Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes
Feeding is an activity of daily living (ADL) that many struggle to perform independently. Thus, there has been increased research into assistive feeding using robotic arms in the recent past. In works such as Sundaresan et al. [1], a robotic arm is used in conjunction with a vision sensor and for...
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sg-ntu-dr.10356-1686992023-06-17T16:51:31Z Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes Shrivastava, Samruddhi Ang Wei Tech School of Mechanical and Aerospace Engineering Rehabilitation Research Institute of Singapore (RRIS) WTAng@ntu.edu.sg Engineering::Mechanical engineering Feeding is an activity of daily living (ADL) that many struggle to perform independently. Thus, there has been increased research into assistive feeding using robotic arms in the recent past. In works such as Sundaresan et al. [1], a robotic arm is used in conjunction with a vision sensor and force-torque sensors to generate fork skewering strategies for various foods. However, force-torque sensors are expensive and have a lengthy and complicated fabrication process. In this work, the classifier algorithm created by Sundaresan et al. [1], HapticVisualNet, is evaluated, using touch sensors instead of force-torque sensors. This is because touch sensors are significantly cheaper and easier to manufacture than force-torque sensors. The touch sensors were created by researchers at the Leong Research Group (Soft Electronics Lab) at NTU. First, these touch sensors are integrated into the hardware of the circuit and robotic system. Their performance is then evaluated, and it is observed that they can distinguish between soft food, such as bananas, and hard foods, such as apples. A food-skewering touch sensor dataset is created to train HapticVisualNet. This strategy was successful in achieving comparable accuracy to force-torque sensors when used with touch sensors in real-time food experimentation. Thus, this is a feasible system that is more suited to an assisted living context. Some limitations of this approach are also discussed along with suggestions for future improvements. Bachelor of Engineering (Mechanical Engineering) 2023-06-15T07:27:49Z 2023-06-15T07:27:49Z 2023 Final Year Project (FYP) Shrivastava, S. (2023). Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/168699 https://hdl.handle.net/10356/168699 en application/pdf Nanyang Technological University |
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Engineering::Mechanical engineering Shrivastava, Samruddhi Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| description |
Feeding is an activity of daily living (ADL) that many struggle to perform independently. Thus,
there has been increased research into assistive feeding using robotic arms in the recent past. In
works such as Sundaresan et al. [1], a robotic arm is used in conjunction with a vision sensor and
force-torque sensors to generate fork skewering strategies for various foods. However, force-torque
sensors are expensive and have a lengthy and complicated fabrication process. In this work, the
classifier algorithm created by Sundaresan et al. [1], HapticVisualNet, is evaluated, using touch
sensors instead of force-torque sensors. This is because touch sensors are significantly cheaper and
easier to manufacture than force-torque sensors. The touch sensors were created by researchers at
the Leong Research Group (Soft Electronics Lab) at NTU. First, these touch sensors are integrated
into the hardware of the circuit and robotic system. Their performance is then evaluated, and it
is observed that they can distinguish between soft food, such as bananas, and hard foods, such as
apples. A food-skewering touch sensor dataset is created to train HapticVisualNet. This strategy
was successful in achieving comparable accuracy to force-torque sensors when used with touch
sensors in real-time food experimentation. Thus, this is a feasible system that is more suited to an
assisted living context. Some limitations of this approach are also discussed along with suggestions
for future improvements. |
| author2 |
Ang Wei Tech |
| author_facet |
Ang Wei Tech Shrivastava, Samruddhi |
| format |
Final Year Project |
| author |
Shrivastava, Samruddhi |
| author_sort |
Shrivastava, Samruddhi |
| title |
Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| title_short |
Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| title_full |
Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| title_fullStr |
Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| title_full_unstemmed |
Using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| title_sort |
using touch sensors to adapt skewering approach of robot arm for assistive feeding purposes |
| publisher |
Nanyang Technological University |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/168699 |
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