400G SR4 vs. 400G SR4.2: What Is the Difference?
As the demand for higher bandwidth and faster data transmission continues to escalate, the networking industry is constantly innovating to meet these needs. In the realm of 400G Ethernet, two technologies, 400G SR4 and 400G SR4.2, have emerged as prominent solutions. While they may appear similar, each has unique features and benefits that cater to different networking scenarios. This article delves into the differences between 400G SR4 and 400G SR4.2, helping you understand which one might best fit your networking needs.
Understanding 400G SR4
400G SR4 is part of the IEEE 802.3bs standard. It leverages four parallel fibers for transmitting data and four parallel fibers for receiving data, supporting a total of eight fibers. Each fiber operates at a rate of 100 Gbps, thus aggregating to 400 Gbps. The "SR" in SR4 stands for "Short Reach," and the "4" indicates four lanes of transmission. 400G SR4 is a high-speed Ethernet solution designed to meet the increasing demand for data transmission in data centers and other high-performance networking environments.
The 400G SR4 interface uses an MPO/MTP (Multi-Fiber Push-On/Pull-Off) connector, which contains 12 or 16 fibers. In the SR4 configuration, 8 of these fibers are active (4 for transmitting and 4 for receiving), while the remaining fibers are either unused or reserved for future use.
Key Features of 400G SR4
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High Data Rate: Provides a robust 400Gbps data rate, suitable for high-demand applications.
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Single Wavelength: It uses 850nm wavelength VCSELs (Vertical-Cavity Surface-Emitting Lasers).
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Short Reach: It supports a reach of up to 100 meters over OM4 multimode fiber and up to 70 meters over OM3 multimode fiber.
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Applications: Optimized for short-distance communication, ideal for intra-data center connections.
FS 400G SR4 Transceivers
The FS 400G SR4 transceivers feature compact OSFP, QSFP112, and QSFP-DD form factors, making them ideal for high-speed data centers and high-performance computing networks. Key selling points include support for 400Gbps transmission rates, low power consumption, high-density, and multimode fiber connectivity. These transceivers offer an efficient and cost-effective solution while being compatible with existing 400G/100G infrastructure, ensuring seamless upgrades and exceptional performance. The following picture shows the 400G-to-400G link to ConnectX-7 of QSFP-DD 400G SR4.
| OSFP-SR4-400G-FL | QSFP112-SR4-400G | QDD-SR4-400G | |
| Center Wavelength | 850nm | 850nm | 850nm |
| Connector | MTP/MPO-12 | MTP/MPO-12 | MTP/MPO-12 |
| Cable Distance (Max.) | 30m/50m@MMF | 50m@MMF | 60m/100m@MMF |
| Modulation | 4x 106.25G PAM4 | 4x 100G PAM4 | 8x 50G PAM4 |
| DSP | 7nm DSP | Broadcom 7nm DSP | Maxlinear |
| Power Consumption | ≤8.5W | ≤9W | ≤8W |
| Transmitter Type | VCSEL | VCSEL | VCSEL |
| Packaging Technology | COB | COB | COB |
| Application | InfiniBand 800G to 2x400G Breakout |
Data Center | Data Center 400G to 2x200G Breakout 400G to 4x100G Breakout |
Understanding 400G SR4.2
400G SR4.2, on the other hand, is a newer standard defined by the IEEE 802.3cm. 400G SR4.2 utilizes wavelength multiplexing to enhance the performance of each fiber pair, making it a more efficient solution. The primary difference between 400G SR4 and 400G SR4.2 lies in its wavelength division multiplexing (WDM) capabilities.
The optical lane arrangement is shown as follows. The leftmost four positions are labeled TR because they transmit wavelength λ1 and receive wavelength λ2. Conversely, the rightmost four positions are labeled RT because they receive wavelength λ1 and transmit wavelength λ2. Wavelength λ1 is traditionally set at 850 nm. The second wavelength, λ2, is nominally set at 910 nm, which supports longer reaches over OM5 multimode fiber, optimized for short wavelength multiplexing. As a result, the reach over OM5 is 50% longer than over OM4 and more than double that over OM3.
Key Features of 400G SR4.2
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Wavelength Multiplexing: Each fiber pair carries two wavelengths of 850nm and 910nm, effectively doubling the capacity.
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Extended Reach: Support up to 150 meters over OM5 multimode fiber and up to 100 meters over OM4 multimode fiber, providing greater flexibility in deployment and addressing some of the limitations of 400G SR4 in larger data centers.
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Fiber Efficiency: 8 fibers (4 transmit and 4 receive) technically, but with each fiber carrying two wavelengths, reducing overall material and installation costs.
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Applications: Suitable for data centers requiring longer reach connections within the same multimode infrastructure.
FS 400G SR4.2 Transceivers
FS QSFP-DD 400G SR4.2 transceivers enable seamless breakout to 4x QSFP28 100G SR1.2 optics, facilitating the creation of 400G connections to meet the increasing demand for higher data rates. These transceivers comply with the IEEE 802.3 protocol and the 400GAUI-8/PAM4 standard. They feature built-in digital diagnostics monitoring (DDM) for real-time access to operating parameters, making them ideal for 400G Ethernet and data center interconnect applications. Moreover, this breakthrough architecture is achieved while leveraging existing fiber cable infrastructure, thereby optimizing cost-effectiveness.
| QDD-SR4.2-400G | |
| Center Wavelength | 850nm,910nm |
| Connector | MTP/MPO-12 |
| Cable Distance (Max.) | 70m@OM3/150m@OM5 |
| Modulation | 8x 53.125G PAM4 |
| DSP | 70m/150m@MMF |
| Power Consumption | ≤12W |
| Transmitter Type | VCSEL 850nm |
| Packaging Technology | COB |
| Application |
Data Center 00G to 4x 100G Breakout |
400G SR4 vs. 400G SR4.2
In the rapidly evolving realm of data centers and high-performance computing networks, the demand for increased data throughput has made 400G optical transceivers a pivotal technological choice. Among these, 400G SR4 and 400G SR4.2 are prominent solutions, each offering distinct differences in transmission methods, distances, and application scenarios. Understanding these differences is crucial for network architects and engineers to select the most suitable solution for their specific deployment needs.
The following table shows a clear comparison between them.
| 400G SR4 | 400G SR4.2 | |
| Wavelength Multiplexing | 1 wavelength (850nm) | 2 wavelengths (850nm and 910nm) |
| Reach | 100m over OM4 and 70m over OM3 | 150m over OM5 and 100m over OM4 |
| Fibers | 8 fibers | 8 fibers |
| BiDi Technology | / | Support |
| Infrastructure Requirements | Relies on traditional OM3 and OM4 multimode fibers. | Benefits from using OM5 fiber, which is optimized for WDM and can take advantage of the dual-wavelength approach. |
| Cost and Installation | Generally, the cost is lower due to the use of a single wavelength and existing OM3/OM4 multimode fiber infrastructure. | Potentially higher upfront costs due to the need for OM5 fiber and more complex transceiver technology, but offers greater scalability and future-proofing. |
| Applications and Use Cases | Ideal for smaller data centers or segments within data centers where distances are relatively short. | Better suited for larger data centers with more significant distances between switches and servers. |
Summary
Both 400G SR4 and 400G SR4.2 play crucial roles in the evolution of high-speed networking within data centers. Choosing between them largely depends on your specific needs regarding reach, existing infrastructure, and future scalability. 400G SR4 is a solid choice for short-reach, cost-sensitive deployments, while 400G SR4.2 offers enhanced performance for more extensive and future-proof data center environments.
By understanding the differences and advantages of each technology, network architects and IT professionals can make informed decisions to optimize their network performance and accommodate the ever-growing demand for higher data rates and improved efficiency. Both 400G SR4 and 400G SR4.2 represent significant advancements in Ethernet technology, ensuring that modern data centers can keep pace with the rapid evolution of digital communication.
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