QSFP28 100G 10km
Supports 103Gbps aggregate bit rates
4x25.78Gbps LAN-WDM transmitter
High-sensitivity PIN-TIA receiver
Up to 10km on SMF
Duplex LC receptacles
Hot pluggable QSFP28 form factor
Power dissipation < 3.5W
All-metal housing for superior EMI performance
RoHS6 compliant (lead free)
Operating case temperature:
Commercial: 0ºC to +70°C
    • Supports 103Gbps aggregate bit rates
    • 4x25.78Gbps LAN-WDM transmitter
    • High-sensitivity PIN-TIA receiver
    • Up to 10km on SMF
    • Duplex LC receptacles
    • Hot pluggable QSFP28 form factor
    • Power dissipation < 3.5W                    
    • All-metal housing for superior EMI performance
    • RoHS6 compliant (lead free)
    • Operating case temperature:
Commercial: 0ºC to +70°C
    • 100GBASE-LR4
    • InfiniBand QDR and DDR interconnects
    • 100G Telecom connections
    • Compliant with QSFP28 MSA
    • Compliant with SFF-8636
    • Compatible with IEEE802.3bm

The QSFP28 transceivers are designed for use in 100-Gigabit Ethernet links up to 10km over Single Mode Fiber.
The transceivers are compatible with QSFP28 MSA and SFF-8636. For further information, please refer to QSFP28 MSA and SFF-8636.

Module Block Diagram

Absolute Maximum Ratings
Power Supply VoltageVCC03.6V
Storage Temperature Ts-40+85°C
Relative HumidityRH085%
RX Input Average Power per LanePmax-5.5dBm

Recommended Operating Environment
Power Supply VoltageVCC3.133.33.46V
Power Supply CurrentICC1000mA
Power DissipationPD3.5W
Operating Case TemperatureTC0+70°C
Aggregate Data Rate-103.125Gbps
Bit Rate per LaneBR25.78125Gbps
Electrical Characteristics
Transmitter Section
Input Differential ImpedanceRin90100110Ω
Differential Data Input SwingVin PP1801000mV1
Receiver Section
Differential Data Output SwingVoutPP300850mV

  1. Connected directly to TX data input pins. AC coupling from pins into laser driver IC.

Optical Parameters
Transmitter Section
Lane Centre Wavelength (range)λ01294.531296.59nm
Spectral Width (-20dB) Δλ1nm
Side Mode Suppression RatioSMSR30dB
Average Optical Power per LanePout-4.3+4.5dBm1
OMA Power per LaneOMA-1.34.5dBm1
Laser Off Power per LanePoff---30dBm
Extinction RatioER4--dB2
Relative Intensity NoiseRIN---128dB/Hz
Optical Return Loss Tolerance--20dB
Transmitter eye mask definition
{X1, X2, X3, Y1, Y2, Y3}
Compliant with IEEE802.3bm
{0.25, 0.4, 0.45, 0.25, 0.28, 0.4}
Receiver Section
Lane Center Wavelength (range)λ01294.531296.59nm
Average Receiver Power per LaneRXPX-10.64.5dBm3
OMA Sensitivity per LaneRXsens-8.6dBm3
Los AssertLOSA-24--dBm
Los DessertLOSD---11.6dBm
Los HysteresisLOSH0.5-5dB
Overload per LanePin-max--4.5dBm3
Receiver Reflectance---12dB
Damage Threshold per Lane--5.5dBm

1. The optical power is launched into 9/125µm SMF.
2. Measured with a PRBS 231-1 test pattern @25.78Gbps.
3. Measured with a PRBS 231-1 test pattern @25.78Gbps, ER=4dB, BER <10-12.

Pin Definitions

Pin Descriptions
PinSymbolDescriptionPlug Seq.Notes
2Tx2nTransmitter Inverted Data Input 3
3Tx2pTransmitter Non-Inverted Data Input 3
5Tx4nTransmitter Inverted Data Input 3
6Tx4pTransmitter Non-Inverted Data Input 3
8ModSelLModule Select 3
9ResetLModule Reset 3
10VccRx+3.3 V Power supply receiver 22
11SCL2-wire serial interface clock 3
12SDA2-wire serial interface data 3
14Rx3pTransmitter Non-Inverted Data Input3
15Rx3nTransmitter Inverted Data Input3
17Rx1pTransmitter Non-Inverted Data Input3
18Rx1nTransmitter Inverted Data Input3
21Rx2nTransmitter Inverted Data Input 3
22Rx2pTransmitter Non-Inverted Data Input 3
24Rx4nTransmitter Inverted Data Input 3
25Rx4pTransmitter Non-Inverted Data Input 3
27ModPrsLModule Present 3
29VccTx+3.3 V Power supply transmitter 22
30Vcc1+3.3 V Power Supply 22
31LPModeLow Power Mode 3
33Tx3pTransmitter Non-Inverted Data Input3
34Tx3nTransmitter Inverted Data Input3
36Tx1pTransmitter Non-Inverted Data Input3
37Tx1nTransmitter Inverted Data Input3

Plug Seq.: Pin engagement sequence during hot plugging.
1. Module ground pins GND are isolated from the module case.
2. VccRx, Vcc1 and VccTx are the receiver and transmitter power supplies and shall be applied concurrently.

Recommended Power Interface Circuit

Recommended Interface Circuit

Digital Diagnostic Functions 
The QSFP28 transceivers 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 A0 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.
Mechanical Dimensions

Ordering information
Part NumberProduct Description
YQ21H-3110100Gbps QSFP28 LR4, 10km on SMF, 0ºC ~ +70ºC, With DDM.

1. QSFP28 MSA Specification for QSFP28 Copper and Optical Transceiver, Rev 4.7, February 2013.
2.SFF-8636 Specification for Management Interface for Cabled Environments, Rev 2.6, June 2015.
3. IEE 802.3bm - PMD Type 100GBASE-LR4.

Important Notice
Performance figures, data and any illustrative material provided in this data sheet are typical and must be specifically confirmed in writing by YOUTHTON before they become applicable to any particular order or contract. In accordance with the YOUTHTON policy of continuous improvement specifications may change without notice. The publication of information in this data sheet does not imply freedom from patent or other protective rights of YOUTHTON or others. Further details are available from any YOUTHTON sales representative.

Contact Information
EMAIL: info@youthton.com