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Human Motion Prediction Using Adaptable Recurrent Neural Networks and Inverse Kinematics

Ruixuan Liu, Changliu Liu

2020IEEE Control Systems Letters47 citationsDOI

Abstract

Human motion prediction, especially arm prediction, is critical to facilitate safe and efficient human-robot collaboration (HRC). This letter proposes a novel human motion prediction framework that combines a recurrent neural network (RNN) and inverse kinematics (IK) to predict human arm motion. A modified Kalman filter (MKF) is applied to adapt the model online. The proposed framework is tested on collected human motion data with up to 2 s prediction horizon. The experiments demonstrate that the proposed method improves the prediction accuracy by approximately 14% comparing to the state-of-art on seen situations. It stably adapts to unseen situations by keeping the maximum prediction error under 4 cm, which is 70% lower than other methods. Moreover, it is robust when the arm is partially occluded. The wrist prediction remains the same, while the elbow prediction has 20% less variation.

Topics & Concepts

Inverse kinematicsKinematicsComputer scienceArtificial intelligenceMotion (physics)Artificial neural networkRecurrent neural networkKalman filterComputer visionRobotControl theory (sociology)Control (management)Classical mechanicsPhysicsHuman Pose and Action RecognitionHuman Motion and AnimationSports Performance and Training
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