International Journal of Open Information Technologies

The importance of Magnetometer measurement in all the fields that are related to moving bodies including UAV, they are used for calculation the attitude of moving body, they are also can integrated with other sensors to calculate accurate position moving body. According to that, there is an urgent need to get accurate data from magnetometer, the raw data can be used directly or can be processed by a calibration process. In this article, an assessment of using neural network (NN) in calibration magnetometer is conducted, the NN model is a sequential model that consists of many layers, the dataset contains raw measurements and calibrated data. The model achieved learning accuracy 99.38 % and loss 1.411 ; the loss metric is mean square error. The dataset was split into three parts, train, test and validation. Train and validation parts are used in the training process. The trained model is tested on the test part, on the whole dataset and on noisy dataset by adding some noise on raw data and test the efficiency of NN model. The results showed high efficiency of NN model in calculating calibrated output directly from raw measurements. A structure of NN is also discussed. To validate the proposed method in the field of UAV orientation, heading angle by using magnetometer data is calculated for raw, calibrated, output of proposed method and another calibration method on the same dataset

Bennett, J. S., Vyhnalek, B. E., Greenall, H., Bridge, E. M., Gotardo, F., Forstner, S., ... & Bowen, W. P. (2021). Precision magnetometers for aerospace applications: A review. Sensors, 21(16), 5568.

Kok, M., & Schön, T. B. (2016). Magnetometer calibration using inertial sensors. IEEE Sensors Journal, 16(14), 5679-5689.

Ousaloo, H. S., Sharifi, G. H., Mahdian, J., & Nodeh, M. T. (2017). Complete calibration of three-axis strapdown magnetometer in mounting frame. IEEE Sensors Journal, 17(23), 7886-7893.

Kok, M., Hol, J. D., Schön, T. B., Gustafsson, F., & Luinge, H. (2012, July). Calibration of a magnetometer in combination with inertial sensors. In 2012 15th International Conference on Information Fusion (pp. 787-793). IEEE.

Soken, H. E. (2018). A survey of calibration algorithms for small satellite magnetometers. Measurement, 122, 417-423.

Bader, J., Styp-Rekowski, K., Doehler, L., Becker, S., & Kao, O. (2022, November). Macaw: The machine learning magnetometer calibration workflow. In 2022 IEEE International Conference on Data Mining Workshops (ICDMW) (pp. 1095-1101). IEEE.

Hoang, M. L., & Pietrosanto, A. (2022). Yaw/Heading optimization by Machine learning model based on MEMS magnetometer under harsh conditions. Measurement, 193, 111013.

Gnadt, A. (2022). Machine Learning-Enhanced Magnetic Calibration for Airborne Magnetic Anomaly Navigation. In AIAA SciTech 2022 Forum (p. 1760).

Han, Q., Dou, Z., Tong, X., Peng, X., & Guo, H. (2017). A modified Tolles–Lawson model robust to the errors of the three-axis strapdown magnetometer. IEEE Geoscience and Remote Sensing Letters, 14(3), 334-338.

Abiodun, O. I., Jantan, A., Omolara, A. E., Dada, K. V., Mohamed, N. A., & Arshad, H. (2018). State-of-the-art in artificial neural network applications: A survey. Heliyon, 4(11).

Fraccaro, M., Sønderby, S. K., Paquet, U., & Winther, O. (2016). Sequential neural models with stochastic layers. Advances in neural information processing systems, 29.

Li, H., Zhang, Z., & Liu, Z. (2017). Application of artificial neural networks for catalysis: a review. Catalysts, 7(10), 306.