Approximate Gradient Descent Convergence Dynamics for Adaptive Control on Heterogeneous Networks

Authors

  • Jean Carpentier Ecole Polytechnique
  • Sebastien Blandin IBM Research

DOI:

https://doi.org/10.1609/icaps.v29i1.3461

Abstract

Adaptive control is a classical control method for complex cyber-physical systems, including transportation networks. In this work, we analyze the convergence properties of such methods on exemplar graphs, both theoretically and numerically. We first illustrate a limitation of the standard backpressure algorithm for scheduling optimization, and prove that a re-scaling of the model state can lead to an improvement in the overall system optimality by a factor of at most O(k) depending on the network parameters, where k characterizes the network heterogeneity. We exhaustively describe the associated transient and steady-state regimes, and derive convergence properties within this generalized class of backpressure algorithms. Extensive simulations are conducted on both a synthetic network and on a more realistic large-scale network modeled on the Manhattan grid on which theoretical results are verified.

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Published

2019-07-05

How to Cite

Carpentier, J., & Blandin, S. (2019). Approximate Gradient Descent Convergence Dynamics for Adaptive Control on Heterogeneous Networks. Proceedings of the International Conference on Automated Planning and Scheduling, 29(1), 68-76. https://doi.org/10.1609/icaps.v29i1.3461