Your search keyword '"Liu, Jason"' showing total 3 results

1. Further Improvements on Non-Negative Edge Consensus of Networked Systems.

Author

Liu, Jason J. R., Lam, James, and Kwok, Ka-Wai

Abstract

In this article, the non-negative edge consensus problem is addressed for positive networked systems with undirected graphs using state-feedback protocols. In contrast to existing results, the major contributions of this work included: 1) significantly improved criteria of consequentiality and non-negativity, therefore leading to a linear programming approach and 2) necessary and sufficient criteria giving rise to a semidefinite programming approach. Specifically, an improved upper bound is given for the maximum eigenvalue of the Laplacian matrix and the (out-) in-degree of the degree matrix, and an improved consensuability and non-negativevity condition is obtained. The sufficient condition presented only requires the number of edges of a nodal network without the connection topology. Also, with the introduction of slack matrix variables, two equivalent conditions of consensuability and non-negativevity are obtained. In the conditions, the system matrices, controller gain, as well as Lyapunov matrices are separated, which is helpful for parameterization. Based on the results, a semidefinite programming algorithm for the controller is readily developed. Finally, a comprehensive analytical and numerical comparison of three illustrative examples is conducted to show that the proposed results are less conservative than the existing work. [ABSTRACT FROM AUTHOR]

Published

2022

2. Nonnegative Consensus Tracking of Networked Systems With Convergence Rate Optimization.

Author

Liu, Jason J. R., Lam, James, Zhu, Bohao, Wang, Xiaomei, Shu, Zhan, and Kwok, Ka-Wai

Subjects

*POSITIVE systems, *SYSTEMS theory, *SEMIDEFINITE programming, *DISTRIBUTED algorithms, *DYNAMICAL systems, *ARTIFICIAL satellite tracking, *GRAPH connectivity

Abstract

This article investigates the nonnegative consensus tracking problem for networked systems with a distributed static output-feedback (SOF) control protocol. The distributed SOF controller design for networked systems presents a more challenging issue compared with the distributed state-feedback controller design. The agents are described by multi-input multi-output (MIMO) positive dynamic systems which may contain uncertain parameters, and the interconnection among the followers is modeled using an undirected connected communication graph. By employing positive systems theory, a series of necessary and sufficient conditions governing the consensus of the nominal, as well as uncertain, networked positive systems, is developed. Semidefinite programming consensus design approaches are proposed for the convergence rate optimization of MIMO agents. In addition, by exploiting the positivity characteristic of the systems, a linear-programming-based design approach is also proposed for the convergence rate optimization of single-input multi-output (SIMO) agents. The proposed approaches and the corresponding theoretical results are validated by case studies. [ABSTRACT FROM AUTHOR]

Published

2022

3. Consensus of Positive Networked Systems on Directed Graphs.

Author

Liu, Jason J. R., Kwok, Ka-Wai, Cui, Yukang, Shen, Jun, and Lam, James

Subjects

*DIRECTED graphs, *POSITIVE systems, *GRAPH theory, *LAPLACIAN matrices, *SYSTEMS theory, *LINEAR control systems

Abstract

This article addresses the distributed consensus problem for identical continuous-time positive linear systems with state-feedback control. Existing works of such a problem mainly focus on the case where the networked communication topologies are of either undirected and incomplete graphs or strongly connected directed graphs. On the other hand, in this work, the communication topologies of the networked system are described by directed graphs each containing a spanning tree, which is a more general and new scenario due to the interplay between the eigenvalues of the Laplacian matrix and the controller gains. Specifically, the problem involves complex eigenvalues, the Hurwitzness of complex matrices, and positivity constraints, which make analysis difficult in the Laplacian matrix. First, a necessary and sufficient condition for the consensus analysis of directed networked systems with positivity constraints is given, by using positive systems theory and graph theory. Unlike the general Riccati design methods that involve solving an algebraic Riccati equation (ARE), a condition represented by an algebraic Riccati inequality (ARI) is obtained for the existence of a solution. Subsequently, an equivalent condition, which corresponds to the consensus design condition, is derived, and a semidefinite programming algorithm is developed. It is shown that, when a protocol is solved by the algorithm for the networked system on a specific communication graph, there exists a set of graphs such that the positive consensus problem can be solved as well. [ABSTRACT FROM AUTHOR]

Published

2022