Prediksi Kekuatan Ujung Jari Berbasis Sinyal EMG Menggunakan Transfer Learning CNN VGG16 untuk Kontrol Genggam Robot Tangan
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Abstract
Loss of hand function due to amputation causes significant limitations in daily
activities, requiring a prosthetic system capable of producing proportional and
adaptive grip control. This study aims to develop a fingertip force prediction system
based on electromyography (EMG) signals using a Convolutional Neural Network
(CNN) approach with VGG16 and VGG19 architectures, as well as to compare fine
tuning and transfer learning strategies for robotic hand grip control. EMG signals
were recorded from subjects with healthy hands using MyoWare sensors, then
processed through preprocessing stages including filtering, windowing, and
transformation to the time-frequency domain using Short-Time Fourier Transform
(STFT). The spectrogram representation was converted into a 224×224 pixel RGB
image and used as input for the CNN model for the regression task of predicting
fingertip force, with actual force data obtained from a force sensitive resistor (FSR)
sensor. Model performance was evaluated through offline testing using cross
validation, statistical testing using ANOVA, and realtime online testing on a robotic
hand system. The test results show that the transfer learning approach tends to
produce higher determination coefficient (R²) values in cross validation testing,
with the best value reaching 0.90 in certain subjects, but followed by greater
prediction errors. Conversely, the fine tuning approach shows more stable
performance with lower RMSE and MAE values and better consistency between
subjects. In realtime testing, the model was able to directly follow the fingertip force
pattern under relatively stable EMG signal conditions, despite a decline in
performance due to signal variation and noise. Overall, the results of this study
show that the EMG spectrogram-based CNN approach can be used to model the
relationship between muscle activity and grip force and integrated into a real-time
robotic hand control system. These findings form the basis for the development of
more natural, adaptive, and responsive prosthetic hand systems tailored to
individual user characteristics.
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Reuploud Repository hasyim Juni 2026
Approved by Teddy
