scholarly journals Improving the Accuracy in Classification of Blood Pressure from Photoplethysmography Using Continuous Wavelet Transform and Deep Learning

2021 ◽  
Vol 2021 ◽  
pp. 1-9
Author(s):  
Jiaze Wu ◽  
Hao Liang ◽  
Changsong Ding ◽  
Xindi Huang ◽  
Jianhua Huang ◽  
...  
Keyword(s):  
Blood Pressure ◽  
Deep Learning ◽  
Wavelet Transform ◽  
Continuous Wavelet Transform ◽  
Heart Association ◽  
Segment Length ◽  
Continuous Wavelet ◽  
Real Time Processing ◽  
Category Labels ◽  
Promising Solution

Background. Continuous wavelet transform (CWT) based scalogram can be used for photoplethysmography (PPG) signal transformation to classify blood pressure (BP) with deep learning. We aimed to investigate the determinants that can improve the accuracy of BP classification based on PPG and deep learning and establish a better algorithm for the prediction. Methods. The dataset from PhysioNet was accessed to extract raw PPG signals for testing and its corresponding BPs as category labels. The BP category of normal or abnormal followed the criteria of the 2017 American College of Cardiology/American Heart Association (ACC/AHA) Hypertension Guidelines. The PPG signals were transformed into 224  ∗  224  ∗  3-pixel scalogram via different CWTs and segment units. All of them are fed into different convolutional neural networks (CNN) for training and validation. The receiver-operating characteristic and loss and accuracy curves were used to evaluate and compare the performance of different methods. Results. Both wavelet type and segment length could affect the accuracy, and Cgau1 wavelet and segment-300 revealed the best performance (accuracy 90%) without obvious overfitting. This method performed better than previously reported MATLAB Morse wavelet transformed scalogram on both of our proposed CNN and CNN-GoogLeNet. Conclusions. We have established a new algorithm with high accuracy to predict BP classification from PPG via matching of CWT type and segment length, which is a promising solution for rapid prediction of BP classification from real-time processing of PPG signal on a wearable device.

Instantaneous Frequencies of Continuous Blood Pressure a Comparison of the Power Spectrum, the Continuous Wavelet Transform and the Hilbert–Huang Transform

2017 ◽  
Vol 09 (04) ◽  
pp. 1750009
Author(s):  
Kathrine Knai ◽  
Geir Kulia ◽  
Marta Molinas ◽  
Nils Kristian Skjaervold
Keyword(s):  
Blood Pressure ◽  
Wavelet Transform ◽  
Power Spectrum ◽  
Continuous Wavelet Transform ◽  
Continuous Wavelet ◽  
Frequency Shifts ◽  
Hilbert Huang Transform ◽  
Frequency Components ◽  
Instantaneous Frequencies ◽  
Continuous Blood Pressure

Continuous biological signals, like blood pressure recordings, exhibit nonlinear and nonstationary properties which must be considered during their analysis. Heart rate variability analyses have identified several frequency components and their autonomic origin. There is need for more knowledge on the time-changing properties of these frequencies. The power spectrum, continuous wavelet transform and Hilbert–Huang transform are applied on a continuous blood pressure signal to investigate how the different methods compare to each other. The Hilbert–Huang transform shows high ability to analyze such data, and can, by identifying instantaneous frequency shifts, provide new insights into the nature of these kinds of data.

Analysis of blood pressure dynamics in male and female rats using the continuous wavelet transform

2009 ◽  
Vol 30 (7) ◽  
pp. 707-717 ◽  
Author(s):  
A N Pavlov ◽  
A A Anisimov ◽  
O V Semyachkina-Glushkovskaya ◽  
E G Matasova ◽  
J Kurths
Keyword(s):  
Blood Pressure ◽  
Wavelet Transform ◽  
Continuous Wavelet Transform ◽  
Female Rats ◽  
Continuous Wavelet ◽  
Male And Female ◽  
Male And Female Rats ◽  
Pressure Dynamics

scholarly journals Continuous Wavelet Transform of Schwartz Distributions in DL2′(Rn), n ≥ 1

Symmetry ◽  
2021 ◽  
Vol 13 (7) ◽  
pp. 1106
Author(s):  
Jagdish N. Pandey
Keyword(s):  
Wavelet Transform ◽  
Function Space ◽  
Continuous Wavelet Transform ◽  
Inversion Formula ◽  
Continuous Wavelet ◽  
The Real ◽  
Schwartz Distributions ◽  
Distributional Sense ◽  
Wavelet Inversion

We define a testing function space DL2(Rn) consisting of a class of C∞ functions defined on Rn, n≥1 whose every derivtive is L2(Rn) integrable and equip it with a topology generated by a separating collection of seminorms {γk}|k|=0∞ on DL2(Rn), where |k|=0,1,2,… and γk(ϕ)=∥ϕ(k)∥2,ϕ∈DL2(Rn). We then extend the continuous wavelet transform to distributions in DL2′(Rn), n≥1 and derive the corresponding wavelet inversion formula interpreting convergence in the weak distributional sense. The kernel of our wavelet transform is defined by an element ψ(x) of DL2(Rn)∩DL1(Rn), n≥1 which, when integrated along each of the real axes X1,X2,…Xn vanishes, but none of its moments ∫Rnxmψ(x)dx is zero; here xm=x1m1x2m2⋯xnmn, dx=dx1dx2⋯dxn and m=(m1,m2,…mn) and each of m1,m2,…mn is ≥1. The set of such wavelets will be denoted by DM(Rn).

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