Abstract
Heart rate variability (HRV) is an intrinsic property of heart and active research domain of the medical research community since last two decades. But in biometrics it is still in its infancy. This article is intended to present the state of art into heart-based biometrics and also explore the possibility of using HRV in biometric recognition systems. Subsequently, we designed hardware and software for data collection and also developed software for HRV analysis in Matlab, which generates 101 HRV Parameters (Features) using various HRV analysis techniques like statistical, spectral, geometrical, etc., which are commonly used and recommended for HRV analysis. All these features have their relative significance in medical interpretations and analysis, but among these 101 features reliable features that can be useful for biometric recognition were unknown; therefore feature selection becomes a necessary step. We used five different wrapper algorithms for feature selection, and obtained 10 reliable features out of 101. Using the proposed 10 HRV features, we used KNN for classification of subjects. The classification test gave us encouraging results with 82.22 % recognition rate.
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Acknowledgments
This work was carried out in Multimodal System Development laboratory established under UGC’s SAP scheme, SAP (II) DRS Phase-I F. No. 3-42/2009 & SAP (II) DRS Phase-II F. No.4-15/2015. This work was also supported by UGC under One Time Research Grant F. No. 4-10/2010 (BSR) & 19-132/2014 (BSR). The authors also acknowledge UGC for providing BSR fellowship.
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Appendix A
Appendix A
Poincare map features | ||
|---|---|---|
1 2 | • SD1 • SD2 | • Standard deviations of the distances of the R–R (I) to the lines • Y = x and y = –x + 2R–Rm, where R–Rm is the mean of all R–R (I) • SD1 related to the • Fast beat-to-beat variability in the data, while SD2 • Describes the long-term variability of R–R (I) |
Statistical features | ||
|---|---|---|
No. | Name | Description |
1 | SDNN | Standard deviation of all normal–normal intervals |
2 | RMSSD | Root mean square of successive differences |
3 | NN50 | It’s a count of the number of adjacent pairs differing by more than 50 ms |
4 | pNN50 | (%) NN50 count divided by total intervals |
5 | MeanRRI | Mean of normal–normal interval |
6 | MeanHR | Mean heart rate |
7 | Max | Maximum interval duration in a particular RRI |
8 | Min | Minimum interval duration |
9 | Mean | Mean of the whole RRI sequence |
10 | Median | Median of the RRI sequence |
11 | SDHR | Standard deviation of heart rate |
Spectral features | ||
|---|---|---|
No. | Name | Description |
1 | aVLF | Absolute value in very low-frequency spectrum |
2 | aLF | Absolute value in low-frequency Spectrum |
3 | aHF | Absolute value in high-frequency Spectrum |
4 | aTotal | Total absolute value |
5 | pVLF | Power % of very low frequency in PSD |
6 | pLF | Power % of low frequency in PSD |
7 | pHF | Power % of high Frequency in PSD |
8 | nLF | Low frequency in normalized Unit |
9 | nHF | High frequency in normalized Unit |
10 | LFHF | LF to HF Ratio |
11 | peakVLF | Peak value in very low frequency |
12 | peakLF | Peak value in low frequency |
13 | peakHF | Peak value in high frequency |
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Akhter, N., Tharewal, S., Kale, V., Bhalerao, A., Kale, K.V. (2016). Heart-Based Biometrics and Possible Use of Heart Rate Variability in Biometric Recognition Systems. In: Chaki, R., Cortesi, A., Saeed, K., Chaki, N. (eds) Advanced Computing and Systems for Security. Advances in Intelligent Systems and Computing, vol 395. Springer, New Delhi. https://doi.org/10.1007/978-81-322-2650-5_2
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