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Following papers were published based on the results of this research project.
I . C. Premarathna, A. Kulasekera, D. Chathuranga and T. Lalitharatne, "Development of Wearable Fingertip Tactile Display Driven by Bowden Cables," 2019 Moratuwa Engineering Research Conference (MERCon), 2019, pp. 621-626, doi: 10.1109/MERCon.2019.8818899. Link: https://ieeexplore.iece.org/abstract/document/8818899
2. C. Premarathna, A. Kulasekera, D. Chathuranga and T. Lalitharatne, "A Novel Fabrication Method for Rapid Prototyping of Soft Structures with Embedded Pneumatic Channels," 2019 Moratuwa Engineering Research Conference (MERCon), 2019, pp. 430-435, doi: 10.1109/MERCon.2019.8818891. Link: https://ieeexplore.iece.org/abstract/document/8818891
3. C. P. Premarathna, I. Ruhunage, D. S. Chathuranga and T. D. Lalitharatne, "Haptic Feedback System for an Artificial Prosthetic Hand for Object Grasping and Slip Detection: A Preliminary Study," 2018 IEEE International Conference on Robotics and Biomimetics (ROBIO), 2018, pp. 2304-2309, doi: 10.1109/ROBI0.2018.8665044. Link:
https://ieeexplore.iece.org/abstract/document/8665044
4. C. P. Premarathna, D. S. Chathuranga and T. D. Lalitharatne, "Fabrication of a soft tactile display based on pneumatic balloon actuators and voice coils: Evaluation of force and vibration sensations," 2017 IEEE/SICE International Symposium on System Integration (SII), 2017, pp. 763-768, doi: 10.1109/SII.2017.8279314. Link:https://ieeexplore.iece.org/abstract/document/8279314 |
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After seeing and hearing (vision and audition), tactile sensing (feeling of touch) is the third most utilized sensation. We use our fingertips to examine properties of objects such as weight (heavy or light), shape (spherical/round or shapes with edges and corners etc.), and texture (smooth or rough). In many situations we can identify and discriminate objects by touch only. Furthermore, tactile sensing is needed for controlling the gripping force of objects and object manipulation tasks. An example would be holding an egg without dropping. We apply just enough grip force to hold the egg and careful not to crush the shell. This is possible due to the ability of the tactile sensors in the fingertips to detect micro slips occurring at the common surface of the object and the fingertips. The adjustment of its grip force is controlled by the detection of insipient slip. This tactile sensing capability is required for both tele-operated robot systems and artificial prosthetic hands that has actuated fingers for grasping and manipulation. However, limited
research has been conducted to address these issues. Researchers have tried to copy the abilities of human fingertips to robots. However, only few research has emerged with usable technologies due to the complexity of the tactile system and its information processing. Therefore, this project is conducted mainly to develop a biomimetic tactile sensing system and its control strategy for the use in prosthetic hands and a tele operated robot systems. The project proposed a tactile
sensing system and an accompanying haptic feedback systems developed using soft materials. The tactile sensors were made using magnets, hall sensors and soft overlays. The tactile arrays were used to measure tactile data while haptic feedback system made from magnets, voice coils and soft material overlays transmitted the tactile information back to the skin. The grant was successful to develop soft tactile sensor array and a soft haptic device. These devices were
utilized in a prosthetic arm to transmit tactile data to the wearer of the prosthetic arm. This tactile data was used to manipulate an object from the prosthetic hand.. |
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