F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module

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  • F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module
  • F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module
  • F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module
  • F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module
  • F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module
  • F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module
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Basic Info.

Model NO.
LAQ2-8485-SR
Condition
New
Transport Package
Blister Pack
Trademark
Linksall
Origin
China
HS Code
8517706000
Production Capacity
100, 000 Per Year

Product Description

100Gb/s QSFP28 SR4 Transceiver Module

PRODUCT FEATURES  

  1. Up to 27.952 Gbps Data rate per channel
  2. Maximum link length of 150m links on OM4 multimode fiber
  3. High Reliability 850nm VCSEL technology
  4. Electrically hot-pluggable
  5. Digital diagnostic SFF-8636 compliant
  6. Compliant with QSFP28 MSA 
  7. Case operating temperature range:0°C to 70°C 
  8. Power dissipation < 2.0W
 APPLICATIONS
  1. 100G Ethernet &100GBASE-SR4
  2. ITU-T OTU4
STANDARD
  1. Compliant to IEEE 802.3 bm
  2. Compliant to SFF-8636
  3. RoHS Compliant.

General Description
LAQ2-8485-SR is designed for use in 100 Gigabit per second links over multimode fiber. They are compliant with the QSFP28 MSA and IEEE 802.3bm
The optical transmitter portion of the transceiver incorporates a 4-channel VCSEL (Vertical Cavity Surface Emitting Laser) array, a 4-channel input buffer and laser driver, diagnostic monitors, control and bias blocks. For module control, the control interface incorporates a Two Wire Serial interface of clock and data signals. Diagnostic monitors for VCSEL bias, module temperature, transmitted optical power,received optical power and supply voltage are implemented and results are available through the TWS interface. Alarm and warning thresholds are established for the monitored attributes. Flags are set and interrupts generated when the attributes are outside the thresholds. Flags are also set and interrupts generated for loss of input signal (LOS) and transmitter fault conditions. All flags are latched and will remain set even if the condition initiating the latch clears and operation resumes. All interrupts can be masked and flags are reset by reading the appropriate flag register. The optical output will squelch for loss of input signal unless squelch is disabled. Fault detection or channel deactivation through the TWS interface will disable the channel. Status, alarm/warning and fault information are available via the TWS interface.
The optical receiver portion of the transceiver incorporates a 4-channel PIN photodiode array, a 4-channel TIA array, a 4 channel output buffer, diagnostic monitors, and control and bias blocks. Diagnostic monitors for optical input power are implemented and results are available through the TWS interface. Alarm and warning thresholds are established for the monitored attributes. Flags are set and interrupts generated when the attributes are outside the thresholds. Flags are also set and interrupts generated for loss of optical input signal (LOS). All flags are latched and will remain set even if the condition initiating the flag clears and operation resumes. All interrupts can be masked and flags are reset upon reading the appropriate flag register. The electrical output will squelch for loss of input signal (unless squelch is disabled) and channel de-activation through TWS interface. Status and alarm/warning information are available via the TWS interface.
Absolute Maximum Ratings  
Parameter Symbol Min. Typ. Max. Unit Note
Storage Temperature Ts -40 - 85 ºC  
Relative Humidity RH 5 - 95 %  
Power Supply Voltage VCC -0.3 - 4 V  
Signal Input Voltage   Vcc-0.3 - Vcc+0.3 V  
Recommended Operating Conditions
Parameter Symbol Min. Typ. Max. Unit Note
Case Operating Temperature Tcase 0 - 70 ºC Without air flow
Power Supply Voltage VCC 3.14 3.3 3.46 V  
Power Supply Current ICC -   600 mA  
Data Rate BR   25.78125   Gbps Each channel
Transmission Distance TD   - 150 m OM4  MMF
Note:100G Ethernet &100GBASE-SR4 and ITU-T OTU4 has different register setting ,not auto- Negotiatio
Optical Characteristics
Parameter Symbol Min Typ Max Unit NOTE
Transmitter            
Center Wavelength λ0 840   860 nm  
Average Launch Power each lane   -8.4   2.4 dBm  
Spectral Width (RMS) σ     0.6 nm  
Optical Extinction Ratio ER 2     dB  
Optical Return Loss Tolerance ORL     12 dB  
Output Eye Mask Compliant with IEEE 802.3bm  
Receiver            
Receiver Wavelength λin 840   860 nm  
Rx Sensitivity per lane RSENS     -10.3 dBm 1
Input Saturation Power (Overload) Psat 2.4     dBm  
Receiver Reflectance Rr     -12 dB  
Notes:  
  1. Measured with a PRBS 231-1 test pattern, @25.78Gb/s, BER<5.2*10-5
    1. Electrical Characteristics
Parameter Symbol Min Typ Max Unit NOTE
Supply Voltage Vcc 3.14 3.3 3.46 V  
Supply Current Icc     600 mA  
Transmitter            
Input differential impedance Rin   100   Ω 1
 Differential data input swing Vin,pp 180   1000 mV  
Single ended input voltage tolerance VinT -0.3   4.0 V  
Receiver            
Differential data output swing Vout,pp 300   850 mV 2
Single-ended output voltage   -0.3   4.0 V  
Notes
  1. Connected directly to TX data input pins. AC coupled thereafter.  
  2. Into 100Ω ohms differential termination.  
    1. Pin Assignment

Figure 1---Pin out of Connector Block on Host Board
Pin Symbol Name/Description NOTE
1 GND Transmitter Ground  (Common with Receiver Ground) 1
2 Tx2n Transmitter Inverted Data Input  
3 Tx2p Transmitter Non-Inverted Data output  
4 GND Transmitter Ground  (Common with Receiver Ground) 1
5 Tx4n Transmitter Inverted Data Input  
6 Tx4p Transmitter Non-Inverted Data output  
7 GND Transmitter Ground  (Common with Receiver Ground) 1
8 ModSelL Module Select  
9 ResetL Module Reset  
10 VccRx 3.3V Power Supply Receiver 2
11 SCL 2-Wire serial Interface Clock  
12 SDA 2-Wire serial Interface Data  
13 GND Transmitter Ground  (Common with Receiver Ground)  
14 Rx3p Receiver Non-Inverted Data Output  
15 Rx3n Receiver Inverted Data Output  
16 GND Transmitter Ground  (Common with Receiver Ground) 1
17 Rx1p Receiver Non-Inverted Data Output  
18 Rx1n Receiver Inverted Data Output  
19 GND Transmitter Ground  (Common with Receiver Ground) 1
20 GND Transmitter Ground  (Common with Receiver Ground) 1
21 Rx2n Receiver Inverted Data Output  
22 Rx2p Receiver Non-Inverted Data Output  
23 GND Transmitter Ground  (Common with Receiver Ground) 1
24 Rx4n Receiver Inverted Data Output 1
25 Rx4p Receiver Non-Inverted Data Output  
26 GND Transmitter Ground  (Common with Receiver Ground) 1
27 ModPrsl Module Present  
28 IntL Interrupt  
29 VccTx 3.3V power supply transmitter 2
30 Vcc1 3.3V power supply 2
31 LPMode Low Power Mode,not connect  
32 GND Transmitter Ground  (Common with Receiver Ground) 1
33 Tx3p Transmitter Non-Inverted Data Input  
34 Tx3n Transmitter Inverted Data Output  
35 GND Transmitter Ground  (Common with Receiver Ground) 1
36 Tx1p Transmitter Non-Inverted Data Input  
37 Tx1n Transmitter Inverted Data Output  
38 GND Transmitter Ground  (Common with Receiver 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 receiving and transmission power suppliers and shall be applied concurrently. Recommended host board power supply filtering is shown 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 500mA.
 
    1. Digital Diagnostic Functions
LAQ2-8485-SR support the 2-wire serial communication protocol as defined in the QSFP28 MSA.,which allows real-time access to the following operating parameters: 
  • Transceiver temperature 
  • Laser bias current 
  • Transmitted optical power
  • Received optical power
  • Transceiver supply voltage 
It also provides a sophisticated system of alarm and warning flags, which may be used to alert end-users when particular operating parameters are outside of a factory-set normal range. 
The operating and diagnostics information is monitored and reported by a Digital Diagnostics Transceiver Controller inside the transceiver, which is accessed through the 2-wire serial interface. When the serial protocol is activated, the serial clock signal (SCL pin) is generated by the host. The positive edge clocks data into the QSFP28 transceiver into those segments of its memory map that are not write-protected. The negative edge clocks data from the QSFP28 transceiver. The serial data signal (SDA pin) is bi-directional for serial data transfer. The host uses SDA in conjunction with SCL to mark the start and end of serial protocol activation. The memories are organized as a series of 8-bit data words that can be addressed individually or sequentially. The 2-wire serial interface provides sequential or random access to the 8 bit parameters, addressed from 00h to the maximum address of the memory.
This clause defines the Memory Map for QSFP28 transceiver used for serial ID, digital monitoring and certain control functions. The interface is mandatory for all QSFP28 devices. The memory map has been changed in order to accommodate 4 optical channels and limit the required memory space. The structure of the memory is shown in Figure 2 -QSFP28 Memory Map. The memory space is arranged into a lower, single page, address space of 128 bytes and multiple upper address space pages. This structure permits timely access to addresses in the lower page, e.g. Interrupt Flags and Monitors. Less time critical entries, e.g. serial ID information and threshold settings, are available with the Page Select function. The structure also provides address expansion by adding additional upper pages as needed.  For example, in Figure 2 upper pages 01 and 02 are optional.  Upper page 01 allows implementation of Application Select Table, and upper page 02 provides user read/write space.  The lower page and upper pages 00 and 03 are always implemented. The interface address used is A0xh and is mainly used for time critical data like interrupt handling in order to enable a "one-time-read" for all data related to an interrupt situation. After an Interrupt, IntL, has been asserted, the host can read out the flag field to determine the effected channel and type of flag.
For more detailed information including memory map definitions, please see the QSFP28 MSA Specification.

                Figure 2 -QSFP28 Memory Map

 Lower Memory Map
The lower 128 bytes of the 2-wire serial bus address space, see Table 1, is used to access a variety of measurements and diagnostic functions, a set of control functions, and a means to select which of the various upper memory map pages are accessed on subsequent reads. This portion of the address space is always directly addressable and thus is chosen for monitoring and control functions that may need to be repeatedly accessed. The definition of identifier field is the same as page 00h Byte 128.



Table 1- Lower Memory Map
 
Byte Address Description Type
0 Identifier (1 Byte) Read-Only
1-2 Status (2 Bytes) Read-Only
3-21 Interrupt Flags (19 Bytes) Read-Only
22-33 Module Monitors (12 Bytes) Read-Only
34-81 Channel Monitors (48 Bytes) Read-Only
82-85 Reserved (4 Bytes) Read-Only
86-97 Control (12 Bytes) Read/Write
98-99 Reserved (2 Bytes) Read/Write
100-106 Module and Channel Masks (7 Bytes) Read/Write
107-118 Reserved (12 Bytes) Read/Write
119-122 Password Change Entry Area (optional) (4 Bytes) Read/Write
123-126 Password Entry Area (optional) (4 Bytes) Read/Write
127 Page Select Byte Read/Write
       
Status Indicator Bits
The Status Indicators are defined inTable 2.

 Table 2 - Status Indicators
 
Byte Bit Name Description
1 All Revision
Compliance
00h: Revision not specified. Do not use for SFF-8636 rev 2.5 or
Higher; 01h: SFF-8436 Rev 4.8 or earlier; 02h: Includes functionality described in revision 4.8 or earlier of SFF-8436, except that this byte and Bytes 186-189 are as defined in this document; 03h: SFF-8636 Rev 1.3 or earlier; 04h: SFF-8636 Rev 1.4; 05h: SFF-8636 Rev 1.5; 06h: SFF-8636 Rev 2.0; 07h: SFF-8636 Rev 2.5, 2.6 and 2.7; 08-FFh: 08-FFh Unallocated
2 7 Reserved  
  6 Reserved  
  5 Reserved  
  4 Reserved  
  3 Reserved  
  2 Flat_mem Upper memory flat or paged.Flat memory: 0= paging, 1=
Page 00h only
  1 IntL Digital state of the IntL Interrupt output pin (if pin supported)
  0 Data_Not_Ready Indicates free-side has not yet achieved power up and monitor data is not ready. Bit remains high until data is ready to be read at which time the device sets the bit low.

Interrupt Flags
A portion of the memory map (Bytes 3 through 21), form a flag field. Within this field, the status of LOS and Tx Fault as well as alarms and warnings for the various monitored items is reported. For normal operation and default state, the bits in this field have the value of 0b. For the defined conditions of LOS, Tx Fault, module and channel alarms and warnings, the appropriate bit or bits are set, value = 1b. Once asserted, the bits remained set (latched) until cleared by a read operation that includes the affected bit or reset by the ResetL pin. The Channel Status Interrupt Flags are defined in Table 3.
Table 3 - Channel Status Interrupt Flags
 
Byte Bit Name Description
3 7 L-Tx4 LOS Latched TX LOS indicator, channel 4 (Not support)
  6 L-Tx3 LOS Latched TX LOS indicator, channel 3 (Not support)
  5 L-Tx2 LOS Latched TX LOS indicator, channel 2 (Not support)
  4 L-Tx1 LOS Latched TX LOS indicator, channel 1 (Not support)
  3 L-Rx4 LOS Latched RX LOS indicator, channel 4
  2 L-Rx3 LOS Latched RX LOS indicator, channel 3
  1 L-Rx2 LOS Latched RX LOS indicator, channel 2
  0 L-Rx1 LOS Latched RX LOS indicator, channel 1
4 7 L-Tx4 Adapt
EQ Fault
Latched TX, Adaptive EQ fault indicator, channel 4 (if supported)
  6 L-Tx3 Adapt
EQ Fault
Latched TX, Adaptive EQ fault indicator, channel 3 (if supported)
  5 L-Tx2 Adapt
EQ Fault
Latched TX, Adaptive EQ fault indicator, channel 2 (if supported)
  4 L-Tx1 Adapt
EQ Fault
Latched TX, Adaptive EQ fault indicator, channel 1 (if supported)
  3 L-Tx4 Fault Latched TX Transmitter/Laser fault indicator, channel 4
  2 L-Tx3 Fault Latched TX Transmitter/Laser fault indicator, channel 3
  1 L-Tx2 Fault Latched TX Transmitter/Laser fault indicator, channel 2
  0 L-Tx1 Fault Latched TX Transmitter/Laser fault indicator, channel 1
5 7 L-Tx4 LOL Latched TX CDR LOL indicator, ch 4
  6 L-Tx3 LOL Latched TX CDR LOL indicator, ch 3
  5 L-Tx2 LOL Latched TX CDR LOL indicator, ch 2
  4 L-Tx1 LOL Latched TX CDR LOL indicator, ch 1
  3 L-Rx4 LOL Latched RX CDR LOL indicator, ch 4
  2 L-Rx3 LOL Latched RX CDR LOL indicator, ch 3
  1 L-Rx2 LOL Latched RX CDR LOL indicator, ch 2
  0 L-Rx1 LOL Latched RX CDR LOL indicator, ch 1

The Module Monitor Interrupt Flags are defined in Table 4.

  Table 4 - Module Monitor Interrupt Flags
Byte Bit Name Description
6 7 L-Temp High Alarm Latched high temperature alarm
  6 L-Temp Low Alarm Latched low temperature alarm
  5 L-Temp High Warning Latched high temperature warning
  4 L-Temp Low Warning Latched low temperature warning
  3-1 Reserved  
  0 Initialization complete flag Asserted (one) after initialization and/or reset has completed. Returns to Zero when read. See Table 6-25 for the Initialization
Complete Implemented bit.
7 7 L-Vcc High Alarm Latched high supply voltage alarm
  6 L-Vcc Low Alarm Latched low supply voltage alarm
  5 L-Vcc High Warning Latched high supply voltage warning
  4 L-Vcc Low Warning Latched low supply voltage warning
  3-0 Reserved  
8 All Vendor Specific  

The Channel Monitor Interrupt Flags are defined in Table 5

Table 5 - Channel Monitor Interrupt Flags
Byte Bit Name Description
9 7 L-Rx1 Power High Alarm Latched high RX power alarm, channel 1
  6 L-Rx1 Power Low Alarm Latched low RX power alarm, channel 1
  5 L-Rx1 Power High Warning Latched high RX power warning, channel 1
  4 L-Rx1 Power Low Warning Latched low RX power warning, channel 1
  3 L-Rx2 Power High Alarm Latched high RX power alarm, channel 2
  2 L-Rx2 Power Low Alarm Latched low RX power alarm, channel 2
  1 L-Rx2 Power High Warning Latched high RX power warning, channel 2
  0 L-Rx2 Power Low Warning Latched low RX power warning, channel 2
10 7 L-Rx3 Power High Alarm Latched high RX power alarm, channel 3
  6 L-Rx3 Power Low Alarm Latched low RX power alarm, channel 3
  5 L-Rx3 Power High Warning Latched high RX power warning, channel 3
  4 L-Rx3 Power Low Warning Latched low RX power warning, channel 3
  3 L-Rx4 Power High Alarm Latched high RX power alarm, channel 4
  2 L-Rx4 Power Low Alarm Latched low RX power alarm, channel 4
  1 L-Rx4 Power High Warning Latched high RX power warning, channel 4
  0 L-Rx4 Power Low Warning Latched low RX power warning, channel 4
11 7 L-Tx1 Bias High Alarm Latched high TX bias alarm, channel 1
  6 L-Tx1 Bias Low Alarm Latched low TX bias alarm, channel 1
  5 L-Tx1 Bias High Warning Latched high TX bias warning, channel 1
  4 L-Tx1 Bias Low Warning Latched low TX bias warning, channel 1
  3 L-Tx2 Bias High Alarm Latched high TX bias alarm, channel 2
  2 L-Tx2 Bias Low Alarm Latched low TX bias alarm, channel 2
  1 L-Tx2 Bias High Warning Latched high TX bias warning, channel 2
  0 L-Tx2 Bias Low Warning Latched low TX bias warning, channel 2
12 7 L-Tx3 Bias High Alarm Latched high TX bias alarm, channel 3
  6 L-Tx3 Bias Low Alarm Latched low TX bias alarm, channel 3
  5 L-Tx3 Bias High Warning Latched high TX bias warning, channel 3
  4 L-Tx3 Bias Low Warning Latched low TX bias warning, channel 3
  3 L-Tx4 Bias High Alarm Latched high TX bias alarm, channel 4
  2 L-Tx4 Bias Low Alarm Latched low TX bias alarm, channel 4
  1 L-Tx4 Bias High Warning Latched high TX bias warning, channel 4
  0 L-Tx4 Bias Low Warning Latched low TX bias warning, channel 4
13 7 L-Tx1 Power High Alarm Latched high TX Power alarm, channel 1
  6 L-Tx1 Power Low Alarm Latched low TX Power alarm, channel 1
  5 L-Tx1 Power High Warning Latched high TX Power warning, channel 1
  4 L-Tx1 Power Low Warning Latched low TX Power warning, channel 1
  3 L-Tx2 Power High Alarm Latched high TX Power alarm, channel 2
  2 L-Tx2 Power Low Alarm Latched low TX Power alarm, channel 2
  1 L-Tx2 Power High Warning Latched high TX Power warning, channel 2
  0 L-Tx2 Power Low Warning Latched low TX Power warning, channel 2
14 7 L-Tx3 Power High Alarm Latched high TX Power alarm, channel 3
  6 L-Tx3 Power Low Alarm Latched low TX Power alarm, channel 3
  5 L-Tx31 Power High Warning Latched high TX Power warning, channel 3
  4 L-Tx3 Power Low Warning Latched low TX Power warning, channel 3
  3 L-Tx4 Power High Alarm Latched high TX Power alarm, channel 4
  2 L-Tx4 Power Low Alarm Latched low TX Power alarm, channel 4
  1 L-Tx4 Power High Warning Latched high TX Power warning, channel 4
  0 L-Tx4 Power Low Warning Latched low TX Power warning, channel 4
15-16 All Reserved Reserved channel monitor flags, set 4
17-18 All Reserved Reserved channel monitor flags, set 5
19-20 All Vendor Specific Reserved channel monitor flags, set 6
21 All Vendor Specific  

 Module Monitors
Real time monitoring for the QSFP28 module include transceiver temperature, transceiver supply voltage, and monitoring for each transmit and receive channel. Measured parameters are reported in 16-bit data fields, i.e., two concatenated bytes. These are shown in Table 6.

Table 6 - Module Monitoring Values
Byte Bit Name Description
22 All Temperature MSB Internally measured module temperature
23 All Temperature LSB  
24-25 All Reserved  
26 All Supply Voltage MSB Internally measured module supply voltage
27 All Supply Voltage LSB  
28-29 All Reserved  
30-33 All Vendor Specific  



Channel Monitoring
Real time channel monitoring is for each transmit and receive channel and includes optical input power ,Tx bias current and Tx output Power. Measurements are calibrated over vendor specified operating temperature and voltage and should be interpreted as defined below. Alarm and warning threshold values should be interpreted in the same manner as real time 16-bit data. Table 7 defines the Channel Monitoring.
Table 7 - Channel Monitoring Values
Byte Bit Name Description
34 All Rx1 Power MSB Internally measured RX input power, channel 1
35 All Rx1 Power LSB  
36 All Rx2 Power MSB Internally measured RX input power, channel 2
37 All Rx2 Power LSB  
38 All Rx3 Power MSB Internally measured RX input power, channel 3
39 All Rx3 Power LSB  
40 All Rx4 Power MSB Internally measured RX input power, channel 4
41 All Rx4 Power LSB  
42 All Tx1 Bias MSB Internally measured TX bias, channel 1
43 All Tx1 Bias LSB  
44 All Tx2 Bias MSB Internally measured TX bias, channel 2
45 All Tx2 Bias LSB  
46 All Tx3 Bias MSB Internally measured TX bias, channel 3
47 All Tx3 Bias LSB  
48 All Tx4 Bias MSB Internally measured TX bias, channel 4
49 All Tx4 Bias LSB  
50 All Tx1 Power MSB Internally measured TX output power, channel 1
51 All Tx1 Power LSB  
52 All Tx2 Power MSB Internally measured TX output power, channel 2
53 All Tx2 Power LSB  
54 All Tx3 Power MSB Internally measured TX output power, channel 3
55 All Tx3 Power LSB  
56 All Tx4 Power MSB Internally measured TX output power, channel 4
57 All Tx4 Power LSB  
58-65     Reserved channel monitor set 4
66-73     Reserved channel monitor set 5
74-81   Vendor Specific  
Control Bytes
Control Bytes are defined in Table 8
                                Table 8 - Control Bytes
Byte Bit Name Description
86 7-4 Reserved  
  3 Tx4_Disable Read/write bit that allows software disable of transmitters
  2 Tx3_Disable Read/write bit that allows software disable of transmitters
  1 Tx2_Disable Read/write bit that allows software disable of transmitters
  0 Tx1_Disable Read/write bit that allows software disable of transmitters
87 7 Rx4_Rate_Select Software Rate Select, Rx channel 4 msb
  6 Rx4_Rate_Select Software Rate Select, Rx channel 4 lsb
  5 Rx3_Rate_Select Software Rate Select, Rx channel 3 msb
  4 Rx3_Rate_Select Software Rate Select, Rx channel 3 lsb
  3 Rx2_Rate_Select Software Rate Select, Rx channel 2 msb
  2 Rx2_Rate_Select Software Rate Select, Rx channel 2 lsb
  1 Rx1_Rate_Select Software Rate Select, Rx channel 1 msb
  0 Rx1_Rate_Select Software Rate Select, Rx channel 1 lsb
88 7 Tx4_Rate_Select Software Rate Select, Tx channel 4 msb (Not support)
  6 Tx4_Rate_Select Software Rate Select, Tx channel 4 lsb (Not support)
  5 Tx3_Rate_Select Software Rate Select, Tx channel 3 msb (Not support)
  4 Tx3_Rate_Select Software Rate Select, Tx channel 3 lsb (Not support)
  3 Tx2_Rate_Select Software Rate Select, Tx channel 2 msb (Not support)
  2 Tx2_Rate_Select Software Rate Select, Tx channel 2 lsb (Not support)
  1 Tx1_Rate_Select Software Rate Select, Tx channel 1 msb (Not support)
  0 Tx1_Rate_Select Software Rate Select, Tx channel 1 lsb (Not support)
89 All Rx4_Application_Select Software Application Select per SFF-8079, Rx Channel 4
90 All Rx3_Application_Select Software Application Select per SFF-8079, Rx Channel 3
91 All Rx2_Application_Select Software Application Select per SFF-8079, Rx Channel 2
92 All Rx1_Application_Select Software Application Select per SFF-8079, Rx Channel 1
93 7-3 Reserved  
  2 High Power Class
Enable (Classes 5-7)
When set (= 1b) enables Power Classes 5 to 7 in Byte 129 to exceed 3.5W. When cleared (=0b), modules with power classes 5 to 7 must dissipate less than 3.5W (but are not required to be fully functional). Default 0.
  1 Power_set Power set to low power mode. Default 0.
  0 Power_over-ride Override of LPMode signal setting the power mode with software.
94 All Tx4_Application_Select Software Application Select per SFF-8079, Tx Channel 4 (Not support)
95 All Tx3_Application_Select Software Application Select per SFF-8079, Tx Channel 3 (Not support)
96 All Tx2_Application_Select Software Application Select per SFF-8079, Tx Channel 2 (Not support)
97 All Tx1_Application_Select Software Application Select per SFF-8079, Tx Channel 1 (Not support)
98 7 Tx4_CDR_control Channel 4 TX CDR Control (1b = CDR on, 0b = CDR off)
  6 Tx3_CDR_control Channel 3 TX CDR Control (1b = CDR on, 0b = CDR off)
  5 Tx2_CDR_control Channel 2 TX CDR Control (1b = CDR on, 0b = CDR off)
  4 Tx1_CDR_control Channel 1 TX CDR Control (1b = CDR on, 0b = CDR off)
  3 Rx4_CDR_control Channel 4 RX CDR Control(1b = CDR on, 0b = CDR off)
  2 Rx3_CDR_control Channel 3 RX CDR Control(1b = CDR on, 0b = CDR off)
  1 Rx2_CDR_control Channel 2 RX CDR Control(1b = CDR on, 0b = CDR off)
  0 Rx1_CDR_control Channel 1 RX CDR Control(1b = CDR on, 0b = CDR off)
99 All Reserved  




F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module

F5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver ModuleF5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver ModuleF5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver ModuleF5 Networks F5-Upg-Qsfp28-Sr4 Compatible 100gbase-Sr4 Qsfp28 850nm 100m Dom MTP/MPO Mmf Optical Transceiver Module

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