TY - GEN
T1 - How Much Reserve Fuel
T2 - 63rd IEEE Conference on Decision and Control, CDC 2024
AU - Padmanabhan, Ram
AU - Bakker, Craig
AU - Dinkar, Siddharth Abhijit
AU - Ornik, Melkior
N1 - This work was supported by the Resilience through Data-driven Intelligently-Designed Control (RD2C) Initiative under the Laboratory Directed Research and Development (LDRD) Program at Pacific Northwest National Laboratory (PNNL), Air Force Office of Scientific Research grant FA9550-23-1-0131 and NASA University Leadership Initiative grant 80NSSC22M0070. The authors thank Elena Fernandez Bravo for useful comments and discussion.
PY - 2024
Y1 - 2024
N2 - Motivated by the design question of additional fuel needed to complete a task in an uncertain environment, this paper introduces metrics to quantify the maximal additional energy used by a control system in the presence of bounded disturbances when compared to a nominal, disturbance-free system. In particular, we consider the task of finite-time stabilization for a linear time-invariant system. We first derive the nominal energy required to achieve this task in a disturbance-free system, and then the worst-case energy over all feasible disturbances. The latter leads to an optimal control problem with a least-squares solution, and then an infinited-imensional optimization problem where we derive an upper bound on the solution. The comparison of these energies is accomplished using additive and multiplicative metrics, and we derive analytical bounds on these metrics. Simulation examples on an ADMIRE fighter jet model demonstrate the practicability of these metrics, and their variation with the task hardness, a combination of the distance of the initial condition from the origin and the task completion time.
AB - Motivated by the design question of additional fuel needed to complete a task in an uncertain environment, this paper introduces metrics to quantify the maximal additional energy used by a control system in the presence of bounded disturbances when compared to a nominal, disturbance-free system. In particular, we consider the task of finite-time stabilization for a linear time-invariant system. We first derive the nominal energy required to achieve this task in a disturbance-free system, and then the worst-case energy over all feasible disturbances. The latter leads to an optimal control problem with a least-squares solution, and then an infinited-imensional optimization problem where we derive an upper bound on the solution. The comparison of these energies is accomplished using additive and multiplicative metrics, and we derive analytical bounds on these metrics. Simulation examples on an ADMIRE fighter jet model demonstrate the practicability of these metrics, and their variation with the task hardness, a combination of the distance of the initial condition from the origin and the task completion time.
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U2 - 10.1109/CDC56724.2024.10886030
DO - 10.1109/CDC56724.2024.10886030
M3 - Conference contribution
AN - SCOPUS:86000598971
T3 - Proceedings of the IEEE Conference on Decision and Control
SP - 5326
EP - 5331
BT - 2024 IEEE 63rd Conference on Decision and Control, CDC 2024
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 16 December 2024 through 19 December 2024
ER -