Assessing Transferability From Simulation to Reality for Reinforcement Learning

Fabio Muratore; Michael Gienger; Jan Peters

doi:10.1109/TPAMI.2019.2952353

Assessing Transferability From Simulation to Reality for Reinforcement Learning

Standard

Assessing Transferability From Simulation to Reality for Reinforcement Learning. / Muratore, Fabio; Gienger, Michael; Peters, Jan.

in: IEEE T SOFTWARE ENG, Jahrgang 43, Nr. 4, 04.2021, S. 1172-1183.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Muratore, F, Gienger, M & Peters, J 2021, 'Assessing Transferability From Simulation to Reality for Reinforcement Learning', IEEE T SOFTWARE ENG, Jg. 43, Nr. 4, S. 1172-1183. https://doi.org/10.1109/TPAMI.2019.2952353

APA

Muratore, F., Gienger, M., & Peters, J. (2021). Assessing Transferability From Simulation to Reality for Reinforcement Learning. IEEE T SOFTWARE ENG, 43(4), 1172-1183. https://doi.org/10.1109/TPAMI.2019.2952353

Vancouver

Muratore F, Gienger M, Peters J. Assessing Transferability From Simulation to Reality for Reinforcement Learning. IEEE T SOFTWARE ENG. 2021 Apr;43(4):1172-1183. https://doi.org/10.1109/TPAMI.2019.2952353

Bibtex

@article{52b8b101b38c4d62a34cb4f0a6c9a41e,

title = "Assessing Transferability From Simulation to Reality for Reinforcement Learning",

abstract = "Learning robot control policies from physics simulations is of great interest to the robotics community as it may render the learning process faster, cheaper, and safer by alleviating the need for expensive real-world experiments. However, the direct transfer of learned behavior from simulation to reality is a major challenge. Optimizing a policy on a slightly faulty simulator can easily lead to the maximization of the 'Simulation Optimization Bias' (SOB). In this case, the optimizer exploits modeling errors of the simulator such that the resulting behavior can potentially damage the robot. We tackle this challenge by applying domain randomization, i.e., randomizing the parameters of the physics simulations during learning. We propose an algorithm called Simulation-based Policy Optimization with Transferability Assessment (SPOTA) which uses an estimator of the SOB to formulate a stopping criterion for training. The introduced estimator quantifies the over-fitting to the set of domains experienced while training. Our experimental results on two different second order nonlinear systems show that the new simulation-based policy search algorithm is able to learn a control policy exclusively from a randomized simulator, which can be applied directly to real systems without any additional training.",

author = "Fabio Muratore and Michael Gienger and Jan Peters",

year = "2021",

month = apr,

doi = "10.1109/TPAMI.2019.2952353",

language = "English",

volume = "43",

pages = "1172--1183",

journal = "IEEE T SOFTWARE ENG",

issn = "0098-5589",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "4",

}

RIS

TY - JOUR

T1 - Assessing Transferability From Simulation to Reality for Reinforcement Learning

AU - Muratore, Fabio

AU - Gienger, Michael

AU - Peters, Jan

PY - 2021/4

Y1 - 2021/4

N2 - Learning robot control policies from physics simulations is of great interest to the robotics community as it may render the learning process faster, cheaper, and safer by alleviating the need for expensive real-world experiments. However, the direct transfer of learned behavior from simulation to reality is a major challenge. Optimizing a policy on a slightly faulty simulator can easily lead to the maximization of the 'Simulation Optimization Bias' (SOB). In this case, the optimizer exploits modeling errors of the simulator such that the resulting behavior can potentially damage the robot. We tackle this challenge by applying domain randomization, i.e., randomizing the parameters of the physics simulations during learning. We propose an algorithm called Simulation-based Policy Optimization with Transferability Assessment (SPOTA) which uses an estimator of the SOB to formulate a stopping criterion for training. The introduced estimator quantifies the over-fitting to the set of domains experienced while training. Our experimental results on two different second order nonlinear systems show that the new simulation-based policy search algorithm is able to learn a control policy exclusively from a randomized simulator, which can be applied directly to real systems without any additional training.

AB - Learning robot control policies from physics simulations is of great interest to the robotics community as it may render the learning process faster, cheaper, and safer by alleviating the need for expensive real-world experiments. However, the direct transfer of learned behavior from simulation to reality is a major challenge. Optimizing a policy on a slightly faulty simulator can easily lead to the maximization of the 'Simulation Optimization Bias' (SOB). In this case, the optimizer exploits modeling errors of the simulator such that the resulting behavior can potentially damage the robot. We tackle this challenge by applying domain randomization, i.e., randomizing the parameters of the physics simulations during learning. We propose an algorithm called Simulation-based Policy Optimization with Transferability Assessment (SPOTA) which uses an estimator of the SOB to formulate a stopping criterion for training. The introduced estimator quantifies the over-fitting to the set of domains experienced while training. Our experimental results on two different second order nonlinear systems show that the new simulation-based policy search algorithm is able to learn a control policy exclusively from a randomized simulator, which can be applied directly to real systems without any additional training.

U2 - 10.1109/TPAMI.2019.2952353

DO - 10.1109/TPAMI.2019.2952353

M3 - SCORING: Journal article

C2 - 31722475

VL - 43

SP - 1172

EP - 1183

JO - IEEE T SOFTWARE ENG

JF - IEEE T SOFTWARE ENG

SN - 0098-5589

IS - 4

ER -