Multi-Task Temporal Shift Attention Networks for On-Device Contactless Vitals Measurement
- Xin Liu ,
- Josh Fromm ,
- Shwetak Patel ,
- Daniel McDuff
Neural Information Processing Systems (NeurIPS) |
Telehealth and remote health monitoring have become increasingly important during the SARS-CoV-2 pandemic and it is widely expected that this will have a lasting impact on healthcare practices. These tools can help reduce the risk of exposing patients and medical staff to infection, make healthcare services more accessible, and allow providers to see more patients. However, objective measurement of vital signs is challenging without direct contact with a patient. We present a video-based and on-device optical cardiopulmonary vital sign measurement approach. It leverages a novel multi-task temporal shift convolutional attention network (MTTS-CAN) and enables real-time cardiovascular and respiratory measurements on mobile platforms. We evaluate our system on an ARM CPU and achieve state-of-the-art accuracy while running at over 150 frames per second which enables real-time applications. Systematic experimentation on large benchmark datasets reveals that our approach leads to substantial (20%-50%) reductions in error and generalizes well across datasets.
Téléchargements de publications
MTTS-CAN
décembre 2, 2020
Accompanies the paper Multi-Task Temporal Shift Attention Networks for On-Device Contactless Vitals Measurement (NeurIPS 2020)
Camera-based non-contact health sensing webinar
The SARS-CoV-2 (COVID-19) pandemic is transforming the face of healthcare around the world. One example of this transformation can be seen in the number of medical appointments held via teleconference, which has increased by more than an order of magnitude because of stay-at-home orders and greater burdens on healthcare systems. Experts suggest that particular attention should be given to cardiovascular and pulmonary protection during treatment for COVID-19. However, in most telehealth scenarios physicians lack access to objective measurements of a patient’s condition because of the inability to capture vital signs. In this webinar, Microsoft Principal Researcher Daniel McDuff and University of Washington PhD student Xin Liu will present an overview of computer vision methods that leverage ordinary webcams to measure physiological signals (for example, peripheral…