PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4
PH-QSFP28/100G-LR4

PH-QSFP28/100G-LR4  

100Gbps QSFP28 LR4 Optical Transceiver

  • Hot pluggable QSFP28 MSA form factor
  • Compliant to IEEE 802.3ba 100GBASE-LR4
  • Up to 10km reach for G.652 SMF
  • Single +3.3V power supply
  • 4x28G Electrical Serial Interface (CEI-28G-VSR)

Thanks a lot for your inquiry and we will handle it as early as possible.

PH-QSFP28/100G-LR4   Overview

This product is a 100Gb/s transceiver module designed for optical communication applications compliant to 100GBASE-LR4 of the IEEE P802.3ba standard. The module converts 4 input channels of 25Gb/s electrical data to 4 channels of LAN WDM optical signals and then multiplexes them into a single channel for 100Gb/s optical transmission. Reversely on the receiver side, the module de- multiplexes a 100Gb/s optical input into 4 channels of LAN WDM optical signals and then converts them to 4 output channels of electrical data.

PH-QSFP28/100G-LR4   Specification

100Gb/s QSFP28 LR4 Optical Transceiver Module

PH-QSFP28/100G-LR4

Features

  • Hot pluggable QSFP28 MSA form factor
  • Compliant to IEEE 802.3ba 100GBASE-LR4
  • Up to 10km reach for G.652 SMF
  • Single +3.3V power supply
  • Operating case temperature: 0~70oCTransmitter: cooled 4x25Gb/s LAN WDM EML TOSA (1295.56, 1300.05, 1304.58, 1309.14nm)
  • Receiver: 4x25Gb/s PIN ROSA
  • 4x28G Electrical Serial Interface (CEI-28G-VSR)
  • Maximum power consumption 4.0W
  • Duplex LC receptacle
  • RoHS-6 compliant

Applications

  • 100GBASE-LR4 Ethernet Links
  • Infiniband QDR and DDR interconnects
  • Client-side 100G Telecom connections

1.General Description

This product is a 100Gb/s transceiver module designed for optical communication applications compliant to 100GBASE-LR4 of the IEEE P802.3ba standard. The module converts 4 input channels of 25Gb/s electrical data to 4 channels of LAN WDM optical signals and then multiplexes them into a single channel for 100Gb/s optical transmission. Reversely on the receiver side, the module de- multiplexes a 100Gb/s optical input into 4 channels of LAN WDM optical signals and then converts them to 4 output channels of electrical data.

The central wavelengths of the 4 LAN WDM channels are 1295.56, 1300.05, 1304.58 and 1309.14 nm as members of the LAN WDM wavelength grid defined in IEEE 802.3ba. The high performance cooled LAN WDM EA-DFB transmitters and high sensitivity PIN receivers provide superior performance for 100Gigabit Ethernet applications up to 10km links and compliant to optical interface with IEEE802.3ba Clause 88 100GBASE-LR4 requirements.

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.

2.Functional Description

The transceiver module receives 4 channels of 25Gb/s electrical data, which are processed by a 4- channel Clock and Data Recovery (CDR) IC that reshapes and reduces the jitter of each electrical signal. Subsequently, each of 4 EML laser driver IC's converts one of the 4 channels of electrical signals to an optical signal that is transmitted from one of the 4 cooled EML lasers which are packaged in the Transmitter Optical Sub-Assembly (TOSA). Each laser launches the optical signal in specific wavelength specified in IEEE802.3ba 100GBASE-LR4 requirements. These 4-lane optical signals will be optically multiplexed into a single fiber by a 4-to-1 optical WDM MUX. The optical output power of each channel is maintained constant by an automatic power control (APC) circuit. The transmitter output can be turned off by TX_DIS hardware signal and/or 2-wire serial interface.

The receiver receives 4-lane LAN WDM optical signals. The optical signals are de-multiplexed by a 1-to-4 optical DEMUX and each of the resulting 4 channels of optical signals is fed into one of the 4 receivers that are packaged into the Receiver Optical Sub-Assembly (ROSA). Each receiver converts the optical signal to an electrical signal. The regenerated electrical signals are retimed and de-jittered and amplified by the RX portion of the 4-channel CDR. The retimed 4-lane output electrical signals are compliant with IEEE CAUI-4 interface requirements. In addition, each received optical signal is monitored by the DOM section. The monitored value is reported through the 2-wire serial interface. If one or more received optical signal is weaker than the threshold level, RX_LOS hardware alarm will be triggered.

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.

Serial Clock (SCL) and Serial Data (SDA) are required for the 2-wire serial bus communication interface and enable the host to access the QSFP28 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 through 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.

3.Transceiver Block Diagram

C:\Users\Administrator\Desktop\图片1.png图片1Figure 1. Transceiver Block Diagram

4.Pin Assignment and Description

Figure 2. MSA Compliant Connector

Pin Definition

PIN

Logic

Symbol

Name/Description

Notes

1

 

GND

Ground

1

2

CML-I

Tx2n

Transmitter Inverted Data Input

 

3

CML-I

Tx2p

Transmitter Non-Inverted Data output

 

4

 

GND

Ground

1

5

CML-I

Tx4n

Transmitter Inverted Data Input

 

6

CML-I

Tx4p

Transmitter Non-Inverted Data output

 

7

 

GND

Ground

1

8

LVTLL-I

ModSelL

Module Select

 

9

LVTLL-I

ResetL

Module Reset

 

10

 

VccRx

+3.3V Power Supply Receiver

2

11

LVCMOS-I/O

SCL

2-Wire Serial Interface Clock

 

12

LVCMOS-I/O

SDA

2-Wire Serial Interface Data

 

13

 

GND

Ground

 

14

CML-O

Rx3p

Receiver Non-Inverted Data Output

 

15

CML-O

Rx3n

Receiver Inverted Data Output

 

16

 

GND

Ground

1

17

CML-O

Rx1p

Receiver Non-Inverted Data Output

 

18

CML-O

Rx1n

Receiver Inverted Data Output

 

19

 

GND

Ground

1

20

 

GND

Ground

1

21

CML-O

Rx2n

Receiver Inverted Data Output

 

22

CML-O

Rx2p

Receiver Non-Inverted Data Output

 

23

 

GND

Ground

1

24

CML-O

Rx4n

Receiver Inverted Data Output

1

25

CML-O

Rx4p

Receiver Non-Inverted Data Output

 

26

 

GND

Ground

1

27

LVTTL-O

ModPrsL

Module Present

 

28

LVTTL-O

IntL

Interrupt

 

29

 

VccTx

+3.3 V Power Supply transmitter

2

30

 

Vcc1

+3.3 V Power Supply

2

31

LVTTL-I

LPMode

Low Power Mode

 

32

 

GND

Ground

1

33

CML-I

Tx3p

Transmitter Non-Inverted Data Input

 

34

CML-I

Tx3n

Transmitter Inverted Data Output

 

35

 

GND

Ground

1

36

CML-I

Tx1p

Transmitter Non-Inverted Data Input

 

37

CML-I

Tx1n

Transmitter Inverted Data Output

 

38

 

GND

Ground

1

Notes:

1. GND is the symbol for signal and supply (power) common for QSFP28 modules. All are

common within the QSFP28 module and all module voltages are referenced to this potential

unless otherwise noted. Connect these directly to the host board signal common ground plane.

2. VccRx, Vcc1 and VccTx are the receiver and transmitter power suppliers and shall be applied

concurrently. Recommended host board power supply filtering is shown in Figure 4 below. Vcc

Rx, Vcc1 and Vcc Tx may be internally connected within the QSFP28 transceiver module in any

combination. The connector pins are each rated for a maximum current of 1000mA.

5.Recommended Power Supply Filter

Fiber 12

Fiber 1

Figure 3. Recommended Power Supply Filter

6.Absolute Maximum Ratings

It has to be noted that the operation in excess of any individual absolute maximum ratings might cause permanent damage to this module.

Parameter

Symbol

Min

Max

Units

Note

Storage Temperature

TS

-40

85

degC

 

Operating Case Temperature

TOP

0

70

degC

 

Power Supply Voltage

VCC

-0.5

3.6

V

 

Relative Humidity (non-condensation)

RH

0

85

%

 

Damage Threshold, each Lane

THd

3.4

 

dBm

 

7.Recommended Operating Conditions and Power Supply Requirements

Parameter

Symbol

Min

Typical

Max

Units

Operating Case Temperature

TOP

0

 

70

degC

Power Supply Voltage

VCC

3.135

3.3

3.465

V

Data Rate, each Lane

   

25.78125

 

Gb/s

Control Input Voltage High

 

2

 

Vcc

V

Control Input Voltage Low

 

0

 

0.8

V

Link Distance with G.652

D

0.002

 

10

KM

8.Electrical Characteristics

The following electrical characteristics are defined over the Recommended Operating Environment unless otherwise specified.

Parameter

Symbol

Min

Typical

Max

Units

Notes

Power Consumption

     

4

W

 

Supply Current

Icc

   

1.21

A

 

Transceiver Power-on Initialization Time

     

2000

ms

1

Transmitter (each Lane)

Single-ended Input Voltage Tolerance (Note 2)

 

-0.3

 

4

V

Referred to TP1 signal common

AC Common Mode Input Voltage Tolerance

 

15

   

mV

RMS

Differential Input Voltage Swing

 

50

   

mVpp

LOSA Threshold

Differential Input Voltage

Vin,pp

190

 

700

mVpp

 

Differential Input Impedance

Zin

90

100

110

Ω

 

Receiver (each Lane)

Single-ended Output Voltage

 

-0.3

 

4

V

Referred to signal common

AC Common Mode Output Voltage

     

7.5

mV

RMS

Differential Output Voltage Swing

Vout,pp

300

 

850

mVpp

 

Differential Output Impedance

Zout

90

100

110

ohm

 

Notes:

1.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 module is fully functional.

The single ended input voltage tolerance is the allowable range of the instantaneous input signals.

9.Optical Characteristics

QSFP28 100GBASE-LR4

Parameter

Symbol

Min

Typical

Max

Unit

Notes

Lane Wavelength

L0

1294.53

1295.56

1296.59

nm

 

L1

1299.02

1300.05

1301.09

nm

 

L2

1303.54

1304.58

1305.63

nm

 

L3

1308.09

1309.14

1310.19

nm

 

Transmitter

SMSR

SMSR

30

   

dB

 

Total Average Launch Power

PT

   

10.5

dBm

 

Average Launch Power, each Lane

PAVG

-4.3

 

4.5

dBm

 

OMA, each Lane

POMA

-1.3

 

4.5

dBm

1

Difference in Launch Power between any Two Lanes (OMA)

Ptx,diff

   

5

dB

 

Launch Power in OMA minus Transmitter and Dispersion Penalty (TDP), each Lane

 

-2.3

   

dBm

 

TDP, each Lane

TDP

   

2.2

dB

 

Extinction Ratio

ER

4

   

dB

 

RIN20OMA

RIN

   

-130

dB/Hz

 

Optical Return Loss Tolerance

TOL

   

20

dB

 

Transmitter Reflectance

RT

   

-12

dB

 

Eye Mask{X1, X2, X3, Y1, Y2, Y3}

 

{0.25, 0.4, 0.45, 0.25, 0.28, 0.4}

 

2

Average Launch Power OFF Transmitter, each Lane

Poff

   

-30

dBm

 

Receiver

Damage Threshold, each Lane

THd

5.5

   

dBm

3

Total Average Receive Power

     

10.5

dBm

 

Average Receive Power, each Lane

 

-10.6

 

4.5

dBm

 

Receive Power (OMA), each Lane

     

4.5

dBm

 

Receiver Sensitivity (OMA), each Lane

SEN

   

-8.6

dBm

 

Stressed Receiver Sensitivity (OMA), each Lane

     

-6.8

dBm

4

Difference in Receive Power between any Two Lanes (OMA)

Prx,diff

   

5.5

dB

 

LOS Assert

LOSA

 

-18

 

dBm

 

LOS Deassert

LOSD

 

-15

 

dBm

 

LOS Hysteresis

LOSH

0.5

   

dB

 

Receiver Electrical 3 dB upper Cutoff Frequency, each Lane

Fc

   

31

GHz

 

Conditions of Stress Receiver Sensitivity Test (Note 5)

Vertical Eye Closure Penalty, each Lane

   

1.8

 

dB

 

Stressed Eye J2 Jitter, each Lane

   

0.3

 

UI

 

Stressed Eye J9 Jitter, each Lane

   

0.47

 

UI

 

Notes:

1.Even if the TDP < 1 dB, the OMA min must exceed the minimum value specified here.

2.See Figure 4 below.

3.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.

4.Measured with conformance test signal at receiver input for BER = 1x10-12.

5.Vertical eye closure penalty and stressed eye jitter are test conditions for measuring stressed receiver sensitivity. They are not characteristics of the receiver.

Figure 4. Eye Mask Definition

10.Digital Diagnostic Functions

The following digital diagnostic characteristics are defined over the normal operating conditions unless otherwise specified.

Parameter

Symbol

Min

Max

Units

Notes

Temperature monitor absolute error

DMI_Temp

-3

+3

degC

Over operating temperature range

Supply voltage monitor absolute error

DMI _VCC

-0.1

0.1

V

Over full operating range

Channel RX power monitor absolute error

DMI_RX_Ch

-2

2

dB

1

Channel Bias current monitor

DMI_Ibias_Ch

-10%

10%

mA

Ch1~Ch4

Channel TX power monitor absolute error

DMI_TX_Ch

-2

2

dB

1

Notes:

  1. Due to measurement accuracy of different single mode fibers, there could be an additional +/-1 dB fluctuation, or a +/- 3 dB total accuracy.

12.Mechanical Dimensions

图片3

Figure 5. Mechanical Outline

13.ESD

This transceiver is specified as ESD threshold 1kV for high speed data pins and 2kV for all others electrical input pins, tested per MIL-STD-883, Method 3015.4 /JESD22-A114-A (HBM). However, normal ESD precautions are still required during the handling of this module. This transceiver is shipped in ESD protective packaging. It should be removed from the packaging and handled only in an ESD protected environment.

14.Laser Safety

This is a Class 1 Laser Product according to EN 60825-1:2014. This product complies with 21 CFR 1040.10 and 1040.11 except for deviations pursuant to Laser Notice No. 50, dated (June 24, 2007).