TY - GEN
T1 - Successive Convexification for Optimal Control with Signal Temporal Logic Specifications
AU - Mao, Yuanqi
AU - Acikmese, Behcet
AU - Garoche, Pierre Loic
AU - Chapoutot, Alexandre
N1 - Publisher Copyright:
© 2022 ACM.
PY - 2022/5/4
Y1 - 2022/5/4
N2 - As the scope and complexity of modern cyber-physical systems increase, newer and more challenging mission requirements will be imposed on the optimal control of the underlying unmanned systems. This paper proposes a solution to handle complex temporal requirements formalized in Signal Temporal Logic (STL) specifications within the Successive Convexification (SCvx) algorithmic framework. This SCvx-STL solution method consists of four steps: 1) Express the STL specifications using their robust semantics as state constraints. 2) Introduce new auxiliary state variables to transform these state constraints as system dynamics, by exploiting the recursively defined structure of robust STL semantics. 3) Smooth the resulting system dynamics with polynomial smooth min- and max- functions. 4) Convexify and solve the resulting optimal control problem with the SCvx algorithm, which enjoys guaranteed convergence and polynomial time subproblem solving capability. Our approach retains the expressiveness of encoding mission requirements with STL semantics, while avoiding the usage of combinatorial optimization techniques such as Mixed-integer programming. Numerical results are shown to demonstrate its effectiveness.
AB - As the scope and complexity of modern cyber-physical systems increase, newer and more challenging mission requirements will be imposed on the optimal control of the underlying unmanned systems. This paper proposes a solution to handle complex temporal requirements formalized in Signal Temporal Logic (STL) specifications within the Successive Convexification (SCvx) algorithmic framework. This SCvx-STL solution method consists of four steps: 1) Express the STL specifications using their robust semantics as state constraints. 2) Introduce new auxiliary state variables to transform these state constraints as system dynamics, by exploiting the recursively defined structure of robust STL semantics. 3) Smooth the resulting system dynamics with polynomial smooth min- and max- functions. 4) Convexify and solve the resulting optimal control problem with the SCvx algorithm, which enjoys guaranteed convergence and polynomial time subproblem solving capability. Our approach retains the expressiveness of encoding mission requirements with STL semantics, while avoiding the usage of combinatorial optimization techniques such as Mixed-integer programming. Numerical results are shown to demonstrate its effectiveness.
KW - optimal control
KW - robust semantics
KW - signal temporal logic
KW - successive convexification
U2 - 10.1145/3501710.3519518
DO - 10.1145/3501710.3519518
M3 - Conference contribution
AN - SCOPUS:85130801897
T3 - HSCC 2022 - Proceedings of the 25th ACM International Conference on Hybrid Systems: Computation and Control, Part of CPS-IoT Week 2022
BT - HSCC 2022 - Proceedings of the 25th ACM International Conference on Hybrid Systems
PB - Association for Computing Machinery, Inc
T2 - 25th ACM International Conference on Hybrid Systems: Computation and Control, HSCC 2022, held as part of the 15th Cyber Physical Systems and Internet-of-Things Week, CPS-IoT Week 2022
Y2 - 4 May 2022 through 6 May 2022
ER -