TY - JOUR
T1 - Online Unsupervised Representation Learning of Waveforms in the Intensive Care Unit via a novel cooperative framework
T2 - 8th Machine Learning for Healthcare Conference, MLHC 2023
AU - Gulamali, Faris
AU - Sawant, Ashwin
AU - Hofer, Ira
AU - Levin, Matthew
AU - Charney, Alexander
AU - Singh, Karandeep
AU - Glicksberg, Benjamin
AU - Nadkarni, Girish
N1 - Publisher Copyright:
© 2023 F. Gulamali, A. Sawant, I. Hofer, M. Levin, A. Charney, K. Singh, B. Glicksberg & G. Nadkarni.
PY - 2023
Y1 - 2023
N2 - Univariate high-frequency time series are dominant data sources for many medical, economic and environmental applications. In many of these domains, the time series are tied to real-time changes in state. In the intensive care unit, for example, changes and intracranial pressure waveforms can indicate whether a patient is developing decreased blood perfusion to the brain during a stroke, for example. However, most representation learning to resolve states is conducted in an offline, batch-dependent manner. In high frequency time-series, high intra-state and inter-sample variability makes offline, batch-dependent learning a relatively difficult task. Hence, we propose Spatial Resolved Temporal Networks (SpaRTeN), a novel composite deep learning model for online, unsupervised representation learning through a spatially constrained latent space. SpaRTeN maps waveforms to states, and learns time-dependent representations of each state. Our key contribution is that we generate clinically relevant representations of each state for intracranial pressure waveforms.
AB - Univariate high-frequency time series are dominant data sources for many medical, economic and environmental applications. In many of these domains, the time series are tied to real-time changes in state. In the intensive care unit, for example, changes and intracranial pressure waveforms can indicate whether a patient is developing decreased blood perfusion to the brain during a stroke, for example. However, most representation learning to resolve states is conducted in an offline, batch-dependent manner. In high frequency time-series, high intra-state and inter-sample variability makes offline, batch-dependent learning a relatively difficult task. Hence, we propose Spatial Resolved Temporal Networks (SpaRTeN), a novel composite deep learning model for online, unsupervised representation learning through a spatially constrained latent space. SpaRTeN maps waveforms to states, and learns time-dependent representations of each state. Our key contribution is that we generate clinically relevant representations of each state for intracranial pressure waveforms.
UR - http://www.scopus.com/inward/record.url?scp=85184279880&partnerID=8YFLogxK
M3 - Conference article
AN - SCOPUS:85184279880
SN - 2640-3498
VL - 219
SP - 230
EP - 247
JO - Proceedings of Machine Learning Research
JF - Proceedings of Machine Learning Research
Y2 - 11 August 2023 through 12 August 2023
ER -