The QSFP-100G-PSM4-S is a 100G QSFP28 optical transceiver module designed for high-speed data communication in modern data centers, enterprise networks, and high-performance computing environments. It utilizes parallel single-mode fiber (PSM4) technology, offering high-bandwidth connectivity and exceptional data transmission rates.
Key Features:
- 100G Ethernet Support:
- The QSFP-100G-PSM4-S supports 100G Ethernet connectivity, enabling fast and efficient data transfer at a rate of 100 gigabits per second. This makes it ideal for high-bandwidth applications like cloud computing, high-performance networking, and large-scale data centers.
- PSM4 Technology:
- The PSM4 (Parallel Single-Mode Fiber) technology allows for efficient transmission over single-mode fiber cables. It enables four parallel lanes, each capable of 25G data rates, which together deliver a total of 100G throughput.
- Distance and Reach:
- This transceiver is optimized for short-distance transmission, providing a reach of up to 500 meters on single-mode fiber (SMF) cables. This makes it perfect for high-speed connections within data centers or enterprise networks where distances between devices are relatively short.
- Low Power Consumption:
- The QSFP-100G-PSM4-S is designed for energy efficiency, consuming less power compared to older transceiver technologies. This helps reduce operating costs and heat generation in high-density networking environments.
- Hot-Pluggable:
- The QSFP-100G-PSM4-S is hot-pluggable, meaning it can be installed or replaced in live network equipment without needing to shut down the system, minimizing downtime and maintaining operational continuity.
- Form Factor:
- The QSFP28 form factor is a compact and widely adopted interface for high-speed transceivers, supporting 100G data rates and offering backward compatibility with earlier generations. It is used in a variety of switches, routers, and servers, enabling high-density interconnects.
- Wavelength and Optical Specifications:
- The QSFP-100G-PSM4-S operates on a wavelength of 1310 nm and uses single-mode fiber for longer transmission distances. Its optical specifications make it highly reliable for long-distance communication in high-speed networks.
- Compatibility:
- The transceiver is compatible with a range of 100G switches, routers, and other networking equipment that support QSFP28 interfaces, ensuring seamless integration into existing infrastructure.
- Quality and Reliability:
- The QSFP-100G-PSM4-S is built to meet industry standards and undergoes rigorous testing for performance, ensuring reliability in mission-critical environments. It delivers consistent, high-speed data transfer, which is crucial for large-scale and high-performance networks.
Ideal Use Cases:
- Data Centers: Perfect for high-speed interconnects between servers, switches, and storage devices in modern data centers, where bandwidth and low-latency communication are critical.
- Cloud Service Providers: Ideal for cloud environments that require high-throughput and low-latency connectivity for large-scale applications.
- High-Performance Computing (HPC): The transceiver’s 100G bandwidth supports compute-intensive applications, making it a suitable option for HPC systems and scientific research networks.
- Enterprise Networks: For large-scale enterprise network infrastructures that demand high-speed data transfer over short distances, such as between different floors or rooms in the same building.
- Telecommunications: Used by service providers for backhaul connections or interconnecting high-density switches and routers.
Conclusion:
The QSFP-100G-PSM4-S is a high-performance, 100G optical transceiver designed for short-distance transmission over single-mode fiber. With its ability to support 100G Ethernet, low power consumption, and easy hot-swapping, it is an excellent choice for data centers, enterprise networks, and high-performance computing environments. Offering 500 meters of reach, it enables high-speed, low-latency data transfer while ensuring compatibility with modern networking equipment. Its reliable performance and efficient design make it an essential component for scaling up network infrastructure and maintaining robust data communications.
