Cross-position Activity Recognition with Stratified Transfer Learning
This work addresses a domain-specific challenge in pervasive computing by improving activity recognition accuracy when sensor data from certain body positions is unavailable, though it is incremental as it builds on existing transfer learning methods.
The paper tackles the problem of cross-position human activity recognition when labeled data for a target body position is missing, by proposing a Stratified Transfer Learning framework that selects the most similar source domain and performs accurate knowledge transfer, achieving superior results on three public datasets.
Human activity recognition aims to recognize the activities of daily living by utilizing the sensors on different body parts. However, when the labeled data from a certain body position (i.e. target domain) is missing, how to leverage the data from other positions (i.e. source domain) to help learn the activity labels of this position? When there are several source domains available, it is often difficult to select the most similar source domain to the target domain. With the selected source domain, we need to perform accurate knowledge transfer between domains. Existing methods only learn the global distance between domains while ignoring the local property. In this paper, we propose a \textit{Stratified Transfer Learning} (STL) framework to perform both source domain selection and knowledge transfer. STL is based on our proposed \textit{Stratified} distance to capture the local property of domains. STL consists of two components: Stratified Domain Selection (STL-SDS) can select the most similar source domain to the target domain; Stratified Activity Transfer (STL-SAT) is able to perform accurate knowledge transfer. Extensive experiments on three public activity recognition datasets demonstrate the superiority of STL. Furthermore, we extensively investigate the performance of transfer learning across different degrees of similarities and activity levels between domains. We also discuss the potential applications of STL in other fields of pervasive computing for future research.