Consensus Control of Multiagent Systems Subject to Biasing Faults: Relative Output Information-Based Approach

In this article, relative output information is applied to tackle the consensus control problem of linear multiagent systems (MASs) under biasing faults and uncertainty in the parameters. An auxiliary system is first introduced to reconstruct the fault signal, and a class of observers is proposed to simultaneously estimate the current states and faults of the augmented MASs. According to the estimated information, distributed H∞ and H2 consensus controllers are proposed, respectively, within this design framework. By utilizing the consensus region-based analysis technique, some sufficient criteria are derived to achieve H∞ and H2 consensus, respectively, when a piece of spectrum information of the Laplacian matrix related to communication topology is involved. The Laplacian matrix's spectrum can be fully decoupled from the observer and controller design process in the case of only actuator faults. Compared with the existing methods, the proposed algorithms almost exclusively depend on the relative output information with little global information of the graph, thereby making the solution more scalable and applicable to practical situations. Numerical simulations ultimately demonstrate the validity of the proposed results. © 2024 IEEE.