Abstract
This paper proposes a real-time trajectory prediction method for quadrotors based on a bidirectional gated recurrent unit model. Historical trajectory data of ten types of quadrotors were obtained. The bidirectional gated recurrent units were constructed and utilized to learn the historic data. The prediction results were compared with the traditional gated recurrent unit method to test its prediction performance. The efficiency of the proposed algorithm was investigated by comparing the training loss and training time. The results over the testing datasets showed that the proposed model produced better prediction results than the baseline models for all scenarios of the testing datasets. It was also found that the proposed model can converge to a stable state faster than the traditional gated recurrent unit model. Moreover, various types of training samples were applied and compared. With the same randomly selected test datasets, the performance of the prediction model can be improved by selecting the historical trajectory samples of the quadrotors close to the weight or volume of the target quadrotor for training. In addition, the performance of stable trajectory samples is significantly better than that with unstable trajectory segments with a frequent change of speed and direction with large angles.
Highlights
In the recent years, unmanned quadrotors are being widely used in various fields due to its small size, easy manipulation, low cost and high flexibility
Sensors 2020, 20, 7061 (a) propose a real-time trajectory prediction method for small-size quadrotors based on machining learning techniques; (b) test the performance of the proposed method based on the selection of various training samples; and (c) identify the impact of the frequent change of speed and direction with large angles in prediction accuracy
This paper proposed a real-time trajectory prediction algorithm for quadrotors based on D-gated recurrent unit (GRU)
Summary
In the recent years, unmanned quadrotors are being widely used in various fields due to its small size, easy manipulation, low cost and high flexibility. As compared with large-scale UAVs, the movement patterns of small-size quadrotors are quite different in terms of the frequent direction change and hovering behaviors, which are more difficult to capture. To this end, this paper aims to: Sensors 2020, 20, 7061; doi:10.3390/s20247061 www.mdpi.com/journal/sensors (a) propose a real-time trajectory prediction method for small-size quadrotors based on machining learning techniques; (b) test the performance of the proposed method based on the selection of various training samples; and (c) identify the impact of the frequent change of speed and direction with large angles in prediction accuracy
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