Stable protocols for the medium access control in wireless networks
DNCOCO'09 Proceedings of the 8th WSEAS international conference on Data networks, communications, computers
Adaptive call admission control for QoS provisioning in multimedia wireless networks
Computer Communications
Performance evaluation of wireless TCP with rerouting in mobile networks
Computer Communications
Call admission control for wireless personal communications
Computer Communications
An efficiency limit of cellular mobile systems
Computer Communications
Soft handoff in a CDMA wireless ATM environment
Computer Communications
A non-disruptive handoff protocol for wireless ATM networks
Computer Communications
A cell-numbering plan for seamless handoff in a wireless ATM network
Computer Communications
High-speed PVC-based handover control in wireless ATM networks
Computer Communications
Rerouting for handoff based on the distance in wireless ATM networks
Computer Communications
Mobility management and control in intelligent wireless ATM networks
Computer Communications
A novel routing algorithm for WDM-based micro-cellular wireless system
Computer Communications
Combined CAC and forced handoff for mobile network performability
ASMTA'12 Proceedings of the 19th international conference on Analytical and Stochastic Modeling Techniques and Applications
Hi-index | 0.07 |
An architecture is presented for a high-speed cellular radio access network based on ATM transport technology. Central to this approach is a new concept known as the virtual connection tree which avoids the need to involve the network call processor for every cell handoff attempt. Such an approach can readily support a very high rate of handoffs, thereby enabling use of physically small radio cells to provide very high system capacity, but may occasionally cause the volume of traffic to be handled by one cell site to exceed that cell site's capacity. A simple analytical methodology is developed which can be used for admission control, the purpose of which is to limit the number of in-progress calls such that two new quality of service metrics (overload probability and average time in overload) can be kept suitably low. Finally, a general framework is presented for overall system organization and signaling