Performance Improvement in Noisy Linear Consensus Networks with Time-Delay
Abstract
We analyze performance of a class of time-delay first-order consensus networks from a graph topological perspective and present methods to improve it. The performance is measured by network's square of H-2 norm and it is shown that it is a convex function of Laplacian eigenvalues and the coupling weights of the underlying graph of the network. First, we propose a tight convex, but simple, approximation of the performance measure in order to achieve lower complexity in our design problems by eliminating the need for eigen-decomposition. The effect of time-delay reincarnates itself in the form of non-monotonicity, which results in nonintuitive behaviors of the performance as a function of graph topology. Next, we present three methods to improve the performance by growing, re-weighting, or sparsifying the underlying graph of the network. It is shown that our suggested algorithms provide near-optimal solutions with lower complexity with respect to existing methods in literature.
Cite
@article{arxiv.1810.08287,
title = {Performance Improvement in Noisy Linear Consensus Networks with Time-Delay},
author = {Yaser Ghaedsharaf and Milad Siami and Christoforos Somarakis and Nader Motee},
journal= {arXiv preprint arXiv:1810.08287},
year = {2018}
}
Comments
16 pages, 11 figures