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Main Authors: Zhang, Ruining, Han, Haoran, Lv, Maolong, Yang, Qisong, Cheng, Jian
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.10472
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author Zhang, Ruining
Han, Haoran
Lv, Maolong
Yang, Qisong
Cheng, Jian
author_facet Zhang, Ruining
Han, Haoran
Lv, Maolong
Yang, Qisong
Cheng, Jian
contents Extensive utilization of deep reinforcement learning (DRL) policy networks in diverse continuous control tasks has raised questions regarding performance degradation in expansive state spaces where the input state norm is larger than that in the training environment. This paper aims to uncover the underlying factors contributing to such performance deterioration when dealing with expanded state spaces, using a novel analysis technique known as state division. In contrast to prior approaches that employ state division merely as a post-hoc explanatory tool, our methodology delves into the intrinsic characteristics of DRL policy networks. Specifically, we demonstrate that the expansion of state space induces the activation function $\tanh$ to exhibit saturability, resulting in the transformation of the state division boundary from nonlinear to linear. Our analysis centers on the paradigm of the double-integrator system, revealing that this gradual shift towards linearity imparts a control behavior reminiscent of bang-bang control. However, the inherent linearity of the division boundary prevents the attainment of an ideal bang-bang control, thereby introducing unavoidable overshooting. Our experimental investigations, employing diverse RL algorithms, establish that this performance phenomenon stems from inherent attributes of the DRL policy network, remaining consistent across various optimization algorithms.
format Preprint
id arxiv_https___arxiv_org_abs_2312_10472
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Analyzing Generalization in Policy Networks: A Case Study with the Double-Integrator System
Zhang, Ruining
Han, Haoran
Lv, Maolong
Yang, Qisong
Cheng, Jian
Machine Learning
Artificial Intelligence
Systems and Control
Extensive utilization of deep reinforcement learning (DRL) policy networks in diverse continuous control tasks has raised questions regarding performance degradation in expansive state spaces where the input state norm is larger than that in the training environment. This paper aims to uncover the underlying factors contributing to such performance deterioration when dealing with expanded state spaces, using a novel analysis technique known as state division. In contrast to prior approaches that employ state division merely as a post-hoc explanatory tool, our methodology delves into the intrinsic characteristics of DRL policy networks. Specifically, we demonstrate that the expansion of state space induces the activation function $\tanh$ to exhibit saturability, resulting in the transformation of the state division boundary from nonlinear to linear. Our analysis centers on the paradigm of the double-integrator system, revealing that this gradual shift towards linearity imparts a control behavior reminiscent of bang-bang control. However, the inherent linearity of the division boundary prevents the attainment of an ideal bang-bang control, thereby introducing unavoidable overshooting. Our experimental investigations, employing diverse RL algorithms, establish that this performance phenomenon stems from inherent attributes of the DRL policy network, remaining consistent across various optimization algorithms.
title Analyzing Generalization in Policy Networks: A Case Study with the Double-Integrator System
topic Machine Learning
Artificial Intelligence
Systems and Control
url https://arxiv.org/abs/2312.10472