Behavior self-organization supports task inference for continual robot learning
Behavior self-organization supports task inference for continual robot learning
Recent advances in robot learning have enabled robots to become increasingly better at mastering a predefined set of tasks. On the other hand, as humans, we have the ability to learn a growing set of tasks over our lifetime. Continual robot learning is an emerging research direction with the goal of endowing robots with this ability. In order to learn new tasks over time, the robot first needs to infer the task at hand. Task inference, however, has received little attention in the multi-task learning literature. In this paper, we propose a novel approach to continual learning of robotic control tasks. Our approach performs unsupervised learning of behavior embeddings by incrementally self-organizing demonstrated behaviors. Task inference is made by finding the nearest behavior embedding to a demonstrated behavior, which is used together with the environment state as input to a multi-task policy trained with reinforcement learning to optimize performance over tasks. Unlike previous approaches, our approach makes no assumptions about task distribution and requires no task exploration to infer tasks. We evaluate our approach in experiments with concurrently and sequentially presented tasks and show that it outperforms other multi-task learning approaches in terms of generalization performance and convergence speed, particularly in the continual learning setting.
6716-6723
Hafez, Muhammad Burhan
e8c991ab-d800-46f2-abeb-cb169a1ed47e
Wermter, Stefan
80682cc6-4251-420a-af8a-f4d616fb0fcc
16 December 2021
Hafez, Muhammad Burhan
e8c991ab-d800-46f2-abeb-cb169a1ed47e
Wermter, Stefan
80682cc6-4251-420a-af8a-f4d616fb0fcc
Hafez, Muhammad Burhan and Wermter, Stefan
(2021)
Behavior self-organization supports task inference for continual robot learning.
IEEE/RSJ International Conference on Intelligent Robots and Systems, , Prague, Czech Republic.
27 Sep - 01 Oct 2021.
.
(doi:10.1109/IROS51168.2021.9636297).
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Conference or Workshop Item
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Abstract
Recent advances in robot learning have enabled robots to become increasingly better at mastering a predefined set of tasks. On the other hand, as humans, we have the ability to learn a growing set of tasks over our lifetime. Continual robot learning is an emerging research direction with the goal of endowing robots with this ability. In order to learn new tasks over time, the robot first needs to infer the task at hand. Task inference, however, has received little attention in the multi-task learning literature. In this paper, we propose a novel approach to continual learning of robotic control tasks. Our approach performs unsupervised learning of behavior embeddings by incrementally self-organizing demonstrated behaviors. Task inference is made by finding the nearest behavior embedding to a demonstrated behavior, which is used together with the environment state as input to a multi-task policy trained with reinforcement learning to optimize performance over tasks. Unlike previous approaches, our approach makes no assumptions about task distribution and requires no task exploration to infer tasks. We evaluate our approach in experiments with concurrently and sequentially presented tasks and show that it outperforms other multi-task learning approaches in terms of generalization performance and convergence speed, particularly in the continual learning setting.
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Published date: 16 December 2021
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IEEE/RSJ International Conference on Intelligent Robots and Systems, , Prague, Czech Republic, 2021-09-27 - 2021-10-01
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Local EPrints ID: 495940
URI: http://eprints.soton.ac.uk/id/eprint/495940
PURE UUID: 4badba7c-44ee-4b8d-bc50-67872a024dfe
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Date deposited: 27 Nov 2024 18:00
Last modified: 28 Nov 2024 03:07
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Author:
Muhammad Burhan Hafez
Author:
Stefan Wermter
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