Jeevan K. Pant scite author profile

A new algorithm for the reconstruction of electrocardiogram (ECG) signals and a dictionary learning algorithm for the enhancement of its reconstruction performance for a class of signals are proposed. The signal reconstruction algorithm is based on minimizing the lp pseudo-norm of the second-order difference, called as the lp(2d) pseudo-norm, of the signal. The optimization involved is carried out using a sequential conjugate-gradient algorithm. The dictionary learning algorithm uses an iterative procedure wherein a signal reconstruction and a dictionary update steps are repeated until a convergence criterion is satisfied. The signal reconstruction step is implemented by using the proposed signal reconstruction algorithm and the dictionary update step is implemented by using the linear least-squares method. Extensive simulation results demonstrate that the proposed algorithm yields improved reconstruction performance for temporally correlated ECG signals relative to the state-of-the-art lp(1d)-regularized least-squares and Bayesian learning based algorithms. Also for a known class of signals, the reconstruction performance of the proposed algorithm can be improved by applying it in conjunction with a dictionary obtained using the proposed dictionary learning algorithm.

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Compressive Sensing of Foot Gait Signals and Its Application for the Estimation of Clinically Relevant Time Series

Pant

Krishnan

2016

IEEE Trans. Biomed. Eng.

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A new signal reconstruction algorithm for compressive sensing based on the minimization of a pseudonorm which promotes block-sparse structure on the first-order difference of the signal is proposed. Involved optimization is carried out by using a sequential version of Fletcher-Reeves' conjugate-gradient algorithm, and the line search is based on Banach's fixed-point theorem. The algorithm is suitable for the reconstruction of foot gait signals which admit block-sparse structure on the first-order difference. An additional algorithm for the estimation of stride-interval, swing-interval, and stance-interval time series from the reconstructed foot gait signals is also proposed. This algorithm is based on finding zero crossing indices of the foot gait signal and using the resulting indices for the computation of time series. Extensive simulation results demonstrate that the proposed signal reconstruction algorithm yields improved signal-to-noise ratio and requires significantly reduced computational effort relative to several competing algorithms over a wide range of compression ratio. For a compression ratio in the range from 88% to 94%, the proposed algorithm is found to offer improved accuracy for the estimation of clinically relevant time-series parameters, namely, the mean value, variance, and spectral index of stride-interval, stance-interval, and swing-interval time series, relative to its nearest competitor algorithm. The improvement in performance for compression ratio as high as 94% indicates that the proposed algorithms would be useful for designing compressive sensing-based systems for long-term telemonitoring of human gait signals.

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Jeevan K. Pant

New Improved Algorithms for Compressive Sensing Based on $\ell_{p}$ Norm

Reconstruction of sparse signals by minimizing a re-weighted approximate ℓ<inf>0</inf>-norm in the null space of the measurement matrix

Unconstrained regularized ℓ<inf>p</inf>-norm based algorithm for the reconstruction of sparse signals

Compressive Sensing of Electrocardiogram Signals by Promoting Sparsity on the Second-Order Difference and by Using Dictionary Learning

Compressive Sensing of Foot Gait Signals and Its Application for the Estimation of Clinically Relevant Time Series

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About

Jeevan K. Pant

New Improved Algorithms for Compressive Sensing Based on $\ell_{p}$ Norm

Reconstruction of sparse signals by minimizing a re-weighted approximate &#x2113;<inf>0</inf>-norm in the null space of the measurement matrix

Unconstrained regularized &#x2113;<inf>p</inf>-norm based algorithm for the reconstruction of sparse signals

Compressive Sensing of Electrocardiogram Signals by Promoting Sparsity on the Second-Order Difference and by Using Dictionary Learning

Compressive Sensing of Foot Gait Signals and Its Application for the Estimation of Clinically Relevant Time Series

Contact Info

Product

Resources

About

Reconstruction of sparse signals by minimizing a re-weighted approximate ℓ<inf>0</inf>-norm in the null space of the measurement matrix

Unconstrained regularized ℓ<inf>p</inf>-norm based algorithm for the reconstruction of sparse signals