800G Modules New Arrival!

800G Modules New Arrival!

800G Modules New Arrival!

400G QSFP112 SR4 VS QDD SR4 VS QDD SR8: What are the differences?

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As the demand for data centers and network infrastructure continues to increase, so does the need for higher-speed and more efficient data transmission solutions. Against this backdrop, 400G fiber optic transmission technology has emerged. It was used as an important technology for large-scale data centers, cloud computing, and high-performance computing. Today, there are several different types of 400G optical modules on the market. QDD SR4, QSFP112 SR4and QDD SR8 are common packages. These modules all belong to the 400G transmission standard; but there are significant differences in interfaces, bandwidth, and transmission distance. As a result, in this paper, we will delve into the main differences between these three modules to help understand their advantages and applicability in different application scenarios.

1. 400G QSFP112 VS 400G QDD

1.1. QSFP112 Introduction

400g QSFP112 SR4

Figure 1: 400G QSFP112 SR4

QSFP112 (Quad Small Form-factor Pluggable 112) is a new type of fiber optic module package for 400G data transmission. This package form factor enables the optical module to have digital diagnostic monitoring (DDM) and control functions. It has four transmission channels, each providing 100 Gbps of bandwidth, for a total of 400 Gbps.What’s more, it uses standard QSFP interfaces, fits into most existing fiber optic architectures, and supports transmission over long distances (typically up to 100 meters). The QSFP112 module benefits from its broad compatibility and more mature technology.

Because qsfp112 offers very high bandwidth, it has a low individual channel bandwidth (100 Gbps per channel transmission) due to its 4-channel design, which can be a bottleneck in certain applications that require very high bandwidth.

1.2.400G QDD Introduction

The 400G Quad Density module was developed to meet the need for higher port density and more compact designs, also using a 4-channel design but with different physical dimensions and connectivity interfaces. The QDD interface is more compact than the QSFP112 interface, providing higher port density and allowing data centers to deploy more fiber optic ports in limited space. fiber optic ports in limited space. What’s more, the QDD module not only maintains the 400Gbps transmission rate but also provides more ports to deploy more fiber connections in the same space.

2. QDD SR4 vs QDD SR8

2.1. SR4 Introduction

400G QSFP-DD SR4

Figure 2: 400G QDD SR4

SR4 module adopts 4 optical signal channels; each channel transmits 100 Gbps, and the total bandwidth reaches 400 Gbps. So SR4 (Short Range 4) means that it is mainly used for short-distance transmission, usually working on multimode fiber, and the maximum transmission distance can reach 100 meters. This module is ideal for high-speed connectivity within data centers, especially in environments requiring high port density and limited space.

2.2. SR8 Introduction

400G QSFP-DD SR8

Figure 3: 400G QDD SR8

QDD SR8 is another optical module in the QDD series, providing 8 optical signal channels; each channel also transmits 100 Gbps with a total bandwidth of 800 Gbps, which means that the QDD SR8 provides twice as much bandwidth as the QDD SR4, and is able to satisfy the demand for larger-scale data transmission. The QDD SR8 module has the same bandwidth per channel as the QDD SR4, but because of the increase in the number of channels, the overall transmission capacity is much higher.

3.400G QSFP112 SR4 VS QDD SR4 VS QDD SR8 Key Features

Key features of the QSFP112 SR4 include:

  • Bandwidth: Supports 400 Gbps high-speed data transmission.
  • Number of channels: Uses 4 optical signaling channels.
  • Connector: Standard LC connector.
  • Distance: Up to 100 meters on multimode fiber.

QDD SR4 module features:

  • Data rate: Also supports 400 Gbps high-speed data transmission.
  • Channel quantity: 4 optical signaling channels are used.
  • Connector: QDD standard connector (smaller than QSFP112).
  • Transmission distance: Also applicable to multi-mode fiber, transmission distance is 100 meters.

Features of the QDD SR8 module include:

  • Transfer rate: Also supports data transmission up to 800 Mbps.
  • Channel count: 8 optical signaling channels are used.
  • Connector: QDD standard connector.
  • Transmission distance: 100 meters over multimode fiber.
FeatureQSFP112 SR4QDD SR4QDD SR8
Bandwidth400Gbps400Gbps800Gbps
Channel Count448
ConnectorLC ConnectorQDD Connector
 (More Compact)
QDD Connector
(More Compact)
Transmission Distance100 meters
(Multimode Fiber)
100 meters
(Multimode Fiber)
100 meters
(Multimode Fiber)
ApplicationData Center
Short Distance
Connectivity
Data Center
High-Density Ports
High-Bandwidth,
 High-Traffic Applications

Figure 4: 400G QSFP112 SR4 VS QDD SR4 VS QDD SR8

4. Application Scenarios and Selection Recommendations

QSFP112 SR4: Since it usually supports a transmission distance of 100 meters, it is suitable for internal data centers and inter-adjacent rack connections. For traditional large-scale data center architectures, QSFP112 SR4 is a proven choice, especially in applications that require high compatibility and stability, such as cloud computing, storage virtualization, and large-scale databases.

QDD SR4: Its more compact design delivers higher port density for scenarios where space is at a premium but high bandwidth is still required. The QDD SR4 is suitable for high-density data center environments, especially in scenarios where more connectivity ports are required but space is at a premium, such as hyperscale data centers, hosting services, and cloud service provider infrastructures.

QDD SR8: It provides higher bandwidth and is suitable for application scenarios where bandwidth is critical. And it has a significant increase in transfer rate and bandwidth compared to QDD SR4, so it can better support large-scale data exchange and high-bandwidth applications, such as big data analytics, AI training, and high-performance computing.

5 Conclusion

Although these modules can all provide more than 400G of bandwidth, their respective channel counts, interface standards, port densities, and transmission capacity differences make them suitable for different network architectures and application requirements. Choosing the right module is not only about bandwidth requirements but also about making decisions based on data center space, connectivity, and future expansion needs.

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