Pulse baseline wander removal using wavelet approximation

K. Q. Wang; Li Sheng Xu; L. Wang; Z. G. Li; Y. Z. Li

doi:10.1109/cic.2003.1291228

Pulse baseline wander removal using wavelet approximation

K. Q. Wang
, Li Sheng Xu^*
, L. Wang
, Z. G. Li
, Y. Z. Li

^*Corresponding author for this work

Faculty of Computing

Harbin Institute of Technology

Research output: Contribution to journal › Conference article › peer-review

24 Scopus citations

Abstract

Pulse waveform is the key to the Traditional Chinese Pulse Diagnosis. However, its baseline wander introduced in the acquisition may result in misdiagnosis. What s more, recent advancements in the pulse variability analysis require more accuracy of baseline estimation. In this paper, a wavelet based cascaded adaptive filter (CAP) was presented to remove this drift. The CAP works in two stages. The first stage is a discrete Meyer wavelet approximation and the second stage is a cubic Spline estimation. The experimental results on 50 simulated and 200 real pulse signals demonstrate the powerful effect of CAF both in removing the baseline wander and in preserving the diagnostic information of pulse waveform, comparing with some traditional methods, such as cubic Spline estimation, morphology filter and Linear-phase FIR least-squares-error digital filter. In addition, this CAF is easy to be accomplished and needs no prior knowledge on pulse and its baseline drift.

Original language	English
Pages (from-to)	605-608
Number of pages	4
Journal	Computers in Cardiology
Volume	30
DOIs	https://doi.org/10.1109/cic.2003.1291228
State	Published - 2003
Event	Computers in Cardiology 2003 - Thessaloniki Chalkidiki, Greece Duration: 21 Sep 2003 → 24 Sep 2003

Access to Document

10.1109/cic.2003.1291228

Cite this

@article{044db1ba40af489e9646d8bd0adf22b2,

title = "Pulse baseline wander removal using wavelet approximation",

abstract = "Pulse waveform is the key to the Traditional Chinese Pulse Diagnosis. However, its baseline wander introduced in the acquisition may result in misdiagnosis. What s more, recent advancements in the pulse variability analysis require more accuracy of baseline estimation. In this paper, a wavelet based cascaded adaptive filter (CAP) was presented to remove this drift. The CAP works in two stages. The first stage is a discrete Meyer wavelet approximation and the second stage is a cubic Spline estimation. The experimental results on 50 simulated and 200 real pulse signals demonstrate the powerful effect of CAF both in removing the baseline wander and in preserving the diagnostic information of pulse waveform, comparing with some traditional methods, such as cubic Spline estimation, morphology filter and Linear-phase FIR least-squares-error digital filter. In addition, this CAF is easy to be accomplished and needs no prior knowledge on pulse and its baseline drift.",

author = "Wang, \{K. Q.\} and Xu, \{Li Sheng\} and L. Wang and Li, \{Z. G.\} and Li, \{Y. Z.\}",

year = "2003",

doi = "10.1109/cic.2003.1291228",

language = "英语",

volume = "30",

pages = "605--608",

journal = "Computers in Cardiology",

issn = "0276-6574",

publisher = "IEEE Computer Society",

note = "Computers in Cardiology 2003 ; Conference date: 21-09-2003 Through 24-09-2003",

}

TY - JOUR

T1 - Pulse baseline wander removal using wavelet approximation

AU - Wang, K. Q.

AU - Xu, Li Sheng

AU - Wang, L.

AU - Li, Z. G.

AU - Li, Y. Z.

PY - 2003

Y1 - 2003

N2 - Pulse waveform is the key to the Traditional Chinese Pulse Diagnosis. However, its baseline wander introduced in the acquisition may result in misdiagnosis. What s more, recent advancements in the pulse variability analysis require more accuracy of baseline estimation. In this paper, a wavelet based cascaded adaptive filter (CAP) was presented to remove this drift. The CAP works in two stages. The first stage is a discrete Meyer wavelet approximation and the second stage is a cubic Spline estimation. The experimental results on 50 simulated and 200 real pulse signals demonstrate the powerful effect of CAF both in removing the baseline wander and in preserving the diagnostic information of pulse waveform, comparing with some traditional methods, such as cubic Spline estimation, morphology filter and Linear-phase FIR least-squares-error digital filter. In addition, this CAF is easy to be accomplished and needs no prior knowledge on pulse and its baseline drift.

AB - Pulse waveform is the key to the Traditional Chinese Pulse Diagnosis. However, its baseline wander introduced in the acquisition may result in misdiagnosis. What s more, recent advancements in the pulse variability analysis require more accuracy of baseline estimation. In this paper, a wavelet based cascaded adaptive filter (CAP) was presented to remove this drift. The CAP works in two stages. The first stage is a discrete Meyer wavelet approximation and the second stage is a cubic Spline estimation. The experimental results on 50 simulated and 200 real pulse signals demonstrate the powerful effect of CAF both in removing the baseline wander and in preserving the diagnostic information of pulse waveform, comparing with some traditional methods, such as cubic Spline estimation, morphology filter and Linear-phase FIR least-squares-error digital filter. In addition, this CAF is easy to be accomplished and needs no prior knowledge on pulse and its baseline drift.

UR - https://www.scopus.com/pages/publications/4143070473

U2 - 10.1109/cic.2003.1291228

DO - 10.1109/cic.2003.1291228

M3 - 会议文章

AN - SCOPUS:4143070473

SN - 0276-6574

VL - 30

SP - 605

EP - 608

JO - Computers in Cardiology

JF - Computers in Cardiology

T2 - Computers in Cardiology 2003

Y2 - 21 September 2003 through 24 September 2003

ER -

Pulse baseline wander removal using wavelet approximation

Abstract

Access to Document

Other files and links

Fingerprint

Cite this