In today’s optical communications market, there are a variety of transceiver modules with various types of interfaces. Because different types of cables/connectors/adapters are required for different interfaces, we need to pay more attention when selecting the relevant assemblies. This article will give you a detailed introduction to the mainstream transceiver module interfaces on the market, so that everyone has a clearer understanding of the transceiver modules.
First of all, we use the following table to list all transceiver modules’ interfaces.
|Form Factor||Transmission Mode||Interface||Example|
|QSFP-DD||Parallel||MPO||200G QSFP-DD SR8/PSM8|
|QSFP-DD||Multiplexing||Dual CS||200G QSFP-DD CWDM8|
|QSFP28||Parallel||MPO||100G QSFP28 SR4/PSM4|
|QSFP28||Multiplexing||Duplex LC||100G QSFP-DD LR4/CLR4/CWDM4/ER4|
|QSFP+||Parallel||MPO||40G QSFP+ SR4/PSM4|
|QSFP+||Multiplexing||Duplex LC||40G QSFP+ LR4|
|SFP28||Dual Fiber||Duplex LC||25G SFP28 SR/LR|
|SFP28||Single Fiber Bidirectional||Simplex LC||25G SFP28 BiDi|
|SFP+||Dual Fiber||Duplex LC||SFP+ 10GBASE-SR/LR|
|SFP+||Single Fiber Bidirectional||Simplex LC/SC||SFP+ BiDi|
|SFP+||2-channel Bidirectional||Dual LC||SFP+ 2-channel BiDi|
|SFP+||Electrical Copper Cable||RJ-45||SFP+ 10GBASE-T|
|SFP||Dual Fiber||Duplex LC||SFP 1000BASE-SX/LX|
|SFP||Single Fiber Bidirectional||Simplex LC/SC||SFP BiDi|
|SFP||2-channel Bidirectional||Dual LC||SFP 2-channel BiDi (CSFP)|
|SFP||Electrical Copper Cable||RJ-45||SFP 1000BASE-T|
|CXP||Parallel||MPO||120G CXP SR10|
|CFP||Parallel||MPO||100G CFP SR10|
|CFP||Multiplexing||Duplex LC||100G CFP LR4/ER4|
|CFP2||Parallel||MPO||100G CFP SR10|
|CFP2||Multiplexing||Duplex LC||100G CFP2 LR4/ER4|
|CFP4||Parallel||MPO||100G CFP4 SR4|
|CFP4||Multiplexing||Duplex LC||100G CFP4 LR4/ER4|
As the table shows, although there are more than a dozen types of transceiver modules, there are only a few types of interfaces. These types of optical interfaces are LC, SC, MPO, and CS. And there are also electrical copper transceiver modules using the RJ-45 interface. Among these interfaces, the LC interface can be divided into duplex and simplex, and there are dual-simplex LC interface (such as CSFP). For BiDi optical transceivers, there are also simplex SC interface, in addition to the simplex LC. We will introduce each of these interfaces one by one, according to the transmission modes of the transceiver modules.
As we konw, a transceiver module consist of a transmiter and a receiver. This means that the transmission has two directions. For the common single-channel optical transceivers, such as SFP28, SFP+, and SFP, the transmitting terminal is connected to one optical fiber and the receiving terminal is also connected to one optical fiber. That’s why the common optical transceivers are called dual-fiber transceiver generally. The dual-fiber transceiver has a duplex LC interface connected to a duplex LC patch cable. (The XENPAK, X2, and GBIC dual-fiber transceivers, not listed in the table, have a duplex SC interface connected to a duplex SC patch cable.)
The single-fiber bidirectional transmission mode is called BiDi for short. The BiDi signals in both directions are combined in a single fiber. The bidirectional transmission means that the light is directional and will not interference each other. The BiDi optical transceiver, such as BiDi SFP+ and BiDi SFP, have a simplex LC or SC interface connected to a simplex LC or SC patch cable. And for high-density BiDi transmission networks, there are 2-channel BiDi SFP+/SFP (CSFP+/CSFP) optical transceivers using dual simplex LC interface.
For multi-channel optical transceivers, such as 4-channel QSFP+, 4-channel QSFP28, and 8-channel QSFP-DD, there are several Tx and several Rx. Some of them (such as 100G QSFP28 SR4 and 100G QSFP28 PSM4) have MPO interfaces, that is, multi-fiber pull on/off, using multiple optical fibers for the parallel transmission shown as the figure below.
There are also dual-fiber 4-channel optical transceivers using the multiplexing transmission mode, that is, multiple Tx multiplexing and Rx demultiplexing. These optical transceivers, such as 40G QSFP+ LR4 and 100G QSFP28 CWDM4, use two optical fibers for long-distance transmission, saving more optical fiber resources than using multi-core optical fibers. Like the common single-channel optical transceiver, the dual-fiber 4-channel optical transceiver also has a duplex LC interface connected to a duplex LC patch cable.
The QSFP-DD MSA specification defines an 8-channel module, cage and connector system. The cage and connector system provides backward compatibility to the 4-channel QSFP28 modules. Doubling the number of duplex optical links with the QSFP-DD specification requires a new smaller optical interconnect to fit in the same physical cage form factor. For the eight-channel QSFP-DD optical transceivers using the multiplexing transmission mode, a new type of optical interface called dual CS is used to replace the duplex LC. The dual CS interface is connected to the CS connector, a miniature single-position plug which is characterized by duo cylindrical, springloaded butting ferrule(s) of a 1.25 mm typical diameter, and a push-pull coupling mechanism. The CS connector provides the characteristics and simplicity of the duplex LC connector into a smaller footprint to allow 2 pairs of CS connectors to fit within the physical constraints of the QSFP-DD form factor.
The RJ-45 interface is used in copper transceiver modules, such as 10G copper SFP+, 1G copper SFP and 100M copper SFP. The copper SFP+ transceivers transmit electrical signals over Category 6a or Category 7 copper cables with RJ-45 connectors, while the copper SFP transceivers transmit electrical signals over Category 5 or Category 5e copper cables with RJ-45 connectors.
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