TY - GEN
T1 - Stabilization of hyperbolic reaction-diffusion systems on directed networks through the generalized Routh-Hurwitz criterion for complex polynomials
AU - Muolo, Riccardo
AU - HASTIR, Anthony
AU - Nakao, Hiroya
N1 - Publisher Copyright:
© 2024 The Society of Instrument and Control Engineers.
PY - 2024/4
Y1 - 2024/4
N2 - The study of dynamical systems on complex networks is of paramount importance in engineering, given that many natural and artificial systems find a natural embedding on discrete topologies. For instance, power grids, chemical reactors and the brain, to name a few, can be modeled through the network formalism by considering elementary units coupled via the links. In recent years, scholars have developed numerical and theoretical tools to study the stability of those coupled systems when subjected to perturbations. In such framework, it was found that asymmetric couplings enhance the possibilities for such systems to become unstable. Moreover, in this scenario the polynomials whose stability needs to be studied bear complex coefficients, which makes the analysis more difficult. In this work, we put to use a recent extension of the well-known Routh-Hurwitz stability criterion, allowing to treat the complex coefficient case. Then, using the Brusselator model as a case study, we discuss the stability conditions and the regions of parameters when the networked system remains stable.
AB - The study of dynamical systems on complex networks is of paramount importance in engineering, given that many natural and artificial systems find a natural embedding on discrete topologies. For instance, power grids, chemical reactors and the brain, to name a few, can be modeled through the network formalism by considering elementary units coupled via the links. In recent years, scholars have developed numerical and theoretical tools to study the stability of those coupled systems when subjected to perturbations. In such framework, it was found that asymmetric couplings enhance the possibilities for such systems to become unstable. Moreover, in this scenario the polynomials whose stability needs to be studied bear complex coefficients, which makes the analysis more difficult. In this work, we put to use a recent extension of the well-known Routh-Hurwitz stability criterion, allowing to treat the complex coefficient case. Then, using the Brusselator model as a case study, we discuss the stability conditions and the regions of parameters when the networked system remains stable.
KW - Network systems
KW - Generalized Routh-Hurwitz criterion
KW - complew polynomials
KW - Hyperbolic reaction-diffusion systems
KW - Networked systems
KW - generalized Routh-Hurwitz criterion
KW - hyperbolic reaction-diffusion systems
KW - complex polynomials
UR - http://www.scopus.com/inward/record.url?scp=85192238416&partnerID=8YFLogxK
U2 - 10.23919/SICEISCS60954.2024.10505754
DO - 10.23919/SICEISCS60954.2024.10505754
M3 - Conference contribution
T3 - 2024 SICE International Symposium on Control Systems, SICE ISCS 2024
SP - 73
EP - 79
BT - 2024 SICE International Symposium on Control Systems, SICE ISCS 2024
ER -