Your search keyword '"SAMARAKOON, S. M. BHAGYA P."' showing total 5 results

1. Toward obstacle-specific morphology for a reconfigurable tiling robot

Author

Samarakoon, S. M. Bhagya P., Muthugala, M. A. Viraj J., and Elara, Mohan Rajesh

Published

2023

2. Reconfigurable Robotic Exercising Companion.

Author

Sachinthana, W. K. R., Wijegunawardana, I. D., Samarakoon, S. M. Bhagya P., Muthugala, M. A. Viraj J., and Elara, Mohan Rajesh

Subjects

ROBOT design & construction, FUZZY logic, WELL-being, ROBOTICS, ROBOTS

Abstract

Regular exercise plays a crucial role in promoting overall well-being in today's lifestyle. However, individuals often find it challenging to properly execute exercises, including maintaining correct postures and appropriate movement speeds. Robotic companions have emerged as potential solutions to assist and motivate users during exercise sessions. This research paper proposes a novel robot companion designed for exercise scenarios using a reconfigurable robot. In contrast to existing non-reconfigurable robotic companions, the use of a reconfigurable robot provides added flexibility in generating emotions. The system incorporates a module that utilizes fuzzy logic to evaluate the correctness of exercise performance based on posture variations and movement speeds. The robot generates emotions and provides feedback to users based on the exercise correctness score. The robot expresses emotions through reconfigurations, motion patterns, and variations in robot speed. This emotion-based feedback could be helpful for creating engaging and interactive exercise experiences. Apart from emotion generation, the robot utilizes vocal cues as feedback. Experimental results validate the effectiveness of the proposed system in evaluating exercise correctness and demonstrating meaningful emotion transitions. The findings of this work contribute to the development of innovative robotic companions for improving exercise adherence and overall well-being. [ABSTRACT FROM AUTHOR]

Published

2024

3. Insights from autonomy trials of a self‐reconfigurable floor‐cleaning robot in a public food court.

Author

Wijegunawardana, I. D., Muthugala, M. A. Viraj J., Samarakoon, S. M. Bhagya P., Hua, Ong Jun, Padmanabha, Saurav Ghante Anantha, and Elara, Mohan Rajesh

Subjects

FOOD courts, ROBOTIC path planning, AUTONOMOUS robots, FIELD research, POTENTIAL field method (Robotics), TRIALS (Law)

Abstract

As autonomous cleaning robots advance, we expect certain features, such as higher area coverage and robustness. To explore these features and their challenges, we need tools and strategies that allow us to develop them rapidly. In this paper, we present lessons learned and results while performing 3 months long field trials on the autonomy of a self‐reconfigurable floor‐cleaning robot. The autonomy here includes path planning and navigation of the robot for coverage in a public food court. The environment of the food court is often subjected to alterations due to human activities. One of the main contributions of this paper is proposing a task‐level execution system to deploy the cleaning robot in an actual use case scenario. We also provide in‐depth discussions on the solutions and the implementation strategies we found in accomplishing goals. These findings would be helpful in conducting autonomy development targeted for field deployments of self‐reconfigurable robots and cleaning robots. [ABSTRACT FROM AUTHOR]

Published

2024

4. Raptor: A Design of a Drain Inspection Robot.

Author

Muthugala, M. A. Viraj J., Palanisamy, Povendhan, Samarakoon, S. M. Bhagya P., Padmanabha, Saurav Ghante Anantha, Elara, Mohan Rajesh, and Terntzer, Dylan Ng

Subjects

ROBOTS, ROBOT design & construction, FUZZY logic, SUBSURFACE drainage

Abstract

Frequent inspections are essential for drains to maintain proper function to ensure public health and safety. Robots have been developed to aid the drain inspection process. However, existing robots designed for drain inspection require improvements in their design and autonomy. This paper proposes a novel design of a drain inspection robot named Raptor. The robot has been designed with a manually reconfigurable wheel axle mechanism, which allows the change of ground clearance height. Design aspects of the robot, such as mechanical design, control architecture and autonomy functions, are comprehensively described in the paper, and insights are included. Maintaining the robot's position in the middle of a drain when moving along the drain is essential for the inspection process. Thus, a fuzzy logic controller has been introduced to the robot to cater to this demand. Experiments have been conducted by deploying a prototype of the design to drain environments considering a set of diverse test scenarios. Experiment results show that the proposed controller effectively maintains the robot in the middle of a drain while moving along the drain. Therefore, the proposed robot design and the controller would be helpful in improving the productivity of robot-aided inspection of drains. [ABSTRACT FROM AUTHOR]

Published

2021

5. Modelling and Control of a Reconfigurable Robot for Achieving Reconfiguration and Locomotion with Different Shapes.

Author

Samarakoon, S. M. Bhagya P., Muthugala, M. A. Viraj J., Abdulkader, Raihan E., Si, Soh Wei, Tun, Thein T., and Elara, Mohan Rajesh

Subjects

*ROBOT control systems, *ROBOTS

Abstract

Area coverage is a crucial factor for a robot intended for applications such as floor cleaning, disinfection, and inspection. Robots with fixed shapes could not realize an adequate level of area coverage performance. Reconfigurable robots have been introduced to overcome the limitations of fixed-shape robots, such as accessing narrow spaces and cover obstacles. Although state-of-the-art reconfigurable robots used for coverage applications are capable of shape-changing for improving the area coverage, the reconfiguration is limited to a few predefined shapes. It has been proven that the ability of reconfiguration beyond a few shapes can significantly improve the area coverage performance of a reconfigurable robot. In this regard, this paper proposes a novel robot model and a low-level controller that can facilitate the reconfiguration beyond a small set of predefined shapes and locomotion per instructions while firmly maintaining the shape. A prototype of a robot that facilitates the aim mentioned above has been designed and developed. The proposed robot model and controller have been integrated into the prototype, and experiments have been conducted considering various reconfiguration and locomotion scenarios. Experimental results confirm the validity of the proposed model and controller during reconfiguration and locomotion of the robot. Moreover, the applicability of the proposed model and controller for achieving high-level autonomous capabilities has been proven. [ABSTRACT FROM AUTHOR]

Published

2021