input Voltage Tolerance (Note 2) | -0.3 | 4.0 | V | Referred to TP1 signal common | ||
AC Common Mode Input Voltage Tolerance (RMS) | 15 | mV | RMS | |||
Differential Input Voltage Swing Threshold | 50 | mVpp | LOSA Threshold | |||
Differential Input Voltage Swing | Vin,pp | 190 | 700 | mVpp | ||
Differential Input Impedance | Zin | 90 | 100 | 110 | Ω | |
Differential Input Return Loss | See IEEE 802.3ba 86A.4.1.1 | dB | 10MHz - 11.1GHz | |||
J2 Jitter Tolerance | Jt2 | 0.17 | UI | |||
J9 Jitter Tolerance | Jt9 | 0.29 | UI | |||
Data Dependent Pulse Width Shrinkage (DDPWS) Tolerance | 0.07 | UI | ||||
Eye Mask Coordinates {X1, X2, Y1, Y2} | 0.11, 0.31 95, 350 | UI mV | Hit Ratio = 5x10-5 |
Electrical Characteristics – Receiver (each lane)
Parameter | Symbol | Min | Typ | Max | Unit | Notes |
Single-ended Output Voltage Threshold | -0.3 | 4.0 | V | Referred to signal common | ||
AC Common Mode Output Voltage Tolerance (RMS) | 7.5 | mV | RMS | |||
Differential Output Voltage Swing Threshold | Vout,pp | 300 | 850 | mVpp | ||
Differential Output Impedance | Aout | 90 | 100 | 110 | Ohm | |
Termination Mismatch at 1MHz | 5 | % | ||||
Differential Output Return Loss | See IEEE 802.3ba 86A.4.2.1 | 10MHz - 11.1GHz | ||||
Common mode Output Return Loss | See IEEE 802.3ba 86A.4.2.2 | 10MHz - 11.1GHz | ||||
Output Transition Time | 28 | ps | 20% to 80% | |||
J2 Jitter Tolerance | Jo2 | 0.42 | UI | |||
J9 Jitter Tolerance | Jo9 | 0.65 | UI | |||
Eye Mask Coordinates {X1, X2, Y1, Y2} | 0.29, 05 150, 425 | UI mV | Hit Ratio = 5x10-5 | |||
Notes:
Power-on initialization time is the time from when the power supply voltages reach and remain above the minimum recommended operating supply voltages to the time when the moduleis fully functional.
The single ended input voltage tolerance is the allowable range of the instantaneous input signals.
Optical Characteristics
Parameter | Symbol | Min | Typ | Max | Unit |
Wavelength Assignment | λ0 | 1264.5 | 1271 | 1277.5 | nm |
λ1 | 1284.5 | 1291 | 1297.5 | nm | |
λ2 | 1304.5 | 1311 | 1317.5 | nm | |
λ3 | 1324.5 | 1331 | 1337.5 | nm |
Optical Characteristics - Transmitter
Parameter | Symbol | Min | Typ | Max | Unit | Notes |
Side Mode Suppression Ratio | SMSR | 30 | dB | |||
Total Average Launch Power | PT | 10.5 | dBm | |||
Average Launch Power (each Lane) | PAVG | -3.7 | 4.5 | dBm | ||
Optical Modulation Amplitude (OMA) (each Lane) | POMA | -0.7 | 5 | dBm | 1 | |
Difference in Launch Power between any Two Lanes (OMA) | Ptx,diff | 4.7 | dB | |||
Launch Power in OMA minus Transmitter and Dispersion Penalty (TDP), each Lane | -1.5 | dBm | ||||
TDP, each Lane | TDP | 2.6 | dB | |||
Extinction Ratio | ER | 5.5 | dB | |||
Relative Intensity Noise | RIN | -128 | dB/Hz | 12dB reflection | ||
Transmitter Reflectance | RT | -12 | dB | |||
Transmitter Eye Mask Definition {X2, X2, X3, Y1, Y2, Y3} | {0.25, 0.4, 0.45, 0.25, 0.28, 0.4} | |||||
Average Launch Power OFF (each lane) | Poff | -30 | dBm |
Note: Transmitter optical characteristics are measured with a single mode fiber.
Optical Characteristics - Receiver
Parameter | Symbol | Min | Typ | Max | Unit | Notes |
Damage Threshold, each Lane | THd | 3.8 | dBm | 2 | ||
Average Receive Power, each Lane | -20.2 | -1.5 | dBm | |||
Receiver Reflectance | RR | -26 | dB | |||
Receive Power (OMA) (each Lane) | -1 | dBm | ||||
Receiver Sensitivity in OMA (each Lane) | SEN | -18 | dBm | |||
Stressed Receiver Sensitivity (OMA), each Lane | -15.8 | dBm | 3 | |||
Difference in Receive Power between any 2 Lanes (OMA) | PRX,diff | 7 | dB | |||
LOS Assert | LOSA | -35 | dBm | |||
LOS Deassert | LOSD | -20 | dBm | |||
LOS Hysteresis | LOSH | 0.5 | dB | |||
Receiver Electrical 3dB upper cut-off Frequency (each Lane) | Fc | 12.3 | GHz | |||
Vertical Eye Closure Penalty, each Lane | 2.2 | dB | ||||
Stressed Eye J2 Jitter, each Lane | 0.3 | UI | ||||
Stressed Eye J9 Jitter, each Lane | 0.4 7 | UI |
Notes:
Even if the TDP < 0.8 dB, the OMA min must exceed theminimum value specified here.
The receiver shall be able to tolerate, without damage, continuous exposure to a modulated optical input signal having this power level on one lane. The receiver does not have to operate correctly at this input power.
Measured with conformance test signal at receiver inputfor BER = 1x10-12.
Vertical eye closure penalty and stressed eye jitter are test conditions for measuring stressed receiver sensitivity. They are not characteristics of the receiver.
Digitial Diagnostics Function
The following digital diagnostic characteristics are defined over the normal operating conditions unless otherwise specified.
Parameter | Symbol | Min | Typ | Max | Unit | Notes |
Temperature monitor absolute error | DMITEMP | -3 | 3 | deg. C | Over operating temperature range | |
Supply voltage monitor absolute error | DMIVCC | -0.1 | 0.1 | V | Over Full operating range | |
Channel RX power monitor absolute error | DMIRX_CH | -2 | 2 | dB | 1 | |
Channel Bias current monitor | DMIIbias_CH | -10% | 10% | mA | ||
Channel TX power monitor absolute error | DMITX_CH | -2 | 2 | dB | 1 |
Note 1: Due to measurement accuracy of different multi-mode fibers, there could be an additional ±1dB fluctuation, or ± 3dB total accuracy.
PIN Assignment and Function Definitions
PIN Assignment
PIN Definition
PIN | Signal Name | Description |
1 | GND | Ground (1) |
2 | Tx2n | CML-I Transmitter 2 Inverted Data Input |
3 | Tx2p | CML-I Transmitter 2 Non-Inverted Data Input |
4 | GND | Ground (1) |
5 | Tx4n | CML-I Transmitter 4 Inverted Data Input |
6 | Tx4p | CML-I Transmitter 4 Non-Inverted Data Input |
7 | GND | Ground (1) |
8 | ModSelL | LVTLL-I Module Select |
9 | ResetL | LVTLL-I Module Reset |
10 | VCCRx | +3.3V Power Supply Receiver (2) |
11 | SCL | LVCMOS-I/O 2-Wire Serial Interface Clock |
12 | SDA | LVCMOS-I/O 2-Wire Serial Interface Data |
13 | GND | Ground (1) |
14 | Rx3p | CML-O Receiver 3 Non-Inverted Data Output |
15 | Rx3n | CML-O Receiver 3 Inverted Data Output |
16 | GND | Ground (1) |
17 | Rx1p | CML-O Receiver 1 Non-Inverted Data Output |
18 | Rx1n | CML-O Receiver 1 Inverted Data Output |
19 | GND | Ground (1) |
20 | GND | Ground (1) |
21 | Rx2n | CML-O Receiver 2 Inverted Data Output |
22 | Rx2p | CML-O Receiver 2 Non-Inverted Data Output |
23 | GND | Ground (1) |
24 | Rx4n | CML-O Receiver 4 Inverted Data Output |
25 | Rx4p | CML-O Receiver 4 Non-Inverted Data Output |
26 | GND | Ground (1) |
27 | ModPrsL | Module Present |
28 | IntL | Interrupt |
29 | VCCTx | +3.3V Power Supply Transmitter (2) |
30 | VCC1 | +3.3V Power Supply |
31 | LPMode | LVTLL-I Low Power Mode |
32 | GND | Ground (1) |
33 | Tx3p | CML-I Transmitter 3 Non-Inverted Data Input |
34 | Tx3n | CML-I Transmitter 3 Inverted Data Input |
35 | GND | Ground (1) |
36 | Tx1p | CML-I Transmitter 1 Non-Inverted Data Input |
37 | Tx1n | CML-I Transmitter 1 Inverted Data Input |
38 | GND | Ground (1) |
Notes:
All Ground (GND) are common within the QSFP+ module and all module voltages are referenced to this potential unless noted otherwise. Connect these directly to the host board signal common ground plane.
VccRx, Vcc1 and VccTx are the receiving and transmission power suppliers and shall be applied concurrently. The connector pins are each rated for a maximum current of 500mA.
Licensing
The following U.S. patents are licensed by Finisar to FluxLight, Inc.:
U.S. Patent Nos: 7,184,668, 7,079,775, 6,957,021, 7,058,310, 6,952,531, 7,162,160, 7,050,720