Safe Checkout
Secure Payments
Fast Delivery
Order Today
Free Shipping
Across the US
Easy Returns
Hassle-Free
Brocade XBR-000081 1Gb/s SFP 550m 850nm Duplex LC MMF Transceiver
- Form Factor: SFP (Small Form-Factor Pluggable)
- Data Rate: 1Gb/s
- Wavelength: 850nm
- Maximum Distance: 550m
- Fiber Type: Multi-Mode Fiber (MMF)
- Connector Type: Duplex LC
- Hot-swappable
Click on Inquire to get latest price
Free U.S. Ground Shipping
Typically 1-2 handling + 3-7 transit days
Purchase orders accepted
For government, enterprise, data center, and small business customers.
Bulk Purchase Inquiry
Volume pricing and availability
Product Overview
The Brocade XBR-000081 is a 1Gb/s SFP transceiver designed for multi-mode fiber networks. It supports distances up to 550 meters at a wavelength of 850nm, featuring a duplex LC connector.
Technical Information
| Data Rate | 1 Gb/s |
| Form Factor | SFP |
| Wavelength | 850nm |
Additional Specifications
| Max Distance | 550m |
| Fiber Type | Multi-Mode Fiber |
| Connector | LC Duplex |
Product Description
The Brocade XBR-000081 is a high-quality SFP (Small Form-Factor Pluggable) transceiver module engineered for 1 Gigabit Ethernet applications over multi-mode fiber. It is specifically designed to operate at a wavelength of 850nm, which is the standard for short-reach optical communication over MMF. This transceiver supports data transmission up to 550 meters, making it an excellent choice for connecting network devices within a data center, building, or across a local campus. It utilizes a duplex LC connector, providing a secure and reliable physical interface for the fiber optic cable. The SFP form factor ensures compatibility with a wide array of switches, routers, and network interface cards that support this standard. As a hot-swappable module, the XBR-000081 can be installed or removed from network equipment without the need to power down the device, facilitating easier network maintenance and upgrades. Brocade's commitment to quality ensures that this transceiver delivers consistent performance and reliability for demanding network environments.
