Product Details:
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Item Name: | 100GBASE-4WDM-10 Transceiver | Form Type: | QSFP28 |
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Components: | CWDM DML + PIN | Wavelength: | 1271nm/1291nm/1311nm/1331nm CWDM |
Interface: | Duplex LC Receptacle | Max Cable Distance: | 10km |
Media: | SMF | DDM/DOM: | Supported |
Highlight: | 100GBASE-4CWDM-10, QSFP28 CWDM4 10km | ||
High Light: | 10km 100G QSFP28 Transceiver,DOM 100G QSFP28 Transceiver,QSFP28 100GBASE CLR4 |
100Gbps CWDM4 10km QSFP28 1310nm SMF Fiber Module Transceiver Duplex LC DOM
Description
Gigaopto’s 100GBASE-4WDM-10/CLR4 Optical Transceiver Module is designed for use in 100GBASE Ethernet throughput to 10km over dual-strand single mode fiber (SMF) via duplex LC connector.
The eCWDM4 module converts 4 input channels of 25.78Gb/s electrical data to 4 channels of CWDM4 optical signals and then multiplexes them into a single channel for 100Gb/s optical transmission. Reversely on the receiver side, the module demultiplexes a 100Gb/s optical input into 4 channels of CWDM4 optical signals and then converts them to 4 output channels of electrical data.
The module is with the QSFP28 38-pin connector to allow hot plug capability. The internally ac coupled high speed serial I/O simplifies interfacing to external circuitry. Only single 3.3V power supply is needed.
A serial EEPROM in the transceiver allows the user to access transceiver digital diagnostic monitoring and configuration data via the 2-wire QSFP28 Management Interface. This interface uses a single address, A0h, with a memory map divided into a lower and upper area. Basic digital diagnostic data is held in the lower area while specific data is held in a series of tables in the high memory area.
This 100G CWDM4 10km transceiver is compliant with IEEE 802.3ba, IEEE 802.3bm, 100G CWDM4 MSA, SFF-8665, SFF-8636 and ITU-T G.694.2 standards. With these features, it is suitable to be used in various applications, such as 100G Ethernet switch, router, and client-side telecom interfaces.
Specification
Form Type | QSFP28 100G eCWDM4 | Max Data Rate | 103.125Gbps (4x 25.78Gbps) |
Lane Wavelength | 1271nm, 1291nm, 1311nm and 1331nm | Max Cable Reach | 10km with FEC |
Connector type | Dual-LC receptacle | Media | SMF |
Transmitter | DML CWDM | Receiver | PIN |
TX Out Power (dBm) | -6.5~2.5dBm | Receiver Sensitivity | <-13 dBm |
Extinction Ratio | >3.5dB | Receiver Overload | > 2.5 dBm |
Power-budget (dB) | 6.5dB | Power Dissipation | ≤3.5W |
DDM/DOM | Supported | Temperature Range | 0 to 70°C (32 to 158°F) |
Packaging Technology | COB (chip on board) | Modulation Format | NRZ |
CDR (Clock and Data Recovery) | TX & RX Built-in CDR | Host FEC | Supported |
OEM/ODM | Supported | Warranty | 3 years |
Protocols |
QSFP28 MSA Compliant,CWDM4 MSA,100G 4WDM4-10 MSA,RoHS |
Feature
Applications
Standard
Optical Characteristics
Parameter | Symbol | Min | Typical | Max | Unit | Notes |
Lane Wavelength |
L0 |
1264.5 |
1271 |
1277.5 |
nm |
|
L1 |
1284.5 |
1291 |
1297.5 |
nm |
||
L2 |
1304.5 |
1311 |
1317.5 |
nm |
||
L3 |
1324.5 |
1331 |
1337.5 |
nm |
||
Transmitter | ||||||
SMSR |
SMSR |
30 |
dB |
|||
Total Average Launch Power |
PT |
8.5 |
dBm |
|||
Average Launch Power, each Lane |
PAVG |
-6.5 |
2.5 |
dBm |
||
OMA, each Lane |
POMA |
-4.0 |
2.5 |
dBm |
1 |
|
Launch power in OMA minus TDP |
-5 |
dB |
||||
TDP, each Lane |
TDP |
3.0 |
dB |
|||
Extinction Ratio |
ER |
3.5 |
dB |
|||
RIN20OMA |
RIN |
-130 |
dB/Hz |
|||
Optical Return Loss Tolerance |
TOL |
20 |
dB |
|||
Transmitter Reflectance |
RT |
-20 |
dB |
|||
Eye Mask coordinates: X1, X2, X3, Y1, Y2, Y3 |
{0.31, 0.4, 0.45, 0.34, 0.38, 0.4} |
2 |
||||
Average Launch Power OFF |
Poff |
-30 |
dBm |
|||
Parameter | Symbol | Min | Typical | Max | Unit | Notes |
Transmitter, each Lane | ||||||
Receiver | ||||||
Damage Threshold, each lane |
THd |
3.5 | dBm | 3 | ||
Average Receive Power, each lane |
-13.0 |
2.5 |
dBm |
|||
Receive Power (OMA), each lane |
2.5 |
dBm |
||||
Receiver Sensitivity (OMA), each Lane |
SEN |
-11.5 |
dBm |
4 |
||
Stressed Receiver Sensitivity (OMA), each Lane | -8.6 | dBm | 5 | |||
LOS Assert | LOSA | -16 | dBm | |||
LOS Deassert | LOSD | -14 | dBm | |||
LOS Hysteresis | LOSH | 0.5 | 2 | 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 | VECP | 1.9 | dB | 6 | ||
Stressed Eye J2 Jitter | J2 | 0.33 | UI | |||
Stressed Eye J4 Jitter, | J4 | 0.48 | UI |
Note:
1. Even if the TDP < 1 dB, the OMA min must exceed the minimum value specified here.
2. Hit ratio of 5e-5, per IEEE; See Figure 2 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 = 5e-5 BER.
5. Measured with 4WDM-10 MSA conformance test signal at TP3 for 5e-5BER.
6. Vertical eye closure penalty and stressed eye jitter are test conditions for measuring stressed receiver sensitivity. They are not characteristics of the receiver.
Compatibility
Gigaopto's optical transceivers are 100% compatible with many famous switch brands and will not cause damage to OEM devices. In order to ensure the quality and compatibility of our products, each product is carefully tested on the corresponding equipment before delivery to customers.
For this 100G eCWDM4 GTQ-L27B4-10DC compatibility, please refer to the P/N correspondence table. If the brand and part number you are looking for is not listed below, please let us know and we will be delighted to provide you with more details.
Corresponding Compatible Brand/Part Number | |||
Brand | Part Number | Brand | Part Number |
Gigaopto | GTQ-L27B4-DC | Arista | QSFP-100G-LR4-AN |
Cisco | QSFP-100G-4WDM-S | Juniper | JNP-QSFP-100G-4WDM |
Dell | QSFP-100G-4wdm-10 | Brocade | 100G-QSFP28-4WDM-10KM |
D-Link | DEM-Q28X10Q-4WDM | Mellanox | QSFP28-EIR4-100G |
F5 Networks | F5-UPG-QSFP28-WDM10 | Fortinet | FG-TRAN-QSFP28-4WDM |
Avago | AFCT-89LDDZ | Palo Alto Networks | PAN-100G-QSFP28-4WDM |
H3C | QSFP-100G-EIR4-WDM1300 | MikroTik | Q28+EIRDLC10D |
Check Point | CPAC-TR-100EIR-SSM160-QSFP28-C | Chelsio | SM100G-4WDM-10 |
Allied Telesis | QSFP28-4WDM-10 | MRV | QSFP28-100GE-4WDM10 |
Edge-Core | ET7402-4WDM-10 |
Mechanical Dimensions
For More of our QSFP28 100GBASE Transceiver Series, please refer to the following form
P/N | Description | Wave Length | Reach | TX/RX | TX Power (dBm) | Rx Sens. (dBm) |
GTQ-M08B4-01DC | QSFP28 100G SR4 | 850nm | 100m | 850nm VCSEL/PIN | -8.4~2.4 | <-10.3 |
GTQ-M08B4-02DC | QSFP28 SR BD | 850/900nm | 100m | 850/900nm VCSEL/PIN | -5.5 - 3 | <-9.5 |
GTQ-M08B4-03DC | 100GBASE eSR4 | 850nm | 300m | 850nm VCSEL/PIN | -8.4~2.4 | <-10.3 |
GTQ-M13B4-P5DC | QSFP28 PSM4-S | 1310nm | 500m | 1310nm DFB/PIN | -9.4~2 | <-12.66 |
GTQ-M13B4-02DC | QSFP28 PSM4-S | 1310nm | 2km | 1310nm DFB/PIN | -6.0~2 | <-10.5 |
GTQ-L27B4-02DC | 100G CWDM4 | 1311nm CWDM | 2km | CWDM DML/PIN | -6.5~2.5 | <-11.5 |
GTQ-L27B4-10DC | 100G eCWDM4 | 1311nm CWDM | 10km | CWDM DML/PIN | -6.5~2.5 | <-13 |
GTQ-L13B4-10DC | QSFP28 LR4 | LAN WDM | 10km | LWDM DFB/PIN | -4.3~4.5 | <-10.6 |
GTQ-L13B4-20DC | QSFP28 eLR4 | LAN WDM | 20km | LWDM DML/PIN | -4.3~4.5 | <-14.5 |
GTQ-L13B4-40DC | QSFP28 ER4 Lite | LAN WDM | 40km(with FEC) | LWDM EML/APD | -2.9~4.5 | <-20.9d |
GTQ-L13B4-80DC | QSFP28 ZR4 | LAN WDM | 80km | LWDM EML/PIN+SOA | 2~6.5 | <-28 |
GTQ-N13B4-10MC | Dual 100/112G LR4 | LAN WDM | 10km | LWDM DML/PIN | -4.3~4.5/-0.6~4 | <-8.6/<-8.4 |
GTQ-N13B4-20MC | Dual 100/112G eLR4 | LAN WDM | 20km | LWDM DML/PIN | -1.0~+4.5/0~4 | <-9.5/<-9.0 |
GTQ-N13B4-40MC | Dual 100/112G ER4 | LAN WDM | 40km | LWDM DML/PIN | -2.5~2.9/-1~3.3 | <-15/<-19 |
GTQ-L13D1-P5DC | 100G QSFP28 DR1 | 1310nm | 500m | PAM4 EML/PIN | -2.9~4 | <-5.9 |
GTQ-L13D1-02DC | 100G QSFP28 FR1 | 1310nm | 2km | PAM4 EML/PIN | -2.4~4 | <-6.4 |
GTQ-L13D1-10DC | 100G QSFP28 LR1 | 1310nm | 10km | PAM4 EML/PIN | -1.4~4.5 | <-7.7 |
Note: OEM/ODM supported.
FAQ:
What is the advantage of the CWDM modules? Is there any difference from the usual one?
RE: CWDM can provide larger transmission capacity, saving optical fiber resources(signals of different rates and formats can be mixed, as long as the rates at both ends of the combined wave front and the split wave rear are consistent)
Contact Person: Ophelia Feng
Tel: +86 15882203619