Detection of Freezing of Gait Using Unsupervised Convolutional Denoising Autoencoder

At the advanced stage of Parkinson's disease, patients may suffer from 'freezing of gait' episodes: a debilitating condition wherein a patient's feet feel as though they are glued to the floor. The objective, continuous monitoring of the gait of Parkinson's disease patients with wearable devices has led to the development of many freezing of gait detection models involving the automatic cueing of a rhythmic auditory stimulus to shorten or prevent episodes. The use of thresholding and manually extracted features or feature engineering returned promising results. However, these approaches are subjective, time-consuming, and prone to error. Furthermore, their performance varied when faced with the different walking styles of Parkinson's disease patients. Inspired by state-of-art deep learning techniques, this research aims to improve the detection model by proposing a feature learning deep denoising autoencoder to learn the salient characteristics of Parkinsonian gait data that is applicable to different walking styles for the elimination of manually handcrafted features. Even with the elimination of manually handcrafted features, a reduction in half of the data window sizes to 2s, and a significant dimensionality reduction of learned features, the detection model still managed to achieve 90.94% sensitivity and 67.04% specificity, which is comparable to the original Daphnet dataset research.

Automated summary

By applying deep learning techniques to freezing of gait detection, an automated model has been proposed that can effectively identify gait characteristics of different Parkinson's disease patients. Despite reducing manually crafted features and data window sizes, the detection model still achieved excellent performance.