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Main Authors: Amigó, José M., Duran, Guillem, Giménez, Angel, Martínez-Bonastre, Oscar, Valero, José
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.10473
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author Amigó, José M.
Duran, Guillem
Giménez, Angel
Martínez-Bonastre, Oscar
Valero, José
author_facet Amigó, José M.
Duran, Guillem
Giménez, Angel
Martínez-Bonastre, Oscar
Valero, José
contents Adaptive management of traffic congestion in the Internet is a complex problem that can gain useful insights from a dynamical approach. In this paper we propose and analyze a one-dimensional, discrete-time nonlinear model for Internet congestion control at the routers. Specifically, the states correspond to the average queue sizes of the incoming data packets and the dynamical core consists of a monotone or unimodal mapping with a unique fixed point. This model generalizes a previous one in that additional control parameters are introduced via the data packet drop probability with the objective of enhancing stability. To make the analysis more challenging, the original model was shown to exhibit the usual features of low-dimensional chaos with respect to several system and control parameters, e.g., positive Lyapunov exponents and Feigenbaum-like bifurcation diagrams. We concentrate first on the theoretical aspects that may promote the unique stationary state of the system to a global attractor, which in our case amounts to global stability. In a second step, those theoretical results are translated into stability domains for robust setting of the new control parameters in practical applications. Numerical simulations confirm that the new parameters make it possible to extend the stability domains, in comparison with previous results. Therefore, the present work may lead to an adaptive congestion control algorithm with a more stable performance than other algorithms currently in use.
format Preprint
id arxiv_https___arxiv_org_abs_2501_10473
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Generalized TCP-RED dynamical model for Internet congestion control
Amigó, José M.
Duran, Guillem
Giménez, Angel
Martínez-Bonastre, Oscar
Valero, José
Optimization and Control
Dynamical Systems
Adaptive management of traffic congestion in the Internet is a complex problem that can gain useful insights from a dynamical approach. In this paper we propose and analyze a one-dimensional, discrete-time nonlinear model for Internet congestion control at the routers. Specifically, the states correspond to the average queue sizes of the incoming data packets and the dynamical core consists of a monotone or unimodal mapping with a unique fixed point. This model generalizes a previous one in that additional control parameters are introduced via the data packet drop probability with the objective of enhancing stability. To make the analysis more challenging, the original model was shown to exhibit the usual features of low-dimensional chaos with respect to several system and control parameters, e.g., positive Lyapunov exponents and Feigenbaum-like bifurcation diagrams. We concentrate first on the theoretical aspects that may promote the unique stationary state of the system to a global attractor, which in our case amounts to global stability. In a second step, those theoretical results are translated into stability domains for robust setting of the new control parameters in practical applications. Numerical simulations confirm that the new parameters make it possible to extend the stability domains, in comparison with previous results. Therefore, the present work may lead to an adaptive congestion control algorithm with a more stable performance than other algorithms currently in use.
title Generalized TCP-RED dynamical model for Internet congestion control
topic Optimization and Control
Dynamical Systems
url https://arxiv.org/abs/2501.10473