Related papers: Investigating Premature Convergence in Co-optimization of Morphology and Control in Evolved Virtual Soft Robots

Investigating Premature Convergence in Co-optimization of Morphology and Control in Evolved Virtual Soft Robots

URL: http://arxiv.org/abs/2402.09231v1
Date: Wed, 14 Feb 2024 15:21:17 GMT
Title: Investigating Premature Convergence in Co-optimization of Morphology and Control in Evolved Virtual Soft Robots
Authors: Alican Mertan and Nick Cheney
Abstract summary: Co-optimization of morphology and control of evolved virtual soft robots is a challenging problem. We show that high-performing regions in the morphology space are not able to be discovered during the co-optimization of the morphology and control. We propose a new body-centric framework to think about the co-optimization problem.
Score: 0.2900810893770134
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Evolving virtual creatures is a field with a rich history and recently it has been getting more attention, especially in the soft robotics domain. The compliance of soft materials endows soft robots with complex behavior, but it also makes their design process unintuitive and in need of automated design. Despite the great interest, evolved virtual soft robots lack the complexity, and co-optimization of morphology and control remains a challenging problem. Prior work identifies and investigates a major issue with the co-optimization process -- fragile co-adaptation of brain and body resulting in premature convergence of morphology. In this work, we expand the investigation of this phenomenon by comparing learnable controllers with proprioceptive observations and fixed controllers without any observations, whereas in the latter case, we only have the optimization of the morphology. Our experiments in two morphology spaces and two environments that vary in complexity show, concrete examples of the existence of high-performing regions in the morphology space that are not able to be discovered during the co-optimization of the morphology and control, yet exist and are easily findable when optimizing morphologies alone. Thus this work clearly demonstrates and characterizes the challenges of optimizing morphology during co-optimization. Based on these results, we propose a new body-centric framework to think about the co-optimization problem which helps us understand the issue from a search perspective. We hope the insights we share with this work attract more attention to the problem and help us to enable efficient brain-body co-optimization.

Related papers

Evolution and learning in differentiable robots [0.0]
We use differentiable simulations to rapidly and simultaneously optimize individual neural control of behavior across a large population of candidate body plans. Non-differentiable changes to the mechanical structure of each robot in the population were applied by a genetic algorithm in an outer loop of search. One of the highly differentiable morphologies discovered in simulation was realized as a physical robot and shown to retain its optimized behavior.
arXiv Detail & Related papers (2024-05-23T15:45:43Z)
Task2Morph: Differentiable Task-inspired Framework for Contact-Aware Robot Design [5.4795537587182475]
This paper proposes a novel differentiable task-inspired framework for contact-aware robot design called Task2Morph. We embed the mapping into a differentiable robot design process, where the gradient information is leveraged for both the mapping learning and the whole optimization. The experiments are conducted on three scenarios, and the results validate that Task2Morph outperforms DiffHand, which lacks a task-inspired morphology module, in terms of efficiency and effectiveness.
arXiv Detail & Related papers (2024-03-28T02:02:00Z)
DiffuseBot: Breeding Soft Robots With Physics-Augmented Generative Diffusion Models [102.13968267347553]
We present DiffuseBot, a physics-augmented diffusion model that generates soft robot morphologies capable of excelling in a wide spectrum of tasks. We showcase a range of simulated and fabricated robots along with their capabilities.
arXiv Detail & Related papers (2023-11-28T18:58:48Z)
SoftZoo: A Soft Robot Co-design Benchmark For Locomotion In Diverse Environments [111.91255476270526]
We introduce SoftZoo, a soft robot co-design platform for locomotion in diverse environments. SoftZoo supports an extensive, naturally-inspired material set, including the ability to simulate environments such as flat ground, desert, wetland, clay, ice, snow, shallow water, and ocean. It provides a variety of tasks relevant for soft robotics, including fast locomotion, agile turning, and path following, as well as differentiable design representations for morphology and control.
arXiv Detail & Related papers (2023-03-16T17:59:50Z)
Universal Morphology Control via Contextual Modulation [52.742056836818136]
Learning a universal policy across different robot morphologies can significantly improve learning efficiency and generalization in continuous control. Existing methods utilize graph neural networks or transformers to handle heterogeneous state and action spaces across different morphologies. We propose a hierarchical architecture to better model this dependency via contextual modulation.
arXiv Detail & Related papers (2023-02-22T00:04:12Z)
Co-optimising Robot Morphology and Controller in a Simulated Open-Ended Environment [1.4502611532302039]
We show how changing the environment, where the agent locomotes, affects the convergence of morphologies. We show that agent-populations evolving in open-endedly evolving environments exhibit larger morphological diversity than agent-populations evolving in hand crafted curricula of environments.
arXiv Detail & Related papers (2021-04-07T11:28:23Z)
Task-Agnostic Morphology Evolution [94.97384298872286]
Current approaches that co-adapt morphology and behavior use a specific task's reward as a signal for morphology optimization. This often requires expensive policy optimization and results in task-dependent morphologies that are not built to generalize. We propose a new approach, Task-Agnostic Morphology Evolution (TAME), to alleviate both of these issues.
arXiv Detail & Related papers (2021-02-25T18:59:21Z)
Emergent Hand Morphology and Control from Optimizing Robust Grasps of Diverse Objects [63.89096733478149]
We introduce a data-driven approach where effective hand designs naturally emerge for the purpose of grasping diverse objects. We develop a novel Bayesian Optimization algorithm that efficiently co-designs the morphology and grasping skills jointly. We demonstrate the effectiveness of our approach in discovering robust and cost-efficient hand morphologies for grasping novel objects.
arXiv Detail & Related papers (2020-12-22T17:52:29Z)
RoboTHOR: An Open Simulation-to-Real Embodied AI Platform [56.50243383294621]
We introduce RoboTHOR to democratize research in interactive and embodied visual AI. We show there exists a significant gap between the performance of models trained in simulation when they are tested in both simulations and their carefully constructed physical analogs.
arXiv Detail & Related papers (2020-04-14T20:52:49Z)
Environmental Adaptation of Robot Morphology and Control through Real-world Evolution [5.08706161686979]
We apply evolutionary search to yield combinations of morphology and control for our mechanically self-reconfiguring quadruped robot. We evolve solutions on two distinct physical surfaces and analyze the results in terms of both control and morphology.
arXiv Detail & Related papers (2020-03-30T07:57:19Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.