A vehicle cloud control system considering communication quantization and stochastic delay. (English) Zbl 07892403
Summary: A novel kind of networked feedback controller is designed for the vehicle cloud control system in the presence of both sensor-controller/controller-actuator delay and communication quantization. Firstly, the vehicle cloud control system with delayed and quantized communication is modeled using the lateral/longitudinal vehicle dynamic and Markovian jump linear system (MJLS) theory. Then, some efficient stabilization conditions in matrix inequalities forms are derived for the considered cloud-controlled vehicles. Furthermore, a cone complementary linearization method is utilized to solve the nonlinear matrix inequalities involved in the stabilization conditions. Simulation tests on connected vehicle lateral and longitudinal control are conducted to verify the effectiveness of the analytical results. Compared with the commonly used constant-parameter controllers, the proposed method is practical to design vehicle cloud controllers under stochastic delay and communication quantization scenarios, with known delay distribution. Lastly, the stability of the vehicle cloud control system is guaranteed under the infection of unreliable communication factors with the proposed control method.
© 2023 Chinese Automatic Control Society and John Wiley & Sons Australia, Ltd.
© 2023 Chinese Automatic Control Society and John Wiley & Sons Australia, Ltd.
MSC:
| 93-XX | Systems theory; control |
Keywords:
Markovian jump linear system; networked control of connected vehicles; stochastic delay; switching controlReferences:
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