Sparse Sensor Placement Optimization for Prediction of Angle of Attack with Artificial Hair-Cell Airflow Microsensors
Document Type
Conference Proceeding
Publication Date
1-4-2024
Abstract
Arrays of bioinspired artificial hair-cell airflow velocity sensors can enable flight-by-feel of small, unmanned aircraft. Natural fliers - bats, insects, and birds - have hundred or thousands of velocity sensors distributed across their wings. Aircraft designers do not have this luxury due to size, weight, and power constraints. The challenge is to identify the best locations for a small set of sensors to extract relevant information from the flow field for the prediction of flight control parameters. In this paper, we introduce the data-reducing Sparse Sensor Placement Optimization for Prediction algorithm which locates near-optimal sensor placement on airfoils and wings. For two or more sensors this algorithm finds a set of sensor locations (design point) which predicts angle of attack to within 0.10 degrees and ranks within the top 1 percent of all possible design points found by brute force search. We demonstrate this algorithm on several variations of airfoil sections of infinite and finite wings in clean and noisy data, evaluate model sensitivities, and show that the algorithm can be used to identify an appropriate number of sensors for a given accuracy requirement. Applications for this algorithm are explored for aircraft design and flight-by-feel control.
Source Publication
AIAA SCITEC 2024 Forum
Recommended Citation
Hollenbeck, A., Grandhi, R. V., Hansen, J., and Pankonien, A. M., “Sparse Sensor Placement Optimization for Prediction of Angle of Attack with Artificial Hair-Cell Airflow Microsensors,” presented at the AIAA SCITECH 2024 Forum, Orlando, FL, 2024. https://doi.org/10.2514/6.2024-1798
Comments
This conference paper is available by purchase or subscription from AIAA through the DOI link below.
Conference session: Emerging Methods, Algorithms, and Software Development in MDO I
AIAA Paper # 2024-1798