Experience-based torque estimation for an industrial robot

Berger, Erik; Grehl, Steve; Vogt, David; Jung, Bernhard; Amor, Heni Ben

doi:10.1109/icra.2016.7487127

Cited by 12 publications

(11 citation statements)

References 9 publications

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“…In any kind of production process, not only the task should be properly designed but also the measurement system should be properly implemented to keep a good product quality and an efficient flow. For Chen (2014) and Berger et al (2016), accurate measurement of external forces is also important in manipulation tasks involving tool-usage, the fastening torque and the angular displacement of the screw have to be closely monitored. Muelaner et al (2010) describe "the accuracy of the measurement system is lower than that of assembly design takes place", calling this statement as a phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Screw torque traceability control: industrial application

Silva

Uhlmann

Frazzon

2020

Ind. Jour. Manag. & Prod.

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This paper analyses a new screw torque traceability control procedure designed for an operation in a car audio workstation. First the detection score at a Failure Mode and Effects Analysis (FMEA) indicated which process improvement were needed. On the sequence, data was collected to evaluate performance indicators. Finally, specific actions were executed based on the improvement plan. As result, the FMEA detection score improved from 7 to 3, the run rate increased from 12 to 16 products/h and defects caused by improper screwing were eliminated. This research contributes to disseminate a practical application of a screw torque traceability control.

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Section: Introductionmentioning

confidence: 99%

Screw torque traceability control: industrial application

Silva

Uhlmann

Frazzon

2020

Ind. Jour. Manag. & Prod.

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“…Additionally, Transfer Entropy (TE) exists, which allows identification of a cause-effect relationship by not accounting for straightforward and uniquely shared information [15]. TE has been applied to many complex problems from diverse research fields e.g., oscillation analysis [16], finance [17,18], sensors [19][20][21][22], biosignals [23,24], thermonuclear fusion [25], complex networks [26], geophysical phenomena [27,28], industrial energy consumption network [29] and algorithmic theory of information [30]. In addition, TE has been implemented in non-Gaussian distributions, such as: multivariate exponential, logistic, Pareto (type I-IV) and Burr distributions [31].…”

Section: Introductionmentioning

confidence: 99%

Parallelism Strategies for Big Data Delayed Transfer Entropy Evaluation

2019

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Generated and collected data have been rising with the popularization of technologies such as Internet of Things, social media, and smartphone, leading big data term creation. One class of big data hidden information is causality. Among the tools to infer causal relationships, there is Delay Transfer Entropy (DTE); however, it has a high demanding processing power. Many approaches were proposed to overcome DTE performance issues such as GPU and FPGA implementations. Our study compared different parallel strategies to calculate DTE from big data series using a heterogeneous Beowulf cluster. Task Parallelism was significantly faster in comparison to Data Parallelism. With big data trend in sight, these results may enable bigger datasets analysis or better statistical evidence.

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“…Safety is the inherent and most important feature of a robot that has to work close to or collaborate with human beings. Due to the limits of sensors 15 and robot motion capabilities, e.g., when the human moves faster than the robot can sense or counteract, undesired contacts or collisions with humans may occur. This is handled in the lowest (direct) layer of the control architecture, which implements sensorless collision detection, isolation, and reflex reaction based on our residual method [4,5,6], a model-based scheme that monitors the 20 generalized momentum of the robot.…”

Section: Introductionmentioning

confidence: 99%

“…A force/torque (F/T) sensor is used to decrease uncertainties due to friction, so as to improve force estimation when the robot is not in motion. Under similar operative conditions, learning-based approaches have also been applied for estimating exchanged external forces [14,15]. The estimated external force and the saturation of motor control torques can be used to keep the actual exchanged forces under a safety threshold [16].…”

Section: Introductionmentioning

confidence: 99%

A model-based residual approach for human-robot collaboration during manual polishing operations

2018

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A fully robotized polishing of metallic surfaces may be insufficient in case of parts with complex geometric shapes, where a manual intervention is still preferable.Within the EU SYMPLEXITY project, we are considering tasks where manual polishing operations are performed in strict physical Human-Robot Collaboration (HRC) between a robot holding the part and a human operator equipped with an abrasive tool. During the polishing task, the robot should firmly keep the workpiece in a prescribed sequence of poses, by monitoring and resisting to the external forces applied by the operator. However, the user may also wish to change the orientation of the part mounted on the robot, simply by pushing or pulling the robot body and changing thus its configuration. We propose a control algorithm that is able to distinguish the external torques acting at the robot joints in two components, one due to the polishing forces being applied at the end-effector level, the other due to the intentional physical interaction engaged by the human. The latter component is used to reconfigure the manipulator arm and, accordingly, its end-effector orientation. The workpiece position is kept instead fixed, by exploiting the intrinsic redundancy of this subtask. The controller uses a F/T sensor mounted at the robot wrist, together with our re-$ cently developed model-based technique (the residual method) that is able to estimate online the joint torques due to contact forces/torques applied at any place along the robot structure. In order to obtain a reliable residual, which is necessary to implement the control algorithm, an accurate robot dynamic model (including also friction effects at the joints and drive gains) needs to be identified first. The complete dynamic identification and the proposed control method for the human-robot collaborative polishing task are illustrated on a 6R UR10 lightweight manipulator mounting an ATI 6D sensor. polishing 45 placed on the final robot flange provides then the exchanged forces/torques. When the contact point is known in advance, the problem of sensor-less contact force estimation without the use of a F/T sensor has been addressed in [13], based on motor torque/current measurements. A dithering feedforward torque

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Experience-based torque estimation for an industrial robot

Cited by 12 publications

References 9 publications

Screw torque traceability control: industrial application

Screw torque traceability control: industrial application

Parallelism Strategies for Big Data Delayed Transfer Entropy Evaluation

A model-based residual approach for human-robot collaboration during manual polishing operations

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