Abstract
Purpose Due to the continuous and rapid evolution of telecommunication equipment, the demand for more efficient and noise-robust detection of dual-tone multi-frequency (DTMF) signals is most significant. Design/methodology/approach A novel machine learning-based approach to detect DTMF tones affected by noise, frequency and time variations by employing the k-nearest neighbour (KNN) algorithm is proposed. The features required for training the proposed KNN classifier are extracted using Goertzel's algorithm that estimates the absolute discrete Fourier transform (DFT) coefficient values for the fundamental DTMF frequencies with or without considering their second harmonic frequencies. The proposed KNN classifier model is configured in four different manners which differ in being trained with or without augmented data, as well as, with or without the inclusion of second harmonic frequency DFT coefficient values as features. Findings It is found that the model which is trained using the augmented data set and additionally includes the absolute DFT values of the second harmonic frequency values for the eight fundamental DTMF frequencies as the features, achieved the best performance with a macro classification F1 score of 0.980835, a five-fold stratified cross-validation accuracy of 98.47% and test data set detection accuracy of 98.1053%. Originality/value The generated DTMF signal has been classified and detected using the proposed KNN classifier which utilizes the DFT coefficient along with second harmonic frequencies for better classification. Additionally, the proposed KNN classifier has been compared with existing models to ascertain its superiority and proclaim its state-of-the-art performance.
Highlights
While telecommunication receivers have gotten exceedingly better with time, there is still a degree of unreliability associated with analog detectors
It is observed that the proposed k-nearest neighbour (KNN) classifier achieved the maximum classification accuracy of 98.1053% whilst attempting to detect dual-tone multi-frequency (DTMF) signals in a noisy environment
All the models have been evaluated with five-fold stratified validation accuracy, precision, recall as well as the F1 score with the help of the plotted confusion matrices
Summary
While telecommunication receivers have gotten exceedingly better with time, there is still a degree of unreliability associated with analog detectors. This is due to various factors such as the circulation of outdated transmitters alongside noise and frequency variations that are extant in analog signals. Single tone frequency line pulsing was used in telephone equipment [1], thanks to rapid technological advancements in the recent past, wireless networks have been moving towards digitization where all signals are considered equal. The dual-tone multi-frequency (DTMF) signal is utilized in many applications in recent past [2,3,4,5,6,7]. The night vision camera has been controlled by DTMF signal and Global
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