Transformer-Based Behavioral Representation Learning Enables Transfer
Learning for Mobile Sensing in Small Datasets
- URL: http://arxiv.org/abs/2107.06097v1
- Date: Fri, 9 Jul 2021 22:26:50 GMT
- Title: Transformer-Based Behavioral Representation Learning Enables Transfer
Learning for Mobile Sensing in Small Datasets
- Authors: Mike A. Merrill and Tim Althoff
- Abstract summary: We provide a neural architecture framework for mobile sensing data that can learn generalizable feature representations from time series.
This architecture combines benefits from CNN and Trans-former architectures to enable better prediction performance.
- Score: 4.276883061502341
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: While deep learning has revolutionized research and applications in NLP and
computer vision, this has not yet been the case for behavioral modeling and
behavioral health applications. This is because the domain's datasets are
smaller, have heterogeneous datatypes, and typically exhibit a large degree of
missingness. Therefore, off-the-shelf deep learning models require significant,
often prohibitive, adaptation. Accordingly, many research applications still
rely on manually coded features with boosted tree models, sometimes with
task-specific features handcrafted by experts. Here, we address these
challenges by providing a neural architecture framework for mobile sensing data
that can learn generalizable feature representations from time series and
demonstrates the feasibility of transfer learning on small data domains through
finetuning. This architecture combines benefits from CNN and Trans-former
architectures to (1) enable better prediction performance by learning directly
from raw minute-level sensor data without the need for handcrafted features by
up to 0.33 ROC AUC, and (2) use pretraining to outperform simpler neural models
and boosted decision trees with data from as few a dozen participants.
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