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Design and Development of an Imitation Astuteness for Single Arm Amputee using Wireless Sensor Network


Affiliations
1 Department of Computer Science, Annai Fathima College of Arts and Science, India
2 Department of Commerce, Madurai Kamaraj University Constituent College- Sattur, India
     

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In this paper, present a wearable detecting glove with inserted hetero-central element optic nerve sensors that identify finger flexion to realize unconstrained hand movement checking. The hetero-main element sensor is fit to the wearable detecting glove since it's fit for optical force based estimations with great security and repeatability utilizing single-mode transmission filaments and is unaffected by temperature variances. The hetero-center sensor components are situated on the back of the hand so as that they are not influenced by arbitrary wrinkles inside the glove at the joints. Subsequently, the hetero-center flexion sensor after adjustment is equipped for recognizing the joint edges of the fingers regardless of contrasts close by size, and in this way the hetero-center detecting strategy empowers the distinguishing glove to be worked with a base number of sensor centers. The optical loss performance of the hetero-core sensors reveals monotonic characteristics with regard to the flexion angle of joints. The optical loss is 1.35dB for a flexion angle of roughly 97.2 with accuracy of 0.89◦ within the detected flexion angle. Ongoing hand movement catch was exhibited by methods for the proposed detecting glove without limiting normal human conduct.

Keywords

Hand Motion Monitoring, Hetero-Core Fiber, Glass Fiber Measurement Applications, Unconstrained and Wearable.
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  • Design and Development of an Imitation Astuteness for Single Arm Amputee using Wireless Sensor Network

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Authors

S. Ravichandran
Department of Computer Science, Annai Fathima College of Arts and Science, India
N. Jeyakumar
Department of Commerce, Madurai Kamaraj University Constituent College- Sattur, India

Abstract


In this paper, present a wearable detecting glove with inserted hetero-central element optic nerve sensors that identify finger flexion to realize unconstrained hand movement checking. The hetero-main element sensor is fit to the wearable detecting glove since it's fit for optical force based estimations with great security and repeatability utilizing single-mode transmission filaments and is unaffected by temperature variances. The hetero-center sensor components are situated on the back of the hand so as that they are not influenced by arbitrary wrinkles inside the glove at the joints. Subsequently, the hetero-center flexion sensor after adjustment is equipped for recognizing the joint edges of the fingers regardless of contrasts close by size, and in this way the hetero-center detecting strategy empowers the distinguishing glove to be worked with a base number of sensor centers. The optical loss performance of the hetero-core sensors reveals monotonic characteristics with regard to the flexion angle of joints. The optical loss is 1.35dB for a flexion angle of roughly 97.2 with accuracy of 0.89◦ within the detected flexion angle. Ongoing hand movement catch was exhibited by methods for the proposed detecting glove without limiting normal human conduct.

Keywords


Hand Motion Monitoring, Hetero-Core Fiber, Glass Fiber Measurement Applications, Unconstrained and Wearable.

References