A model for enhancing connection rerouting in mobile networks
Wireless Networks - Special issue: Design and modeling in mobile and wireless systsems
Performance of Active Multicast Congestion Control
IWAN '00 Proceedings of the Second International Working Conference on Active Networks
An Active Layered Multicast Adaptation Protocol
IWAN '00 Proceedings of the Second International Working Conference on Active Networks
ICTAI '99 Proceedings of the 11th IEEE International Conference on Tools with Artificial Intelligence
Model checking active networks with SPIN
Computer Communications
Integration of Reliability and Performance Analyses for Active Network Services
Electronic Notes in Theoretical Computer Science (ENTCS)
Active congestion control using available bandwidth-based congestion detection
ICAI'05/MCBC'05/AMTA'05/MCBE'05 Proceedings of the 6th WSEAS international conference on Automation & information, and 6th WSEAS international conference on mathematics and computers in biology and chemistry, and 6th WSEAS international conference on acoustics and music: theory and applications, and 6th WSEAS international conference on Mathematics and computers in business and economics
Software agents architecture for controlling long-range dependent network traffic
Mathematical and Computer Modelling: An International Journal
Agent-based rate coordination between TCP and ABR congestion control algorithms
Computer Communications
An extension of the ns simulator for active network research
Computer Communications
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Active congestion control (ACC) uses active networking (AN) technology to make feedback congestion control more responsive to network congestion. Current end-to-end feedback congestion control systems detect and relieve congestion only at endpoints. ACC includes programs in each data packet that tell routers how to react to congestion without incurring the round-trip delay that reduces feedback effectiveness in wide area networks. The congested router also sends the new state of the congestion control algorithm to the endpoints to ensure that the distributed state becomes consistent. We present a model for extending feedback congestion control into an active network, apply that model to TCP congestion control, and present simulations that show that the resulting system exhibits up to 18 percent better throughput than TCP under bursty traffic. In simulations without bursty traffic, the systems behaved comparably