Morphology specific stepwise learning of in-hand manipulation with a four-fingered hand

Satoshi Funabashi; Alexander Schmitz; Shun Ogasa; Shigeki Sugano

doi:10.1109/TII.2019.2893713

Morphology specific stepwise learning of in-hand manipulation with a four-fingered hand

Satoshi Funabashi^*, Alexander Schmitz, Shun Ogasa, Shigeki Sugano

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

In past research, in-hand object manipulation for various sized and shaped objects has been achieved. However, the network had to be trained for each different motion. Training data takes time to acquire and increases the hardware load, thereby increasing the cost for training data. Four-fingered in-hand manipulation is especially difficult as a high number of joints need to be controlled in synchrony. This paper presents a method that reduces the required training data for in-hand manipulation with the idea of pretraining and mutual finger motions. The Allegro Hand is used with soft fingertips and integrated 6-axis F/T sensors to evaluate the proposed method. To make the network more versatile, the training data included objects of various sizes and shapes. When pretraining the network, one shot learning suffices to learn a new task; mutual finger motions can be exploited to use three-fingered pretraining data for four-fingered manipulation. Both data-sharing and weight-sharing were used and show similar results. Crucially, pretraining data from fingers with the same kinematic chain has to be used, showing the importance of morphology specific learning. Moreover, objects with untrained sizes and shapes could be manipulated.

Original language	English
Article number	8616845
Pages (from-to)	433-441
Number of pages	9
Journal	IEEE Transactions on Industrial Informatics
Volume	16
Issue number	1
DOIs	https://doi.org/10.1109/TII.2019.2893713
Publication status	Published - 2020 Jan

Keywords

In-hand manipulation
multifingered hand
neural networks
one-shot learning
tactile sensing
weight-sharing

ASJC Scopus subject areas

Control and Systems Engineering
Information Systems
Computer Science Applications
Electrical and Electronic Engineering

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10.1109/TII.2019.2893713

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title = "Morphology specific stepwise learning of in-hand manipulation with a four-fingered hand",

abstract = "In past research, in-hand object manipulation for various sized and shaped objects has been achieved. However, the network had to be trained for each different motion. Training data takes time to acquire and increases the hardware load, thereby increasing the cost for training data. Four-fingered in-hand manipulation is especially difficult as a high number of joints need to be controlled in synchrony. This paper presents a method that reduces the required training data for in-hand manipulation with the idea of pretraining and mutual finger motions. The Allegro Hand is used with soft fingertips and integrated 6-axis F/T sensors to evaluate the proposed method. To make the network more versatile, the training data included objects of various sizes and shapes. When pretraining the network, one shot learning suffices to learn a new task; mutual finger motions can be exploited to use three-fingered pretraining data for four-fingered manipulation. Both data-sharing and weight-sharing were used and show similar results. Crucially, pretraining data from fingers with the same kinematic chain has to be used, showing the importance of morphology specific learning. Moreover, objects with untrained sizes and shapes could be manipulated.",

keywords = "In-hand manipulation, multifingered hand, neural networks, one-shot learning, tactile sensing, weight-sharing",

author = "Satoshi Funabashi and Alexander Schmitz and Shun Ogasa and Shigeki Sugano",

note = "Funding Information: Manuscript received July 29, 2018; revised November 1, 2018; accepted December 18, 2018. Date of publication January 17, 2019; date of current version January 4, 2020. This work was supported in part by the JSPS Grant-in-Aid for Scientific Research (S) No. 25220005, in part by the JSPS Research Fellowship for Young Scientists (DC) No. JP17J10571, in part by the Research Institute for Science and Engineering of Waseda University, and in part by the Program for Leading Graduate Schools (Graduate Program for Embodiment Informatics) of MEXT. Paper no. TII-18-1957. (Corresponding author: Satoshi Funabashi.) The authors are with the Sugano Laboratory, Faculty of Science and Engineering, Department of Modern Mechanical Engineering, Waseda University, Tokyo 169-8555, Japan (e-mail:,[email protected]. waseda.ac.jp; [email protected]; [email protected]. jp; [email protected]). Publisher Copyright: {\textcopyright} 2005-2012 IEEE.",

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N1 - Funding Information: Manuscript received July 29, 2018; revised November 1, 2018; accepted December 18, 2018. Date of publication January 17, 2019; date of current version January 4, 2020. This work was supported in part by the JSPS Grant-in-Aid for Scientific Research (S) No. 25220005, in part by the JSPS Research Fellowship for Young Scientists (DC) No. JP17J10571, in part by the Research Institute for Science and Engineering of Waseda University, and in part by the Program for Leading Graduate Schools (Graduate Program for Embodiment Informatics) of MEXT. Paper no. TII-18-1957. (Corresponding author: Satoshi Funabashi.) The authors are with the Sugano Laboratory, Faculty of Science and Engineering, Department of Modern Mechanical Engineering, Waseda University, Tokyo 169-8555, Japan (e-mail:,[email protected]. waseda.ac.jp; [email protected]; [email protected]. jp; [email protected]). Publisher Copyright: © 2005-2012 IEEE.

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N2 - In past research, in-hand object manipulation for various sized and shaped objects has been achieved. However, the network had to be trained for each different motion. Training data takes time to acquire and increases the hardware load, thereby increasing the cost for training data. Four-fingered in-hand manipulation is especially difficult as a high number of joints need to be controlled in synchrony. This paper presents a method that reduces the required training data for in-hand manipulation with the idea of pretraining and mutual finger motions. The Allegro Hand is used with soft fingertips and integrated 6-axis F/T sensors to evaluate the proposed method. To make the network more versatile, the training data included objects of various sizes and shapes. When pretraining the network, one shot learning suffices to learn a new task; mutual finger motions can be exploited to use three-fingered pretraining data for four-fingered manipulation. Both data-sharing and weight-sharing were used and show similar results. Crucially, pretraining data from fingers with the same kinematic chain has to be used, showing the importance of morphology specific learning. Moreover, objects with untrained sizes and shapes could be manipulated.

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Morphology specific stepwise learning of in-hand manipulation with a four-fingered hand

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Keywords

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