Abstract:
Hand is the main environmental manipulator for humans. Therefore, any accidental lost
of hand does a great harm in amputee life. Only choice left that he or she is using
prosthesis, which is dated back to ancient time. Due to their usefulness prosthesis is also
used in modern days. Now-a-day robotic rehabilitation opens a new era in the field of
prosthesis. They are more capable of doing things compared to their ancestors.
However, to duplicate the complex work of hand, the robotic hand is needed to
complete two basic operations first one is predict the angular displacement and another
one is the estimation of force. Estimation of force is essential for instance when drinking
from a glass, one needs to apply sufficient grip force to prevent the object from slipping
Out of the hand. In addition, one needs to control the total torque exerted on the glass
such that the glass remains vertical. Usually, the requirements for grip force
stabilization allow for some laxity, while the requirements for total torque production
are highly specified. The grip force needs only to be larger than the slip threshold and
smaller than the force that would break the object. Different researchers used different
approach to solve this problem like body-powered prostheses, force-sensitive resistors.
Nevertheless, when it comes to rehabilitation of amputee they are not up to the mark in
practical field.Using of Electromyography (EMG) in the robotic rehabilitation shows some hope.
Muscle tissue conducts electrical potentials similar to the way nerves do and the name
given to these electrical signals is the muscle action potential. A muscle is composed of
bundles of specialized cells capable of contraction and relaxation. The primary function
of these specialized cells is to generate forces, movements and the ability to
communicate such as speech or writing or other modes of expression. The skeletal
muscle tissue is attached to the bone and its contraction is responsible for supporting
and moving the skeleton. The contraction of skeletal muscle is initiated by impulses in
the neurons to the muscle and is usually under voluntary control. Skeletal muscle fibers
are well-supplied with neurons for its contraction. This depolarization, accompanied by
a movement of ions, generates an electric field near each muscle fiber. An EMG signal
is the train of Motor Unit Action Potential (MUAP) showing the muscle response to
neural stimulation. There is a clear relationship between force and EMG. The higher the
muscle force, the higher EMG level is developed. Clench force estimation is highly
desirable in the field of prosthesis hand. It is one of the most used postures among
different types of postures. In this thesis, the author proposes to estimate the clench
force using two types of Surface Electromyography (SEMG): rectified SEMG and
integrated SEMG. An Artificial Neural Network (ANN) is used to estimate the force
from SEMG. For weight adjustment of the estimator Levenberg-Marquardt (L-M) back
propagation algorithm is used. The proposed network is trained and tested using SEMG
recorded from five subjects. The estimation result clearly shows that integrated SEMG
performed 3.53 times better than rectified SEMG in the case of cross correlation
coefficient. So integrated SEMG is recommended for clench force estimation. A neural
number based experiment is also done to find the optimal number of neurons in hidden
layer, which are five neurons as previously described neural network. In addition to that,
these result also compared with Support Vector Machine (S\TM). Same result is found
for integrated SEMG. In the case of rectified SEMG ANN is more suitable than SVM.
Description:
This thesis is submitted to the Department of Biomedical Engineering, Khulna University of Engineering & Technology in partial fulfillment of the requirements for the degree of Master of Science in Biomedical Engineering, September 2012.
Cataloged from PDF Version of Thesis.
Includes bibliographical references (pages 92-98).