A novel algorithm based on discrete Hermite functions achieved higher compression ratios for QRS complexes compared to continuous Hermite functions and other standard transforms.
A novel algorithm using discrete Hermite functions provides superior compression of ECG QRS complexes compared to traditional transform methods.
We propose a novel algorithm for the compression of ECG signals, in particular QRS complexes. The algorithm is based on the expansion of signals with compact support into a basis of discrete Hermite functions. These functions can be constructed by sampling continuous Hermite functions at specific sampling points. They form an orthogonal basis in the underlying signal space. The proposed algorithm relies on the theory of signal models based on orthogonal polynomials. We demonstrate that the constructed discrete Hermite functions have important ad- vantages compared to continuous Hermite functions, which have previously been suggested for the compression of QRS complexes. Our algorithm achieves higher compression ratios compared with previously reported algorithms based on continuous Hermite functions, discrete Fourier, cosine, or wavelet transforms.
Sandryhaila et al. (Thu,) conducted a other in ECG signal compression. Discrete Hermite functions algorithm vs. Continuous Hermite functions, discrete Fourier, cosine, or wavelet transforms was evaluated on Compression ratio. A novel algorithm based on discrete Hermite functions achieved higher compression ratios for QRS complexes compared to continuous Hermite functions and other standard transforms.