Title :
Graph-Theoretic Analysis and Synthesis of Relative Sensing Networks
Author :
Zelazo, Daniel ; Mesbahi, Mehran
Author_Institution :
Inst. for Syst. Theor. & Autom. Control, Univ. Stuttgart, Stuttgart, Germany
fDate :
5/1/2011 12:00:00 AM
Abstract :
This work provides a general framework for the analysis and synthesis of a class of relative sensing networks (RSNs) in the context of its H2 and H∞ performance. We consider RSNs with homogeneous and heterogeneous agent dynamics. In both cases, explicit graph theoretic expressions and bounds for the H2 and H∞ performance are derived. The H2 performance turns out to be a function of the number of edges in the graph, whereas the H∞ performance is structure dependent and related to the spectral radius of the graph Laplacian. The analysis results are then used to develop synthesis methods for RSNs. An optimal topology is designed using the Kruskal´s Algorithm for H2 performance, and a semi-definite program for the H∞ performance of uncertain RSNs.
Keywords :
H∞ control; graph theory; mathematical programming; mobile robots; multi-robot systems; network theory (graphs); H∞ performance; H2 performance; Kruskal algorithm; graph Laplacian; graph edges; graph theory; heterogeneous agent dynamics; homogeneous agent dynamics; optimal topology; relative sensing network synthesis; semidefinite programming; spectral radius; Controllability; Eigenvalues and eigenfunctions; Laplace equations; Network topology; Observability; Sensors; Topology; ${cal H}_{2}$ and ${cal H}_{infty}$ performance; Combinatorial optimization; graph theory; relative sensing networks; semi-definite programming;
Journal_Title :
Automatic Control, IEEE Transactions on
DOI :
10.1109/TAC.2010.2085312
