A neural network-based model for lower limb continuous estimation against the disturbance of uncertainty*

In this paper, a novel prediction model is proposed to estimate human continuous motion intention using a fuzzy wavelet neural network (FWNN) and a zeroing neural network (ZNN). During walking, seven channel surface electromyography (sEMG) signals and motion data of hip and knee are collected, and two signals are selected and processed from the seven muscles based on physiological and correlation analysis. Then, FWNN is built as an intention recognition model, with sEMG signals as input and physical hip and knee information as output. Meanwhile, ZNN is exploited into the FWNN model, forming a hybrid model to eliminate the prediction errors of the FWNN model. Finally, comparative numerical simulations are established to indicate the validity of the FWNN-ZNN model with root mean square error (RMSE), mean absolute error (MAE) and coefficient of determination (R2) as evaluation indexes. Results show that the proposed FWNN-ZNN model can more accurately estimate human motion intention, which lays the theoretical foundation for the human-robot interaction of rehabilitation robots.

Automated summary

This paper proposes a novel prediction model to estimate human continuous motion intention using FWNN and ZNN, and demonstrates its effectiveness through comparative numerical simulations. The results show that the FWNN-ZNN model can more accurately estimate human motion intention.