TY - GEN
T1 - Comparative Bioinspired Optimization for Delay-Compensated SMC in Dominant Dead-Time Systems
AU - Herrera, Marco
AU - Aguirre, Omar
AU - Benítez, Diego S.
AU - Pérez-Pérez, Noel
AU - Camacho, Oscar
AU - Prado, Alvaro
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - This work aims to develop and evaluate a tuning methodology for a Smith Predictor-based Sliding Mode Controller (SMC) optimized with five bioinspired algorithms to improve robustness and performance in time-delay systems under uncertainty. The central hypothesis is that combining the predictive capabilities of the Smith Predictor with the robustness of SMC and the optimization power of bioinspired algorithms can produce a controller that maintains high performance. Experimental tests on the TCLab platform, which add significant delays, confirm this. The results show that the proposed strategy effectively manages reference changes, outperforming traditional tuning methods. The main contributions include integrating intelligent optimization with robust predictive control and validating the methodology in a real-time delayed process.
AB - This work aims to develop and evaluate a tuning methodology for a Smith Predictor-based Sliding Mode Controller (SMC) optimized with five bioinspired algorithms to improve robustness and performance in time-delay systems under uncertainty. The central hypothesis is that combining the predictive capabilities of the Smith Predictor with the robustness of SMC and the optimization power of bioinspired algorithms can produce a controller that maintains high performance. Experimental tests on the TCLab platform, which add significant delays, confirm this. The results show that the proposed strategy effectively manages reference changes, outperforming traditional tuning methods. The main contributions include integrating intelligent optimization with robust predictive control and validating the methodology in a real-time delayed process.
KW - Bioinspired optimization
KW - Sliding Mode Control
KW - Smith Predictor
KW - Thermal process control
UR - https://www.scopus.com/pages/publications/105033322590
U2 - 10.1109/C366505.2025.11340465
DO - 10.1109/C366505.2025.11340465
M3 - Contribución a la conferencia
AN - SCOPUS:105033322590
T3 - C3 2025 - IEEE Colombian Caribbean Conference
BT - C3 2025 - IEEE Colombian Caribbean Conference
A2 - Gomez, Yesica Beltran
A2 - Mendoza, Paul Sanmartin
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2025 IEEE Colombian Caribbean Conference, C3 2025
Y2 - 17 September 2025 through 20 September 2025
ER -