TY - GEN
T1 - Experimental force reconstruction using a neural network and simulated training data
AU - Dare, Tyler
N1 - Publisher Copyright:
© Proceedings of 2020 International Congress on Noise Control Engineering, INTER-NOISE 2020. All rights reserved.
PY - 2020/8/23
Y1 - 2020/8/23
N2 - Force reconstruction is the determination of unknown applied forces using operational vibration information. This inverse problem is made more difficult by limiting the number of operational sensors and increasing the number of modes excited in a given frequency range. Artificial neural networks have been generated to do a wide variety of tasks in vibrations, including inverse problems. However, the amount of training data required is usually too much for a single experiment to generate. In this research, a neural network was generated to estimate the location of a hammer impact on a plate using accelerometer data. Instead of experimental data, however, the network was trained on a finite element model of the structure. To account for variations between the model and reality, the training data was generated with a range of physical properties, such as material stiffness and damping. The resulting model was able to identify the location of a hammer impact to within approximately 12% of the size of the plate.
AB - Force reconstruction is the determination of unknown applied forces using operational vibration information. This inverse problem is made more difficult by limiting the number of operational sensors and increasing the number of modes excited in a given frequency range. Artificial neural networks have been generated to do a wide variety of tasks in vibrations, including inverse problems. However, the amount of training data required is usually too much for a single experiment to generate. In this research, a neural network was generated to estimate the location of a hammer impact on a plate using accelerometer data. Instead of experimental data, however, the network was trained on a finite element model of the structure. To account for variations between the model and reality, the training data was generated with a range of physical properties, such as material stiffness and damping. The resulting model was able to identify the location of a hammer impact to within approximately 12% of the size of the plate.
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M3 - Conference contribution
AN - SCOPUS:85101400472
T3 - Proceedings of 2020 International Congress on Noise Control Engineering, INTER-NOISE 2020
BT - Proceedings of 2020 International Congress on Noise Control Engineering, INTER-NOISE 2020
A2 - Jeon, Jin Yong
PB - Korean Society of Noise and Vibration Engineering
T2 - 49th International Congress and Exposition on Noise Control Engineering, INTER-NOISE 2020
Y2 - 23 August 2020 through 26 August 2020
ER -