Your search keyword '"Erden, Mustafa"' showing total 9 results

1. End-point impedance measurements across dominant and nondominant hands and robotic assistance with directional damping.

Author

Erden MS and Billard A

Subjects

Adult, Algorithms, Electric Impedance, Female, Humans, Male, Models, Theoretical, Paint, Robotics instrumentation, Task Performance and Analysis, Young Adult, Hand physiology, Man-Machine Systems, Robotics methods

Abstract

The goal of this paper is to perform end-point impedance measurements across dominant and nondominant hands while doing airbrush painting and to use the results for developing a robotic assistance scheme. We study airbrush painting because it resembles in many ways manual welding, a standard industrial task. The experiments are performed with the 7 degrees of freedom KUKA lightweight robot arm. The robot is controlled in admittance using a force sensor attached at the end-point, so as to act as a free-mass and be passively guided by the human. For impedance measurements, a set of nine subjects perform 12 repetitions of airbrush painting, drawing a straight-line on a cartoon horizontally placed on a table, while passively moving the airbrush mounted on the robot's end-point. We measure hand impedance during the painting task by generating sudden and brief external forces with the robot. The results show that on average the dominant hand displays larger impedance than the nondominant in the directions perpendicular to the painting line. We find the most significant difference in the damping values in these directions. Based on this observation, we develop a "directional damping" scheme for robotic assistance and conduct a pilot study with 12 subjects to contrast airbrush painting with and without robotic assistance. Results show significant improvement in precision with both dominant and nondominant hands when using robotic assistance.

Published

2015

2. Understanding soft-tissue behavior for application to microlaparoscopic surface scan.

Author

Erden MS, Rosa B, Szewczyk J, and Morel G

Subjects

Animals, Cattle, Chickens, Image Processing, Computer-Assisted, Reproducibility of Results, Signal Processing, Computer-Assisted, Laparoscopy instrumentation, Laparoscopy methods, Liver physiology, Muscles physiology, Robotics methods

Abstract

This paper presents an approach for understanding the soft-tissue behavior in surface contact with a probe scanning the tissue. The application domain is confocal microlaparoscopy, mostly used for imaging the outer surface of the organs in the abdominal cavity. The probe is swept over the tissue to collect sequential images to obtain a large field of view with mosaicking. The problem we address is that the tissue also moves with the probe due to its softness; therefore, the resulting mosaic is not in the same shape and dimension as traversed by the probe. Our approach is inspired by the finger slip studies and adapts the idea of load-slip phenomenon that explains the movement of the soft part of the finger when dragged on a hard surface. We propose the concept of loading-distance and perform measurements on beef liver and chicken breast tissues. We propose a protocol to determine the loading-distance prior to an automated scan and introduce an approach to compensate the tissue movement in raster scans. Our implementation and experiments show that we can have an image mosaic of the tissue surface in a desired rectangular shape with this approach.

Published

2013

3. Building large mosaics of confocal edomicroscopic images using visual servoing.

Author

Rosa B, Erden MS, Vercauteren T, Herman B, Szewczyk J, and Morel G

Subjects

Animals, Biomechanical Phenomena, Chickens, Image Processing, Computer-Assisted instrumentation, Microscopy, Confocal instrumentation, Minimally Invasive Surgical Procedures, Muscle, Skeletal anatomy & histology, Robotics instrumentation, Video Recording, Image Processing, Computer-Assisted methods, Microscopy, Confocal methods, Robotics methods

Abstract

Probe-based confocal laser endomicroscopy provides real-time microscopic images of tissues contacted by a small probe that can be inserted in vivo through a minimally invasive access. Mosaicking consists in sweeping the probe in contact with a tissue to be imaged while collecting the video stream, and process the images to assemble them in a large mosaic. While most of the literature in this field has focused on image processing, little attention has been paid so far to the way the probe motion can be controlled. This is a crucial issue since the precision of the probe trajectory control drastically influences the quality of the final mosaic. Robotically controlled motion has the potential of providing enough precision to perform mosaicking. In this paper, we emphasize the difficulties of implementing such an approach. First, probe-tissue contacts generate deformations that prevent from properly controlling the image trajectory. Second, in the context of minimally invasive procedures targeted by our research, robotic devices are likely to exhibit limited quality of the distal probe motion control at the microscopic scale. To cope with these problems visual servoing from real-time endomicroscopic images is proposed in this paper. It is implemented on two different devices (a high-accuracy industrial robot and a prototype minimally invasive device). Experiments on different kinds of environments (printed paper and ex vivo tissues) show that the quality of the visually servoed probe motion is sufficient to build mosaics with minimal distortion in spite of disturbances.

Published

2013

4. Reaching and Grasping of Objects by Humanoid Robots Through Visual Servoing

Author

Ardón, Paola, Dragone, Mauro, Erden, Mustafa Suphi, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Prattichizzo, Domenico, editor, Shinoda, Hiroyuki, editor, Tan, Hong Z., editor, Ruffaldi, Emanuele, editor, and Frisoli, Antonio, editor

Published

2018

5. Anomaly Detection Methods in Autonomous Robotic Missions.

Author

Chirayil Nandakumar, Shivoh, Mitchell, Daniel, Erden, Mustafa Suphi, Flynn, David, and Lim, Theodore

Subjects

INTRUSION detection systems (Computer security), ROBOTICS, AUTONOMOUS robots, RESEARCH & development

Abstract

Since 2015, there has been an increase in articles on anomaly detection in robotic systems, reflecting its growing importance in improving the robustness and reliability of the increasingly utilized autonomous robots. This review paper investigates the literature on the detection of anomalies in Autonomous Robotic Missions (ARMs). It reveals different perspectives on anomaly and juxtaposition to fault detection. To reach a consensus, we infer a unified understanding of anomalies that encapsulate their various characteristics observed in ARMs and propose a classification of anomalies in terms of spatial, temporal, and spatiotemporal elements based on their fundamental features. Further, the paper discusses the implications of the proposed unified understanding and classification in ARMs and provides future directions. We envisage a study surrounding the specific use of the term anomaly, and methods for their detection could contribute to and accelerate the research and development of a universal anomaly detection system for ARMs. [ABSTRACT FROM AUTHOR]

Published

2024

6. A Robotic Experimental Setup with a Stewart Platform to Emulate Underwater Vehicle-Manipulator Systems.

Author

Cetin, Kamil, Tugal, Harun, Petillot, Yvan, Dunnigan, Matthew, Newbrook, Leonard, and Erden, Mustafa Suphi

Subjects

PARALLEL robots, WATER currents, SUBMERSIBLES, EMULATION software, MANIPULATORS (Machinery), TORQUEMETERS, ROBOTICS, ACQUISITION of data

Abstract

This study presents an experimental robotic setup with a Stewart platform and a robot manipulator to emulate an underwater vehicle–manipulator system (UVMS). This hardware-based emulator setup consists of a KUKA IIWA14 robotic manipulator mounted on a parallel manipulator, known as Stewart Platform, and a force/torque sensor attached to the end-effector of the robotic arm interacting with a pipe. In this setup, we use realistic underwater vehicle movements either communicated to a system in real-time through 4G routers or recorded in advance in a water tank environment. In addition, we simulate both the water current impact on vehicle movement and dynamic coupling effects between the vehicle and manipulator in a Gazebo-based software simulator and transfer these to the physical robotic experimental setup. Such a complete setup is useful to study the control techniques to be applied on the underwater robotic systems in a dry lab environment and allows us to carry out fast and numerous experiments, circumventing the difficulties with performing similar experiments and data collection with actual underwater vehicles in water tanks. Exemplary controller development studies are carried out for contact management of the UVMS using the experimental setup. [ABSTRACT FROM AUTHOR]

Published

2022

7. Robotic training for hand movements during manual welding with real-time alarm feedback.

Author

Erden, Mustafa Suphi and Billard, Aude

Abstract

Purpose – The purpose of this study is to develop a robotic training system for the hand movements during manual welding. The system provides real-time notice-feedback with sound or light alarms, whenever the welding hand vibrates beyond the nominal level observed with professional welders. Design/methodology/approach – The large variations of hand movements are detected by monitoring the deviation of the tool position from a smooth curve estimated in real time by a Kalman filter. An alarm is generated in the form of a flashing light or beep sound whenever the deviations exceed a predetermined threshold. The performance of hand movements is measured in terms of the variations of the position data. Twelve novice and five professional welders took part in the experiments and answered a questionnaire that assessed the usability and work load of the system. Findings – Compared to the sound alarms, the light alarms resulted in a larger and statistically significant decrease in the variation of hand movements of the novice welders and brought the level of variation close to that of the professional welders. The alarms did not result in a significant decrease in the variation of hand movements of the professional welders. The responses to the questionnaire indicated that both professional and novice welders found the system useful and they did not experience any significant work load. Social implications – The system developed in this study can ease the training of novice welders, by speeding up the learning and reducing the need for human tutors. Originality/value – This study is first to provide real-time notice-feedback for training while manual welding, based on a comparison of the performances of novice and professional welders. [ABSTRACT FROM AUTHOR]

Published

2015

8. Hand Impedance Measurements During Interactive Manual Welding With a Robot.

Author

Erden, Mustafa Suphi and Billard, Aude

Subjects

*IMPEDANCE control, *MECHANICAL impedance, *INDUSTRIAL robots, *HUMAN-robot interaction, *HUMAN-machine systems, *ROBOTICS

Abstract

This paper presents a study of hand impedance measurements comparatively across ten professional and 14 novice manual welders, when they are performing tungsten inert gas (TIG) welding interactively with the KUKA lightweight robot arm (LWR). The results show that hand impedance differs across professional and novice welders. The welding torch is attached to the KUKA LWR, which is admittance controlled via a force sensor to give the feeling of a free floating mass at its end-effector. The subjects perform TIG welding on 1.5-mm-thick stainless steel plates by manipulating the torch. Impedance is measured by introducing external force disturbances and fitting a mass–damper–spring model to human hand reactions. The quality of welding is measured using the variance of the position signals above 0.1 Hz. Professional welders demonstrate less variance and, in general, apply larger hand impedance (larger damping and stiffness) than the novice welders. The variance of position during nominal welding is minimal for both professional and novice welders in the direction perpendicular to the welding line in the plane of the plate, which is the most important direction for the quality of the weld. For both professional and novice welders, the mass and damping values are largest in this direction compared with the other two directions. Professional welders demonstrate larger damping than the novice welders in this direction. [ABSTRACT FROM PUBLISHER]

Published

2015

9. Human-Intent Detection and Physically Interactive Control of a Robot Without Force Sensors.

Author

Erden, Mustafa Suphi and Tomiyama, Tetsuo

Subjects

*ROBOT control systems, *ROBOTICS, *ELECTRIC impedance, *TACTILE sensors, *HUMAN-robot interaction, *SWITCHING theory

Abstract

In this paper, a physically interactive control scheme is developed for a manipulator robot arm. The human touches the robot and applies force in order to make it behave as he/she likes. The communication between the robot and the human is maintained by a physical contact with no sensors. The intent of the human is estimated by observing the change in control effort. The robot receives the estimated human intent and updates its position reference accordingly. The developed method uses the principle of conservation of zero momentum for position-controlled systems. A switching scheme is developed that goes between the modes of pure impedance control with a fixed-position reference and interactive control under human intent. The switching mechanism uses neither a physical switch nor a sensor; it observes the human intent and puts the robot into interactive mode, if there is any. When the human intent disappears, the robot goes into the pure-impedance-control mode, thus stabilizing in the left position. [ABSTRACT FROM AUTHOR]

Published

2010