Litcius/Paper detail

An Interpretable Nonlinear Decoupling and Calibration Approach to Wheel Force Transducers

Lihang Feng, Sui Wang, Jiantao Shi, Pengwen Xiong, Chuang Chen, Di Xiao, Aiguo Song, Peter Liu

2023IEEE Transactions on Intelligent Transportation Systems13 citationsDOI

Abstract

The multi-dimensional force/torque decoupling and calibration is extremely crucial to increase the accuracy of the Wheel Force Transducer/Sensor (WFT). A novel interpretable nonlinear decoupling and calibration approach to WFT is presented. A physical interpretable prime-error framework is developed such that the linear prime part accounts for most force-voltage responses while the nonlinear error part accounts for the gross error deviation. The conventional least-square decoupling is improved with the delicate nonlinear error modeling using a polynomial base module and a hyperbolic activation function. The developed framework is proved to be mathematically solvable and physically feasible by a two-step calibration scheme. A two-axis WFT is tested and compared with the proposed interpretable nonlinear decoupling model (IND), the least-square-based method (LSM), and the error-based neural network model (eNN). Results demonstrate that the proposed IND provides an accurate, practical, and effective scheme for modeling and calibrating WFTs and maintains a good balance among accuracy, generalization ability, and computational efficiency for real applications.

Topics & Concepts

Decoupling (probability)Nonlinear systemControl theory (sociology)CalibrationMean squared errorComputer scienceVoltageTorqueAlgorithmMathematicsEngineeringArtificial intelligenceControl engineeringPhysicsStatisticsControl (management)Electrical engineeringQuantum mechanicsThermodynamicsSensor Technology and Measurement SystemsMuscle activation and electromyography studiesAdvanced Sensor Technologies Research