DYNIMP: DYNAMIC IMPUTATION FOR WEARABLE SENSING DATA THROUGH SENSORY AND TEMPORAL RELATEDNESS
Zepeng Huo, Taowei Ji, Yifei Liang, Xiaoning Qian, Bobak Mortazavi, Shuai Huang, Zhangyang Wang
-
SPS
IEEE Members: $11.00
Non-members: $15.00Length: 00:06:01
In wearable sensing applications, data is inevitable to be irregularly sampled or partially missing, which pose challenges for any downstream application. A unique aspect of wearable data is that it is time-series data and each channel can be correlated to another one, such as x, y, z axis of accelerometer. We argue that traditional methods have rarely made use of both times-series dynamics of the data as well as the relatedness of the features from different sensors. We propose a model, termed as DynImp, to handle different time point's missingness with nearest neighbors along feature axis and then feeding the data into a LSTM-based denoising autoencoder which can reconstruct missingness along the time axis. We experiment the model on the extreme missingness scenario (>50% missing rate) which has not been widely tested in wearable data. Our experiments on activity recognition show that the method can exploit the multi-modality features from related sensors and also learn from history time-series dynamics to reconstruct the data under extreme missingness.