Your search keyword '"Kolbeinsson, Arinbjörn"' showing total 3 results

1. Self-supervision of wearable sensors time-series data for influenza detection

Author

Kolbeinsson, Arinbjörn, Gade, Piyusha, Kainkaryam, Raghu, Jankovic, Filip, and Foschini, Luca

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Machine Learning (cs.LG)

Abstract

Self-supervision may boost model performance in downstream tasks. However, there is no principled way of selecting the self-supervised objectives that yield the most adaptable models. Here, we study this problem on daily time-series data generated from wearable sensors used to detect onset of influenza-like illness (ILI). We first show that using self-supervised learning to predict next-day time-series values allows us to learn rich representations which can be adapted to perform accurate ILI prediction. Second, we perform an empirical analysis of three different self-supervised objectives to assess their adaptability to ILI prediction. Our results show that predicting the next day's resting heart rate or time-in-bed during sleep provides better representations for ILI prediction. These findings add to previous work demonstrating the practical application of self-supervised learning from activity data to improve health predictions., Comment: The workshop on Self-Supervised Learning at NeurIPS (2021)

Published

2021

2. Biologically inspired architectures for sample-efficient deep reinforcement learning

Author

Richemond, Pierre H., Kolbeinsson, Arinbjörn, and Guo, Yike

Subjects

Computer Science::Machine Learning, FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Computer Science - Neural and Evolutionary Computing, Machine Learning (stat.ML), Neural and Evolutionary Computing (cs.NE), Machine Learning (cs.LG)

Abstract

Deep reinforcement learning requires a heavy price in terms of sample efficiency and overparameterization in the neural networks used for function approximation. In this work, we use tensor factorization in order to learn more compact representation for reinforcement learning policies. We show empirically that in the low-data regime, it is possible to learn online policies with 2 to 10 times less total coefficients, with little to no loss of performance. We also leverage progress in second order optimization, and use the theory of wavelet scattering to further reduce the number of learned coefficients, by foregoing learning the topmost convolutional layer filters altogether. We evaluate our results on the Atari suite against recent baseline algorithms that represent the state-of-the-art in data efficiency, and get comparable results with an order of magnitude gain in weight parsimony., Comment: Deep Reinforcement Learning Workshop, NeurIPS 2019, Vancouver, Canada

Published

2019

3. Adaptive Model Selection Framework: An Application to Airline Pricing

Author

Shukla, Naman, Kolbeinsson, Arinbjörn, Marla, Lavanya, and Yellepeddi, Kartik

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Machine Learning (stat.ML), Machine Learning (cs.LG)

Abstract

Multiple machine learning and prediction models are often used for the same prediction or recommendation task. In our recent work, where we develop and deploy airline ancillary pricing models in an online setting, we found that among multiple pricing models developed, no one model clearly dominates other models for all incoming customer requests. Thus, as algorithm designers, we face an exploration - exploitation dilemma. In this work, we introduce an adaptive meta-decision framework that uses Thompson sampling, a popular multi-armed bandit solution method, to route customer requests to various pricing models based on their online performance. We show that this adaptive approach outperform a uniformly random selection policy by improving the expected revenue per offer by 43% and conversion score by 58% in an offline simulation.

Published

2019