Design, develop, deploy, analyze and support the first citywide Wi-Fi system for Verizon Wireless. Determined frequency reuse cellular model, developed software coverage prediction modules, designed hardware equipment to meet coverage predictions, deployed and remotely managed the hardware, and performed drive testing to fine tune prediction model. Provided help desk support for client installations. The project’s success provided the proof of concept for Verizon Wireless to launch its Wi-Fi Hotspot strategy throughout North America.

Re-deploy a 1300 node AP Systems for student and facility throughout a major university campus. Provided frequency planning; managed the IP allocation subnetting strategy, updated the MIB to improve manageability, provided power over Ethernet and PoE for cost effective deployment, utilized SNMP protocol for configuration, management and support utilizing AAA authentication via Steel Belted Radius to control user access.

A high performance, QoS enabled network was deployed in North America, Europe and Asia for content delivery and Internet bypass. 45 PoPs in North America, 6 in Europe, 3 in Asia with originally in excess of 120 Cisco 12016 routers, 2,000 Sun servers, DWDM Long Haul and Optical and TDM ADMs and switching gear. The Routers were configured with three classes of service to support painted ToS bits and the configurations tuned to allow rapid reroute of traffic in the network.

EBS responded to a RFP from MSN and architected, designed and implemented a 10 city DSL / IP aggregation network that was based on a ATM front end with Redback SMS IP aggregation switches attached to Cisco 650x switches and Cisco 12016 and 12416 Routers. Steel belted Radius servers were setup to proxy the AAA requests and responses to the closets MSN AAA servers. A layer 2 ATM switched network was in front of the SMS 1800 Redbacks to allow a layer 2 switch if the routers or switches went down to allow the IP stream to continue on a hot SMS. Redundant DNS and AAA servers were also deployed.

Designed and implemented an ATM based WAN and LAN to demonstrate bandwidth on demand utilizing Newbridge Networks VIVID architecture and UNI 3.1 signaling for US Army Signal Center and Fort Gordon. An ATM based WAN/LAN was proposed to the US Army to support dynamic bandwidth mission requirements. Heads up, Interactive Full Motion, on demand, Video Teleconferencing, Streaming Video and Ethernet attached server ran across an Army Fore Systems ATM backbone network. The full network was successfully demonstrated at the US Army Signal Symposium in 1996. The on post network ran successfully for several years until it was replaced by GigE switches and Routers.