Safe Physical Human-Robot Interaction through Sensorless External Force Estimation for Industrial Robots

As social robot research is advancing, the interaction distance between people and robots is decreasing. Indeed, although we were once required to maintain a certain physical distance from traditional industrial robots for safety, we can now interact with social robots in such a close distance that we can touch them. The physical existence of social robots will be essential to realize natural and acceptable interactions with people in daily environments. Because social robots function in our daily environments, we must design scenarios where robots interact closely with humans by considering various viewpoints. Interactions that involve touching robots influence the changes in the behavior of a person strongly. Therefore, robotics researchers and developers need to design such scenarios carefully. Based on these considerations, this special issue focuses on close human-robot interactions. This special issue on “Human-Robot Interaction in Close Distance” includes a review paper and 11 other interesting papers covering various topics such as social touch interactions, non-verbal behavior design for touch interactions, child-robot interactions including physical contact, conversations with physical interactions, motion copying systems, and mobile human-robot interactions. We thank all the authors and reviewers of the papers and hope this special issue will help readers better understand human-robot interaction in close distance.

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Practical Aspects of Model-Based Collision Detection

Frontiers in Robotics and AI ◽

10.3389/frobt.2020.571574 ◽

2020 ◽

Vol 7 ◽

Author(s):

Shamil Mamedov ◽

Stanislav Mikhel

Keyword(s):

Collision Detection ◽

Model Identification ◽

Computation Time ◽

Human Robot Interaction ◽

Observer Design ◽

Industrial Robots ◽

Robot Interaction ◽

Model Based ◽

Proprioceptive Sensors ◽

The Relationship

Recently, with the increased number of robots entering numerous manufacturing fields, a considerable wealth of literature has appeared on the theme of physical human-robot interaction using data from proprioceptive sensors (motor or/and load side encoders). Most of the studies have then the accurate dynamic model of a robot for granted. In practice, however, model identification and observer design proceeds collision detection. To the best of our knowledge, no previous study has systematically investigated each aspect underlying physical human-robot interaction and the relationship between those aspects. In this paper, we bridge this gap by first reviewing the literature on model identification, disturbance estimation and collision detection, and discussing the relationship between the three, then by examining the practical sides of model-based collision detection on a case study conducted on UR10e. We show that the model identification step is critical for accurate collision detection, while the choice of the observer should be mostly based on computation time and the simplicity and flexibility of tuning. It is hoped that this study can serve as a roadmap to equip industrial robots with basic physical human-robot interaction capabilities.

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V2SOM: A Novel Safety Mechanism Dedicated to a Cobot’s Rotary Joints

Robotics ◽

10.3390/robotics8010018 ◽

2019 ◽

Vol 8 (1) ◽

pp. 18 ◽

Cited By ~ 4

Author(s):

Younsse Ayoubi ◽

Med Laribi ◽

Said Zeghloul ◽

Marc Arsicault

Keyword(s):

Good Control ◽

Variable Stiffness ◽

Human Robot Interaction ◽

Industrial Robots ◽

Necessary Condition ◽

Physical Interaction ◽

Robot Interaction ◽

Internal Damage ◽

Low Stiffness ◽

The Impact

Unlike “classical” industrial robots, collaborative robots, known as cobots, implement a compliant behavior. Cobots ensure a safe force control in a physical interaction scenario within unknown environments. In this paper, we propose to make serial robots intrinsically compliant to guarantee safe physical human–robot interaction (pHRI), via our novel designed device called V2SOM, which stands for Variable Stiffness Safety-Oriented Mechanism. As its name indicates, V2SOM aims at making physical human–robot interaction safe, thanks to its two basic functioning modes—high stiffness mode and low stiffness mode. The first mode is employed for normal operational routines. In contrast, the low stiffness mode is suitable for the safe absorption of any potential blunt shock with a human. The transition between the two modes is continuous to maintain a good control of the V2SOM-based cobot in the case of a fast collision. V2SOM presents a high inertia decoupling capacity which is a necessary condition for safe pHRI without compromising the robot’s dynamic performances. Two safety criteria of pHRI were considered for performance evaluations, namely, the impact force (ImpF) criterion and the head injury criterion (HIC) for, respectively, the external and internal damage evaluation during blunt shocks.

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Development of Flexible Robot Skin for Safe and Natural Human–Robot Collaboration

Micromachines ◽

10.3390/mi9110576 ◽

2018 ◽

Vol 9 (11) ◽

pp. 576 ◽

Cited By ~ 19

Author(s):

Gaoyang Pang ◽

Jia Deng ◽

Fangjinhua Wang ◽

Junhui Zhang ◽

Zhibo Pang ◽

...

Keyword(s):

Three Dimensional ◽

Human Robot Interaction ◽

Industrial Robots ◽

Percentage Change ◽

Flexible Robot ◽

Robot Interaction ◽

Industrial Manufacturing ◽

Collision Force ◽

The One ◽

Robot Skin

For industrial manufacturing, industrial robots are required to work together with human counterparts on certain special occasions, where human workers share their skills with robots. Intuitive human–robot interaction brings increasing safety challenges, which can be properly addressed by using sensor-based active control technology. In this article, we designed and fabricated a three-dimensional flexible robot skin made by the piezoresistive nanocomposite based on the need for enhancement of the security performance of the collaborative robot. The robot skin endowed the YuMi robot with a tactile perception like human skin. The developed sensing unit in the robot skin showed the one-to-one correspondence between force input and resistance output (percentage change in impedance) in the range of 0–6.5 N. Furthermore, the calibration result indicated that the developed sensing unit is capable of offering a maximum force sensitivity (percentage change in impedance per Newton force) of 18.83% N−1 when loaded with an external force of 6.5 N. The fabricated sensing unit showed good reproducibility after loading with cyclic force (0–5.5 N) under a frequency of 0.65 Hz for 3500 cycles. In addition, to suppress the bypass crosstalk in robot skin, we designed a readout circuit for sampling tactile data. Moreover, experiments were conducted to estimate the contact/collision force between the object and the robot in a real-time manner. The experiment results showed that the implemented robot skin can provide an efficient approach for natural and secure human–robot interaction.

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Practical application of a safe human-robot interaction software

Industrial Robot the international journal of robotics research and application ◽

10.1108/ir-09-2019-0180 ◽

2020 ◽

Vol 47 (3) ◽

pp. 359-368 ◽

Cited By ~ 1

Author(s):

Mustafa Can Bingol ◽

Omur Aydogmus

Keyword(s):

Robot Manipulator ◽

Industrial Robot ◽

Wavelet Packet ◽

Human Robot Interaction ◽

Industrial Robots ◽

Robot Interaction ◽

Content Type ◽

Depth Sensors ◽

Working Space ◽

Vision Module

Purpose Because of the increased use of robots in the industry, it has become inevitable for humans and robots to be able to work together. Therefore, human security has become the primary noncompromising factor of joint human and robot operations. For this reason, the purpose of this study was to develop a safe human-robot interaction software based on vision and touch. Design/methodology/approach The software consists of three modules. Firstly, the vision module has two tasks: to determine whether there is a human presence and to measure the distance between the robot and the human within the robot’s working space using convolutional neural networks (CNNs) and depth sensors. Secondly, the touch detection module perceives whether or not a human physically touches the robot within the same work environment using robot axis torques, wavelet packet decomposition algorithm and CNN. Lastly, the robot’s operating speed is adjusted according to hazard levels came from vision and touch module using the robot’s control module. Findings The developed software was tested with an industrial robot manipulator and successful results were obtained with minimal error. Practical implications The success of the developed algorithm was demonstrated in the current study and the algorithm can be used in other industrial robots for safety. Originality/value In this study, a new and practical safety algorithm is proposed and the health of people working with industrial robots is guaranteed.

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