Compensating Pose Uncertainties Through Appropriate Gripper Finger Cutouts

Adam Wolniakowski; Andrej Gams; Lilita Kiforenko; Aljaž Kramberger; Dimitrios Chrysostomou; Ole Madsen; Konstantsin Miatliuk; Henrik Gordon Petersen; Frederik Hagelskjær; Anders Glent Buch; Ales Ude; Norbert Krüger

Compensating Pose Uncertainties Through Appropriate Gripper Finger Cutouts

Adam Wolniakowski, Andrej Gams, Lilita Kiforenko, Aljaž Kramberger, Dimitrios Chrysostomou, Ole Madsen, Konstantsin Miatliuk, Henrik Gordon Petersen, Frederik Hagelskjær, Anders Glent Buch, Ales Ude, Norbert Krüger

Publikation: Bidrag til bog/antologi/rapport/konference proceeding › Konferenceartikel i proceeding › Forskning › peer review

Abstract

The gripper finger design is a recurring problem in many robotic grasping platforms used in industry. The task of switching the gripper configuration to accommodate for a new batch of objects typically requires engineering expertise, and is a lengthy and costly iterative trial-and-error process. One of the open challenges is the need for the gripper to compensate for uncertainties inherent to the workcell, e.g. due to errors in calibration, inaccurate pose estimation from the vision system, or object deformation. In this paper, we present an analysis of gripper uncertainty compensating capabilities in a sample industrial object grasping scenario for a finger that was designed using an automated simulation-based geometry optimization method [1, 2]. We test the developed gripper with a set of grasps subjected to structured perturbation in a simulation environment and in the real-world setting. We provide a comparison of the data obtained by using both of these approaches. We argue that the strong correspondence observed in results validates the use of dynamic simulation for the gripper finger design and optimization.

Originalsprog	Engelsk
Titel	12th International Conference Mechatronic Systems and Materials (MSM'16)
Publikationsdato	2018
Status	Udgivet - 2018
Begivenhed	International Conference on Mechatronic Systems and Materials - Białystok, Białystok, Polen Varighed: 3 jul. 2016 → 8 jul. 2016 Konferencens nummer: 12 http://www.msm2016.pb.edu.pl/

Konference

Konference	International Conference on Mechatronic Systems and Materials
Nummer	12
Lokation	Białystok
Land/Område	Polen
By	Białystok
Periode	03/07/2016 → 08/07/2016
Internetadresse	http://www.msm2016.pb.edu.pl/

AUB Link

Søg efter materialet i Aalborg Universitetsbiblioteks søgemaskine

ACAT: Learning and Execution of Action Categories
Madsen, O. & Chrysostomou, D.
01/03/2013 → 30/04/2016
Projekter: Projekt › Forskning

Fil

Citationsformater

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title = "Compensating Pose Uncertainties Through Appropriate Gripper Finger Cutouts",

abstract = "The gripper finger design is a recurring problem in many robotic grasping platforms used in industry. The task of switching the gripper configuration to accommodate for a new batch of objects typically requires engineering expertise, and is a lengthy and costly iterative trial-and-error process. One of the open challenges is the need for the gripper to compensate for uncertainties inherent to the workcell, e.g. due to errors in calibration, inaccurate pose estimation from the vision system, or object deformation. In this paper, we present an analysis of gripper uncertainty compensating capabilities in a sample industrial object grasping scenario for a finger that was designed using an automated simulation-based geometry optimization method [1, 2]. We test the developed gripper with a set of grasps subjected to structured perturbation in a simulation environment and in the real-world setting. We provide a comparison of the data obtained by using both of these approaches. We argue that the strong correspondence observed in results validates the use of dynamic simulation for the gripper finger design and optimization.",

author = "Adam Wolniakowski and Andrej Gams and Lilita Kiforenko and Alja{\v z} Kramberger and Dimitrios Chrysostomou and Ole Madsen and Konstantsin Miatliuk and Petersen, {Henrik Gordon} and Frederik Hagelskj{\ae}r and Buch, {Anders Glent} and Ales Ude and Norbert Kr{\"u}ger",

year = "2018",

language = "English",

booktitle = "12th International Conference Mechatronic Systems and Materials (MSM'16)",

note = "International Conference on Mechatronic Systems and Materials, MSM ; Conference date: 03-07-2016 Through 08-07-2016",

url = "http://www.msm2016.pb.edu.pl/",

}

Wolniakowski, A, Gams, A, Kiforenko, L, Kramberger, A, Chrysostomou, D , Madsen, O, Miatliuk, K, Petersen, HG, Hagelskjær, F, Buch, AG, Ude, A & Krüger, N 2018, Compensating Pose Uncertainties Through Appropriate Gripper Finger Cutouts. i 12th International Conference Mechatronic Systems and Materials (MSM'16). International Conference on Mechatronic Systems and Materials, Białystok, Polen, 03/07/2016.

TY - GEN

T1 - Compensating Pose Uncertainties Through Appropriate Gripper Finger Cutouts

AU - Wolniakowski, Adam

AU - Gams, Andrej

AU - Kiforenko, Lilita

AU - Kramberger, Aljaž

AU - Chrysostomou, Dimitrios

AU - Madsen, Ole

AU - Miatliuk, Konstantsin

AU - Petersen, Henrik Gordon

AU - Hagelskjær, Frederik

AU - Buch, Anders Glent

AU - Ude, Ales

AU - Krüger, Norbert

N1 - Conference code: 12

PY - 2018

Y1 - 2018

N2 - The gripper finger design is a recurring problem in many robotic grasping platforms used in industry. The task of switching the gripper configuration to accommodate for a new batch of objects typically requires engineering expertise, and is a lengthy and costly iterative trial-and-error process. One of the open challenges is the need for the gripper to compensate for uncertainties inherent to the workcell, e.g. due to errors in calibration, inaccurate pose estimation from the vision system, or object deformation. In this paper, we present an analysis of gripper uncertainty compensating capabilities in a sample industrial object grasping scenario for a finger that was designed using an automated simulation-based geometry optimization method [1, 2]. We test the developed gripper with a set of grasps subjected to structured perturbation in a simulation environment and in the real-world setting. We provide a comparison of the data obtained by using both of these approaches. We argue that the strong correspondence observed in results validates the use of dynamic simulation for the gripper finger design and optimization.

AB - The gripper finger design is a recurring problem in many robotic grasping platforms used in industry. The task of switching the gripper configuration to accommodate for a new batch of objects typically requires engineering expertise, and is a lengthy and costly iterative trial-and-error process. One of the open challenges is the need for the gripper to compensate for uncertainties inherent to the workcell, e.g. due to errors in calibration, inaccurate pose estimation from the vision system, or object deformation. In this paper, we present an analysis of gripper uncertainty compensating capabilities in a sample industrial object grasping scenario for a finger that was designed using an automated simulation-based geometry optimization method [1, 2]. We test the developed gripper with a set of grasps subjected to structured perturbation in a simulation environment and in the real-world setting. We provide a comparison of the data obtained by using both of these approaches. We argue that the strong correspondence observed in results validates the use of dynamic simulation for the gripper finger design and optimization.

M3 - Article in proceeding

BT - 12th International Conference Mechatronic Systems and Materials (MSM'16)

T2 - International Conference on Mechatronic Systems and Materials

Y2 - 3 July 2016 through 8 July 2016

ER -

Compensating Pose Uncertainties Through Appropriate Gripper Finger Cutouts

Abstract

Konference

AUB Link

Fingeraftryk

Projekter

ACAT: Learning and Execution of Action Categories

Citationsformater