The Cisco ESR-8E3DS3-ATM is a high-performance line card expansion module, designed to deliver enhanced functionality and scalability for Cisco networking devices. This module features 8 ports, specifically built to support high-speed E3/DS3 interfaces, offering robust connectivity for demanding network environments such as service provider or enterprise WAN backbones. It connects to Cisco routers, providing additional ATM (Asynchronous Transfer Mode) connectivity capabilities.
Supporting both E3 and DS3 circuits, the ESR-8E3DS3-ATM is an ideal solution for organisations looking to expand their network infrastructure with flexible WAN connectivity options. With a data rate of up to 34 Mbps per port for E3 and 45 Mbps per port for DS3, this line card effectively balances high-speed data transmission over long distances, helping ensure reliable, resilient network performance.
The Cisco ESR-8E3DS3-ATM module supports ATM technology, a core function of many legacy and contemporary high-performance WAN environments. This ensures compatibility with a wide range of related hardware and protocols. Additionally, the module is equipped with advanced features like traffic shaping and fault tolerance, allowing organisations to maintain high-quality service while managing network congestion and outages.
Physically, the ESR-8E3DS3-ATM is designed to fit into standard Cisco equipment chassis, making it a straightforward hardware upgrade for businesses seeking to expand their existing infrastructures. The module allows for easy configuration and quick integration into the network system, making it a practical choice for professionals looking to upgrade or maintain their Cisco network devices in a cost-effective way.
EOL Technology Services provides comprehensive support, professional services, and expert sourcing for parts like the ESR-8E3DS3-ATM. Whether for ongoing operational support, assistance with part replacement, or upgrading your Cisco systems, our team assists in ensuring your network continues running efficiently with minimal disruption.