Can We Find Deterministic Signatures in ECG and PCG Signals?

J. H. Oliveira, V. Ferreira, M. Coimbra

2015

Abstract

The first step in any non linear time series analysis, is to characterize signals in terms of periodicity, stationarity ,linearity and predictability. In this work we aim to find if PCG (phonocardiogram) and ECG (electrocardiogram) time series are generated by a deterministic system and not from a random stochastic process. If PCG and ECG are non-linear deterministic systems and they are not very contaminated with noise, data should be confined to a finite dimensional manifold, which means there are structures hidden under the signal that could be used to increase our knowledge in forecasting future values of the time series. A non-linear process can give rise to very complex dynamic behaviours, even though the underlying process is purely deterministic and probably low-dimensional. To test this hypothesis, we have generated 99 surrogates and then we compared the fitting capability of AR (auto-regressive) models on the original and surrogate data. The results show with a 99% of confidence level that PCG and ECG were generated by a deterministic process. We compared the fitting capability of an ECG and PCG to AR linear models, using a multi-channel approach. We make an assumption that if a signal is more linearly predictable than another one, it may adjust better to these AR linear models. The results showed that ECG is more linearly predictable (for both channels) than PCG, although a filtering step is needed for the first channel. Finally we show that the false nearest neighbour method is insufficient to identify the correct dimension of the attractor in the reconstructed state space for both PCG and ECG signals.

References

1. D. T. Kaplan and L.Glass, Phys. Rev. Lett 68, 427 (1992).
2. D. T. Kaplan and L.Glass, Phys. Rev. Lett 64, 431 (1993).
3. T. Schreiber and A.Schmitz, Phys. Rev. Lett. 77. 635 (1996).
4. M. Kennel, H. Abarbanel, False neighbours and false strands: A reliable minimum embedding dimension algorithm, Phys. Rev.E, Vol 66, Nub 4, (2002).
5. A. Guyton, J.E.Hall, Textbook of Medical Physiology. Elsevier Saunders, 11th ed, Ed Hall, (Jun 2006).
6. R. Hegger, H.Kantz, Improved false nearest neighbour method to detect determinism in the time series data, Phys. Rev. E, Vol 60, Numb 4, (Oct 1999).
7. T. Schreiber and A.Schmitz, Surrogate time series Physica D, vol. 142, no 3-4, pp 34-382, (2000).
8. M. B. Kennel, R.Brown, and H.D.I Abarbanel, Phys. Rev. A 45, 3403 (1992).
9. J. F. Kaiser, System Analysis by Digital Computer, chap. 7. New York, Wiley (1996).
10. H. Kantz, T. Schreiber, Nonlinear Time Series Analysis , 2th ed. Vol .3, Ed. Cambridge University Press, ( Jan 2004).
11. R. B. Govindan, K. Narayanan, and M. S. Gopinathan On the evidence of deterministic chaos in ECG: Surrogate and predictability analysis, Vol .8, Numb 2, Chaos (June 1998).

Paper Citation

in Harvard Style

H. Oliveira J., Ferreira V. and Coimbra M. (2015). Can We Find Deterministic Signatures in ECG and PCG Signals? . In Proceedings of the International Conference on Bio-inspired Systems and Signal Processing - Volume 1: BIOSIGNALS, (BIOSTEC 2015) ISBN 978-989-758-069-7, pages 184-189. DOI: 10.5220/0005205201840189

in Bibtex Style

@conference{biosignals15,
author={J. H. Oliveira and V. Ferreira and M. Coimbra},
title={Can We Find Deterministic Signatures in ECG and PCG Signals?},
booktitle={Proceedings of the International Conference on Bio-inspired Systems and Signal Processing - Volume 1: BIOSIGNALS, (BIOSTEC 2015)},
year={2015},
pages={184-189},
publisher={SciTePress},
organization={INSTICC},
doi={10.5220/0005205201840189},
isbn={978-989-758-069-7},
}

in EndNote Style

TY - CONF
JO - Proceedings of the International Conference on Bio-inspired Systems and Signal Processing - Volume 1: BIOSIGNALS, (BIOSTEC 2015)
TI - Can We Find Deterministic Signatures in ECG and PCG Signals?
SN - 978-989-758-069-7
AU - H. Oliveira J.
AU - Ferreira V.
AU - Coimbra M.
PY - 2015
SP - 184
EP - 189
DO - 10.5220/0005205201840189