Brocade - SFP+ transceiver module - 8Gb Fibre Channel (SW), 16Gb Fibre Channel (SW), 32Gb Fibre Channel (SW) - Fibre Channel - up to 623 ft (pack of 8) - for ThinkSystem DB620S, DB630S
- Offers a data transfer rate of 32 Gbps
- Supports multiple data link protocols including 8Gb, 16Gb, and 32Gb
- Designed for distances up to 190 meters
- Plug-in module form factor for easy installation
- Ideal for enhancing network performance in data centers
The Lenovo Brocade 32Gb Fiber Channel SFP+ transceiver module offers high-speed data transfer capabilities, making it an essential component for efficient networking solutions. With a data transfer rate of 32 Gbps, this plug-in module is designed to enhance connectivity performance in fiber channel networks. The short wave technology allows for effective communication over a maximum distance of 190 meters, ensuring reliable data transmission for various applications. This wired transceiver module supports multiple data link protocols including 8Gb, 16Gb, and 32Gb Fiber Channel, providing flexibility for different network architectures. Ideal for modern data centers, the Brocade SFP+ transceiver module streamlines network operations while maintaining robust performance, catering to the needs of businesses demanding consistency and speed in their fiber channel connections.
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Efficient data transfer
Achieves a high-speed data transfer rate of 32 Gbps, ensuring quick communication between devices and reduced latency in data transmission.
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Versatile compatibility
Supports various data link protocols including 8Gb, 16Gb, and 32Gb Fiber Channel, making it suitable for diverse networking configurations.
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Extended range capability
Provides a maximum transfer distance of 190 meters, allowing reliable connectivity even in larger environments.
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Convenient plug-in design
Features a plug-in module form factor for straightforward installation, simplifying upgrades and replacements in networking setups.
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Robust wired connectivity
Utilizes wired connectivity technology to ensure stable and secure connections, minimizing the risk of interference compared to wireless alternatives.
