Scaling whole-body multi-contact manipulation with contact optimization

Victor Levé; Joao Moura; Sachiya Fujita; Tamon Miyake; Steve Tonneau; Sethu Vijayakumar

Scaling whole-body multi-contact manipulation with contact optimization

Victor Levé^*, Joao Moura, Sachiya Fujita, Tamon Miyake, Steve Tonneau, Sethu Vijayakumar

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Daily tasks require us to use our whole body to manipulate objects, for instance when our hands are unavailable. We consider the issue of providing humanoid robots with the ability to autonomously perform similar whole-body manipulation tasks. In this context, the infinite possibilities for where and how contact can occur on the robot and object surfaces hinder the scalability of existing planning methods, which predominantly rely on discrete sampling. Given the continuous nature of contact surfaces, gradient-based optimization offers a more suitable approach for finding solutions. However, a key remaining challenge is the lack of an efficient representation of robot surfaces. In this work, we propose (i) a
representation of robot and object surfaces that enables closedform computation of proximity points, and (ii) a cost design that effectively guides whole-body manipulation planning. Our experiments demonstrate that the proposed framework can solve problems unaddressed by existing methods, and achieves a 77% improvement in planning time over the state of the art. We also validate the suitability of our approach on real hardware through the whole-body manipulation of boxes by a humanoid robot.

Original language	English
Title of host publication	Proceedings of the 24th International Conference on Humanoid Robots
Publisher	Institute of Electrical and Electronics Engineers
Pages	1-8
Number of pages	8
Publication status	Accepted/In press - 21 Jul 2025
Event	The 24th International Conference on Humanoid Robots - COEX, Seoul, Korea, Democratic People's Republic of Duration: 30 Sept 2025 → 2 Oct 2025 Conference number: 24 https://2025humanoids.org/

Publication series

Name	IEEE-RAS International Conference on Humanoid Robots
Publisher	IEEE
ISSN (Print)	2164-0572
ISSN (Electronic)	2164-0580

Conference

Conference	The 24th International Conference on Humanoid Robots
Abbreviated title	Humanoids 2025
Country/Territory	Korea, Democratic People's Republic of
City	Seoul
Period	30/09/25 → 2/10/25
Internet address	https://2025humanoids.org/

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LeveEtalHumanoids25ScalingWholeBodyMultiContactAccepted author manuscript, 11.8 MB

Moonshot - Hierarchical Motion Planning Framework Realizing Long-horizon Task
Vijayakumar, S. (Principal Investigator)
Japan Science and Technology Agency
1/04/24 → 30/11/25
Project: Research

Cite this

@inproceedings{c3638d69ec8b435e84de29d379d5a0cc,

title = "Scaling whole-body multi-contact manipulation with contact optimization",

abstract = "Daily tasks require us to use our whole body to manipulate objects, for instance when our hands are unavailable. We consider the issue of providing humanoid robots with the ability to autonomously perform similar whole-body manipulation tasks. In this context, the infinite possibilities for where and how contact can occur on the robot and object surfaces hinder the scalability of existing planning methods, which predominantly rely on discrete sampling. Given the continuous nature of contact surfaces, gradient-based optimization offers a more suitable approach for finding solutions. However, a key remaining challenge is the lack of an efficient representation of robot surfaces. In this work, we propose (i) a representation of robot and object surfaces that enables closedform computation of proximity points, and (ii) a cost design that effectively guides whole-body manipulation planning. Our experiments demonstrate that the proposed framework can solve problems unaddressed by existing methods, and achieves a 77\% improvement in planning time over the state of the art. We also validate the suitability of our approach on real hardware through the whole-body manipulation of boxes by a humanoid robot.",

author = "Victor Lev{\'e} and Joao Moura and Sachiya Fujita and Tamon Miyake and Steve Tonneau and Sethu Vijayakumar",

year = "2025",

month = jul,

day = "21",

language = "English",

series = "IEEE-RAS International Conference on Humanoid Robots",

publisher = "Institute of Electrical and Electronics Engineers",

pages = "1--8",

booktitle = "Proceedings of the 24th International Conference on Humanoid Robots",

address = "United States",

note = "The 24th International Conference on Humanoid Robots, Humanoids 2025 ; Conference date: 30-09-2025 Through 02-10-2025",

url = "https://2025humanoids.org/",

}

Levé, V, Moura, J, Fujita, S, Miyake, T, Tonneau, S & Vijayakumar, S 2025, Scaling whole-body multi-contact manipulation with contact optimization. in Proceedings of the 24th International Conference on Humanoid Robots. IEEE-RAS International Conference on Humanoid Robots, Institute of Electrical and Electronics Engineers, pp. 1-8, The 24th International Conference on Humanoid Robots, Seoul, Korea, Democratic People's Republic of, 30/09/25.

Scaling whole-body multi-contact manipulation with contact optimization. / Levé, Victor; Moura, Joao; Fujita, Sachiya et al.
Proceedings of the 24th International Conference on Humanoid Robots. Institute of Electrical and Electronics Engineers, 2025. p. 1-8 (IEEE-RAS International Conference on Humanoid Robots).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

TY - GEN

T1 - Scaling whole-body multi-contact manipulation with contact optimization

AU - Levé, Victor

AU - Moura, Joao

AU - Fujita, Sachiya

AU - Miyake, Tamon

AU - Tonneau, Steve

AU - Vijayakumar, Sethu

N1 - Conference code: 24

PY - 2025/7/21

Y1 - 2025/7/21

N2 - Daily tasks require us to use our whole body to manipulate objects, for instance when our hands are unavailable. We consider the issue of providing humanoid robots with the ability to autonomously perform similar whole-body manipulation tasks. In this context, the infinite possibilities for where and how contact can occur on the robot and object surfaces hinder the scalability of existing planning methods, which predominantly rely on discrete sampling. Given the continuous nature of contact surfaces, gradient-based optimization offers a more suitable approach for finding solutions. However, a key remaining challenge is the lack of an efficient representation of robot surfaces. In this work, we propose (i) a representation of robot and object surfaces that enables closedform computation of proximity points, and (ii) a cost design that effectively guides whole-body manipulation planning. Our experiments demonstrate that the proposed framework can solve problems unaddressed by existing methods, and achieves a 77% improvement in planning time over the state of the art. We also validate the suitability of our approach on real hardware through the whole-body manipulation of boxes by a humanoid robot.

AB - Daily tasks require us to use our whole body to manipulate objects, for instance when our hands are unavailable. We consider the issue of providing humanoid robots with the ability to autonomously perform similar whole-body manipulation tasks. In this context, the infinite possibilities for where and how contact can occur on the robot and object surfaces hinder the scalability of existing planning methods, which predominantly rely on discrete sampling. Given the continuous nature of contact surfaces, gradient-based optimization offers a more suitable approach for finding solutions. However, a key remaining challenge is the lack of an efficient representation of robot surfaces. In this work, we propose (i) a representation of robot and object surfaces that enables closedform computation of proximity points, and (ii) a cost design that effectively guides whole-body manipulation planning. Our experiments demonstrate that the proposed framework can solve problems unaddressed by existing methods, and achieves a 77% improvement in planning time over the state of the art. We also validate the suitability of our approach on real hardware through the whole-body manipulation of boxes by a humanoid robot.

M3 - Conference contribution

T3 - IEEE-RAS International Conference on Humanoid Robots

SP - 1

EP - 8

BT - Proceedings of the 24th International Conference on Humanoid Robots

PB - Institute of Electrical and Electronics Engineers

T2 - The 24th International Conference on Humanoid Robots

Y2 - 30 September 2025 through 2 October 2025

ER -

Scaling whole-body multi-contact manipulation with contact optimization

Abstract

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Moonshot - Hierarchical Motion Planning Framework Realizing Long-horizon Task

Cite this