QSFP28 CWDM4 vs. QSFP28 PSM4: Which One Is Better?

Although a series of 200G or even 400G optical transceiver products emerge in the optical communication market, and they have not yet been put into commecial use currently due to that they are still in the stage of preparation in some aspects. Thus, 100G optical transceiver modules, especially QSFP28 PSM4 and QSFP28 CWDM4, are still spoiled in various application fields. Well, for these two optical transceivers, what are their differences and which one is better? The answers will be found in this article.

A Brief Introduction to QSFP28 PSM4 Optical Transceiver

PSM4, the abbreviation of Parallel Single Mode 4-channels, a optics with parallel technology, defined by the 100G PSM4 MSA(Multi-Source Agreement). It uses four lanes of parallel single fiber to deliever serialized data at a rate of 25Gbps per lane. 100GE PSM4 QSFP28 will be the optical transceiver that enables single-mode fiber to become popular in next-generation data centers due to its low cost and high configurability. It doesn’t need a MUX/DEMUX for each laser but it does need a directly modulated DFB laser (DML) or an external modulator for each fiber. QSFP28 100G PSM4 uses eight fibers, in which four fibers are for transmitting and four fibers are for receiving. A PSM4 QSFP28 optical module supports link lengths of up to 500 meters over single-mode fiber with 12 fiber MTP/MPO connectors. The light source of QSFP 100G PSM4 optic module is a single uncooled distributed feedback (DFB) laser operating at 1310nm.

A Brief Introduction to QSFP28 CWDM4 Optical Transceiver

The QSFP28 100G CWDM4 optical transceiver is a full duplex, photonic-integrated optical transceiver module that provides a high-speed link with a maximum transmission distance of 2km for 100G Ethernet. 100G QSFP CWDM4 is designed for optical communication applications compliant with the QSFP MSA, CWDM4 MSA and portions of IEEE P802.3bm standard. CWDM4 interfaces with LC duplex connectors. It converts 4 input channels of 25Gb/s electrical data to 4 channels of CWDM optical signals and then multiplexes them into a single channel for 100Gb/s optical transmission. Specifically speaking, four lanes with center wavelengths of 1270nm, 1290nm, 1310nm and 1330nm are controlled on the transmitting end. On the receiving end, four lanes of optical data streams are optically de-multiplexed by an integrated optical demultiplexer. With an optical multiplexer and de-multiplexer, one just uses a duplex single-mode fiber to connect two 100G CWDM4 optical transceivers.

QSFP28 CWDM4 vs. QSFP28 PSM4: Which One Is More Cost-Effective?

After knowing the basic information of PSM4 QSFP28 and CWDM4 QSFP28 optical transceiver, the comparison between them will be made in the following content to know which one is better. It is mainly made from perspectives of similarities and differences, shown as below:

Similarities of QSFP28 CWDM4 and QSFP28 PSM4 Optical Transceiver:

Optic Fiber Types: Both 100G QSFP CWDM4 and 100G QSFP PSM4 use single-mode fiber to transmit.

The Number of Lane: Both of 100G QSFP28 CWDM4 and 100GE PSM4 QSFP28 use 4 lanes(4×25Gbps) to achieve 100Gbps.

Wavelength: The wavelength of QSFP28 100G CWDM4 and QSFP28 100G PSM4 is around 1310 nm.

Differences of QSFP28 CWDM4 and QSFP28 PSM4 Optical Transceiver :

Connector Types: QSFP-100G-CWDM4-S optical transceiver is with LC duplex connector, while QSFP-100G-PSM4-S optics is with MTP/MPO connector.

Transmission Distance: The transmission distance of 100G QSFP CWDM4 optics is longer than that of QSFP 100G PSM4 optics. The maximum transmission distance of CWDM4 QSFP28 and PSM4 QSFP28 are respectively 2kms and 500ms.

Cost: QSFP28 CWDM4 optical transceiver module is more expensive than QSFP28 PSM4 optical transceiver module. It is on accoun that CWDM4 QSFP28 optics needs 4-wavelengths coarse wavelength division multiplexer(high in cost) while PSM4 QSFP28 optics does not need.

The Number of Optic Fiber: QSFP28 CWDM4 uses 2 single-mode fibers to transmit while QSFP28 PSM4 uses 8 single-mode fibers for transmission.

qsfp28 psm4 vs. qsfp28 cwdm4

As the components such as multiplexer/demultiplexer for the CWDM4 QSFP28 optical transceiver are very expensive, the cost of 100G QSFP28 CWDM4 optical module is much higher than that of 100G QSFP28 PSM4 optical module. It is seen from above information that QSFP28 PSM4 seemingly is more cost-effective choice than QSFP28 CWDM4. However, if the cost is taken into account from perspective of whole 100G connection, it should actually depend on the link distance. For PSM4 QSFP28 optics, as the connection distance increases, its total cost climbs up very fast due to increasing in the number of optic fibers. Therefore, 100GE PSM4 QSFP28 optics is a recommended solution with cost effectiveness for the deployment of 100G network with short reach. On the contrary, if it is to deploy 100G network with long-reach, 100GE CWDM4 QSFP28 is the better choice.

Conclusion

It is believed that the answers about what the differences between 100G QSFP28 CWDM4 and 100G QSFP28 PSM4 optical module are and which one is better are very clear. If you want to know more about them in this aspect, Gigalight official website is available for you.

About Gigalight:

Gigalight is a design innovator in global optical interconnect field. A series of optical interconnect products include: optical transceivers, passive optical components, active optical cables, GIGAC MTP/MPO cabling, cloud programmers & checkers, etc. Three applications are mainly covered: Data Center & Cloud Computing, MAN & Broadcast Video, and Mobile Network & 5G Optical Transmission. Gigalight takes advantage of its exclusive design to provide clients with one-stop optical network devices and cost-effective products.

How Much Do You Know about QSFP28 CWDM4?

These years， data center has always been expanded at the high speed and higher rate of single port are required, which contributes to the wide applications of 100G in the data center. While in the practical use, many optical transceiver usually can’t meet the demands on the deployment of data center by the way of saving cost, on account of the variety  in the lengths of optic fiber channel. For it, 2 km 100G QSFP28 CWDM4 appears in the current optical components market. Well, this article will have an introduction to QSFP28 CWDM4  from perspectives of CWDM4 definition, CWDM4 MSA as well as advantages and applications of QSFP28 CWDM4 by Gigalight.

What’s CWDM4 Optical Transceiver?

The 100G QSFP28 CWDM4 optical transceiver is a full duplex, photonic-integrated optical transceiver module that provides a high-speed link with a maximum transmission distance of 2km for 100G Ethernet. CWDM4 interfaces with LC duplex connectors. It uses 4×25Gbps to achieve 100Gbps. Specifically speaking, four lanes with center wavelengths of 1270nm, 1290nm, 1310nm and 1330nm are controlled on the transmit side. On the receiving side, four lanes of optical data streams are optically de-multiplexed by an integrated optical demultiplexer. With an optical multiplexer and de-multiplexer, one just uses a duplex single-mode fiber to connect two 100G CWDM4 optical transceivers. CWDM4 has many advantages, such as low power consumption, high compatibility, Digital Diagnostic Monitoring (DDM) support and so on. Nowadays, it has been widely applied in Local Area Network (LAN), Wide Area Network (WAN), and Ethernet switches and router application.

 

What’s CWDM4 MSA ?

The CWDM4 MSA (Multi-Source Agreement) targets a common specification for low-cost 100G optical interfaces that run up to 2km in data center applications. The MSA uses CWDM technology with 4 lanes of 25Gbps optically multiplexed into and demultiplexed from duplex single-mode fiber. CWDM4 MSA targets the broad data center 100G interconnects that support FEC applications.

CWDM4 MSA’  members consist of Avago Technologies, Finisar Corporation, JDSU and Oclaro, Inc. The Multi-Source Agreement (MSA) defines 4 x 25Gbps Coarse Wavelength Division Multiplex(CWDM) optical interfaces for 100Gbit/s optical transceivers in Ethernet applications including 100GbE. Forward error correction (FEC) is required to be implemented by the host in order to ensure reliable system operation. Two transceivers communicate over single mode fibers(SMF) of length from 2 meters to at least 2 kilometers. The transceiver electrical interface is not specified by this MSA but can have four lanes in each direction with a nominal signaling rate of 25.78125Gbps per lane.

Different form factors for the transceivers are possible. Initial implementations are expected to use the CFP4 or the QSFP28 module form factors. Other form factors are possible and are not precluded by this MSA.

Advantages and Applications of QSFP28 CWDM4

CWDM4 has many advantages, such as low power consumption, high compatibility, Digital Diagnostic Monitoring (DDM) support, high transmission rate, long transmission distance and so on, in which the long transmission distance is its most highlighted feature. It adopts WDM (Wavelength Division Multiplex) tech, full-duplex LC connector and single-mode fiber, which are helpful to realize 2km reaches. Besides, on account of the adoption of WDM, it just needs two single-mode fibers to realize the transmission, which, to some degree, save the costs in fibers. At this time, compared with QSFP28 PSM4 in cost and transmission distance, QSFP28 CWDM4 is preferred.

As for its applications, by virtue of its various advantages, it’s widely utilized in many fields, such as CATV(Community Antenna Television), FTTH(Fiber To The Home), 1G and 2G fiber channel, Gigabit Ethernet, SONET (Synchronous Optical Network) OC-3（155Mbps）/OC-12（622Mbps）/ OC-48（2.488Gbps） , Security and Protection systems; also in Local Area Network (LAN), Wide Area Network (WAN), and Ethernet switches and router application.

Conclusion

Although CWDM4 transceiver is high in cost, and the it’s still an economical solution for long transmission distance. Whether in aspects of link’ lengths or cost savings, it can meet the needs in a cost-effective way by DWM. Maybe it will get improved with the advances in future tech. We will see.

Note: article resource from www.gigalight.com.