TY - JOUR
T1 - Identification of hessian matrix in distributed gradient-based multi-agent coordination control systems
AU - Sun, Zhiyong
AU - Sugie, Toshiharu
N1 - Publisher Copyright:
© 2019, American Institute of Mathematical Sciences. All rights reserved.
PY - 2019/9
Y1 - 2019/9
N2 - Multi-agent coordination control usually involves a potential function that encodes information of a global control task, while the control input for individual agents is often designed by a gradient-based control law. The property of Hessian matrix associated with a potential function plays an important role in the stability analysis of equilibrium points in gradient-based coordination control systems. Therefore, the identification of Hessian matrix in gradient-based multi-agent coordination systems becomes a key step in multi-agent equilibrium analysis. However, very often the identification of Hessian matrix via the entry-wise calculation is a very tedious task and can easily introduce calculation errors. In this paper we present some general and fast approaches for the identification of Hessian matrix based on matrix differentials and calculus rules, which can easily derive a compact form of Hessian matrix for multi-agent coordination systems. We also present several examples on Hessian identification for certain typical potential functions involving edge-tension distance functions and triangular-area functions, and illustrate their applications in the context of distributed coordination and formation control.
AB - Multi-agent coordination control usually involves a potential function that encodes information of a global control task, while the control input for individual agents is often designed by a gradient-based control law. The property of Hessian matrix associated with a potential function plays an important role in the stability analysis of equilibrium points in gradient-based coordination control systems. Therefore, the identification of Hessian matrix in gradient-based multi-agent coordination systems becomes a key step in multi-agent equilibrium analysis. However, very often the identification of Hessian matrix via the entry-wise calculation is a very tedious task and can easily introduce calculation errors. In this paper we present some general and fast approaches for the identification of Hessian matrix based on matrix differentials and calculus rules, which can easily derive a compact form of Hessian matrix for multi-agent coordination systems. We also present several examples on Hessian identification for certain typical potential functions involving edge-tension distance functions and triangular-area functions, and illustrate their applications in the context of distributed coordination and formation control.
KW - Gradient-based control
KW - Hessian matrix
KW - Multi-agent coordination
UR - http://www.scopus.com/inward/record.url?scp=85079058862&partnerID=8YFLogxK
U2 - 10.3934/naco.2019020
DO - 10.3934/naco.2019020
M3 - Article
SN - 2155-3289
VL - 9
SP - 297
EP - 318
JO - Numerical Algebra, Control and Optimization
JF - Numerical Algebra, Control and Optimization
IS - 3
ER -