Please use this identifier to cite or link to this item: https://hdl.handle.net/1783.1/107430
Suppression of self-excited thermoacoustic oscillations using genetic programming
Author |
Yin, Bo
Guan, Yu Redonnet, Stephane Gupta, Vikrant Li, Larry K.B. |
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Issue Date | 2020 |
Abstract | Genetic programming (GP) is a powerful tool for unsupervised data-driven discovery of closed-loop control laws. In fluid mechanics, it has been used for various purposes, such as to enhance mixing in a turbulent shear layer and to delay flow separation. This model-free control framework is well suited for such complex tasks as it exploits an evolutionary mechanism to propagate the genetics of high-performing control laws from one generation to the next. Here we combine automated experiments with GP to discover model-free control laws for the suppression of self-excited thermoacoustic oscillations in a Rijke tube. Using a GP-based controller linked to a single sensor (a microphone) and a single actuator (a loudspeaker), we rank the performance of all the control laws in a given generation based on a cost function that accounts for the pressure amplitude and the actuation effort. We use a tournament process to breed further generations of control laws, and then benchmark them against conventional periodic forcing optimized via open-loop mapping. We find that, with only minimal input from the user, this GP-based control framework can identify new feedback actuation mechanisms, providing improved control laws for the suppression of self-excited thermoacoustic oscillations. |
Conference | 73rd Annual Meeting of the American Physical Society’s Division of Fluid Dynamics (APS/DFD 2020), Chicago, Virtual, 22-24 November 2020 |
Language | English |
Type | Conference paper |