Time-varying rPPG signal separation via block-sparse signal model
Pith reviewed 2026-07-01 07:45 UTC · model grok-4.3
The pith
Modeling rPPG quasi-periodicity as block-sparse in the time-frequency domain enables adaptive separation from illumination noise.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Our approach models quasi-periodicity of the rPPG signal, which arises from the stable cardiac cycle, as a block-sparse structure in the time-frequency domain. To incorporate a block-sparse model and enable adaptive signal separation under illumination fluctuations, we construct a time-varying signal separation framework.
What carries the argument
The time-varying signal separation framework that models rPPG quasi-periodicity as a block-sparse structure in the time-frequency domain.
If this is right
- rPPG extraction adapts automatically to time-varying illumination without fixed assumptions on lighting.
- The stable cardiac cycle provides a reliable block-sparse prior that isolates the pulse from stronger noise.
- Signal separation operates continuously across frames rather than in fixed windows.
- Public dataset experiments confirm the framework isolates the cardiac signal under realistic fluctuations.
Where Pith is reading between the lines
- The same block-sparse time-frequency construction could extend to other quasi-periodic signals such as respiration rate from video.
- Integration with motion-robust preprocessing might further isolate the cardiac component when both illumination and head movement occur together.
- The time-varying aspect suggests the method could handle gradual heart-rate changes without re-initialization.
Load-bearing premise
The quasi-periodic characteristics of rPPG signals can be modeled as a block-sparse structure in the time-frequency domain that enables effective adaptive separation under illumination fluctuations.
What would settle it
A direct comparison on videos with sudden illumination shifts where the proposed method shows no improvement over standard rPPG techniques would falsify the utility of the block-sparse time-frequency model.
read the original abstract
Remote photoplethysmography (rPPG) enables non-contact measurement of cardiac pulse signals by analyzing subtle color changes in facial videos. Nevertheless, extracting rPPG signals remains challenging because of their extremely weak signal strength and susceptibility to illumination noise. In this paper, we propose an rPPG signal extraction method that exploits the quasi-periodic characteristics of rPPG signals. Our approach models quasi-periodicity of the rPPG signal, which arises from the stable cardiac cycle, as a block-sparse structure in the time-frequency domain. To incorporate a block-sparse model and enable adaptive signal separation under illumination fluctuations, we construct a time-varying signal separation framework. Experiments using a public dataset demonstrate the effectiveness of our method.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper proposes an rPPG signal extraction method that models the quasi-periodicity arising from the stable cardiac cycle as a block-sparse structure in the time-frequency domain. It constructs a time-varying signal separation framework to enable adaptive separation under illumination fluctuations, with effectiveness asserted via experiments on a public dataset.
Significance. If the empirical results hold with appropriate quantitative validation, the block-sparse modeling of quasi-periodicity combined with the time-varying framework could offer a principled approach to robust rPPG extraction, addressing a key challenge in non-contact vital sign monitoring under real-world lighting variations.
major comments (1)
- [Abstract] Abstract: The assertion that 'Experiments using a public dataset demonstrate the effectiveness of our method' supplies no quantitative results, baselines, error metrics (e.g., SNR, MAE on heart rate), or implementation details, which is load-bearing for the central claim of effectiveness and prevents assessment of whether the block-sparse model improves upon existing methods.
Simulated Author's Rebuttal
We thank the referee for the detailed review and constructive comment. We agree that the abstract requires quantitative support for the effectiveness claim and will revise accordingly.
read point-by-point responses
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Referee: [Abstract] Abstract: The assertion that 'Experiments using a public dataset demonstrate the effectiveness of our method' supplies no quantitative results, baselines, error metrics (e.g., SNR, MAE on heart rate), or implementation details, which is load-bearing for the central claim of effectiveness and prevents assessment of whether the block-sparse model improves upon existing methods.
Authors: We agree that the abstract should include quantitative results to support the central claim. The full manuscript contains experimental results on a public dataset with metrics such as SNR and heart-rate MAE, but these were not summarized in the abstract. In the revised manuscript we will update the abstract to report key quantitative outcomes (e.g., SNR improvement and MAE reduction relative to baselines) so that the effectiveness claim can be assessed directly from the abstract. revision: yes
Circularity Check
No significant circularity; modeling proposal is self-contained
full rationale
The paper's central contribution is a modeling proposal: quasi-periodicity of rPPG (arising from stable cardiac cycle) is represented as block-sparse structure in the time-frequency domain, with a time-varying separation framework added for illumination fluctuations. This is an explicit construction based on known signal properties, not a derivation chain that reduces to fitted parameters, self-definitions, or self-citation load-bearing steps. No equations or steps in the provided text exhibit the patterns of circularity (e.g., no fitted input called prediction or ansatz smuggled via citation). Validity is tied to experiments on a public dataset, which is an external benchmark, so the work is self-contained with no internal reduction to its own inputs.
Axiom & Free-Parameter Ledger
Reference graph
Works this paper leans on
-
[1]
INTRODUCTION Photoplethysmography (PPG) signals are time-series signals that represent blood volume changes associated with cardiac cycles [1]. Traditionally, contact-type sensors have been used as the gold standard for PPG signal measurement; however, these sensors require continuous physical contact during mea- surement, imposing constraints on daily us...
work page internal anchor Pith review Pith/arXiv arXiv 2026
-
[2]
In the following, we describe each step in detail
PROPOSED METHOD Our method consists mainly of three steps after preprocess- ing: (1) constructing a time-varying signal separation frame- work, (2) formulating an objective function with our block- sparse model, and (3) optimizing via alternating minimiza- tion. In the following, we describe each step in detail. 2.1. Preprocessing We first obtain input RG...
-
[3]
Experimental settings 3.1.1
EXPERIMENTS 3.1. Experimental settings 3.1.1. Dataset We conducted experiments using the UBFC-RPPG dataset [14]. This dataset comprises 49 videos of 47 subjects who were in- structed to sit. Each video was captured for approximately 1 minute. The illumination conditions were natural and not strictly controlled. The captured videos are in an uncom- pressed...
-
[4]
CONCLUSION AND FUTURE WORK We proposed an rPPG signal extraction method that ex- ploits the quasi-periodic characteristics of rPPG signals. We Green ICA CHRO POS PVMM MTTS Phys Ours SNR [dB] -40 -20 0 20 40 w/pca w/pca w/pca w/pca w/pca w/pca Green ICA CHRO POS PVMM MTTS Phys Ours MAE [bpm] 0 50 100 w/pca w/pca w/pca w/pca w/pca w/pca Green ICA CHRO POS P...
-
[5]
Photoplethysmography and its application in clinical physiological measurement,
J. Allen, “Photoplethysmography and its application in clinical physiological measurement,”Physiol. Meas., vol. 28, no. 3, pp. R1–R39, 2007
2007
-
[6]
Remote photoplethysmography for heart rate measure- ment: A review,
H. Xiao, T. Liu, Y . Sun, Y . Li, S. Zhao, and A. Avolio, “Remote photoplethysmography for heart rate measure- ment: A review,”Biomed. Signal Process. Control, vol. 88, 2024, Art. no. 105608
2024
-
[7]
Dis- tancePPG: Robust non-contact vital signs monitoring using a camera,
M. Kumar, A. Veeraraghavan, and A. Sabharwal, “Dis- tancePPG: Robust non-contact vital signs monitoring using a camera,”Biomed. Opt. Exp., vol. 6, no. 5, pp. 1565–1588, 2015
2015
-
[8]
Re- mote plethysmographic imaging using ambient light,
W. Verkruysse, L. O. Svaasand, and J. S. Nelson, “Re- mote plethysmographic imaging using ambient light,” Opt. Express, vol. 16, no. 26, pp. 21434–21445, 2008
2008
-
[9]
Algorithmic principles of remote ppg,
W. Wang, A. C. D. Brinker, S. Stuijk, and G. D. Haan, “Algorithmic principles of remote ppg,”IEEE Trans. Biomed. Eng., vol. 64, no. 7, pp. 1479–1491, 2017
2017
-
[10]
Robust pulse rate from chrominance-based rppg,
G. D. Haan and V . Jeanne, “Robust pulse rate from chrominance-based rppg,”IEEE Trans. Biomed. Eng., vol. 60, no. 10, pp. 2878–2886, 2013
2013
-
[11]
Advancements in noncontact, multiparameter physiological measure- ments using a webcam,
M. Poh, D. McDuff, and R. W. Picard, “Advancements in noncontact, multiparameter physiological measure- ments using a webcam,”IEEE Trans. Biomed. Eng., vol. 58, no. 1, pp. 7–11, 2011
2011
-
[12]
Periodic variance maximization us- ing generalized eigenvalue decomposition applied to remote photoplethysmography estimation,
R. Macwan, S. Bobbia, Y . Benezeth, J. Dubois, and A. Mansouri, “Periodic variance maximization us- ing generalized eigenvalue decomposition applied to remote photoplethysmography estimation,” inProc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. Work- shops (CVPRW), 2018, pp. 1445–1453
2018
-
[13]
Remote photoplethysmography with constrained ica using peri- odicity and chrominance constraints,
R. Macwan, Y . Benezeth, and A. Mansouri, “Remote photoplethysmography with constrained ica using peri- odicity and chrominance constraints,”Biomed. Eng. On- line, vol. 17, no. 1, pp. 1–22, 2018
2018
-
[14]
On the analysis of fingertip photoplethys- mogram signals,
M. Elgendi, “On the analysis of fingertip photoplethys- mogram signals,”Curr . Cardiol. Rev., vol. 8, no. 1, pp. 14–25, 2012
2012
-
[15]
Block-sparse recovery with optimal block partition,
H. Kuroda and D. Kitahara, “Block-sparse recovery with optimal block partition,”IEEE Trans. Signal Pro- cess., vol. 70, pp. 1506–1520, 2022
2022
-
[16]
Proximal algorithms,
N. Parikh and S. Boyd, “Proximal algorithms,”F ound. Trends Optim., vol. 1, no. 3, pp. 127–239, 2014
2014
-
[17]
M. J. Kochenderfer and T. A. Wheeler,Algorithms for Optimization, MIT Press, Cambridge, MA, USA, 2019
2019
-
[18]
Unsupervised skin tissue segmentation for remote photoplethysmography,
S. Bobbia, R. Macwan, Y . Benezeth, A. Mansouri, and J. Dubois, “Unsupervised skin tissue segmentation for remote photoplethysmography,”Pattern Recognit. Lett., vol. 124, no. 1, pp. 82–90, 2019
2019
-
[19]
Non- contact heart rate estimation via adaptive rgb/nir signal fusion,
K. Kurihara, D. Sugimura, and T. Hamamoto, “Non- contact heart rate estimation via adaptive rgb/nir signal fusion,”IEEE Trans. Image Process., vol. 30, pp. 6528– 6543, 2021
2021
-
[20]
Spatio-temporal structure extraction of blood volume pulse using dynamic mode decomposition for heart rate estimation,
K. Kurihara, Y . Maeda, D. Sugimura, and T. Hamamoto, “Spatio-temporal structure extraction of blood volume pulse using dynamic mode decomposition for heart rate estimation,”IEEE Access, vol. 11, pp. 59081–59096, 2023
2023
-
[21]
Self-adaptive matrix completion for heart rate estimation from face videos under realis- tic conditions,
S. Tulyakov, X. Alameda-Pineda, E. Ricci, L. Yin, J. F. Cohn, and N. Sebe, “Self-adaptive matrix completion for heart rate estimation from face videos under realis- tic conditions,” inProc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR), 2016, pp. 2396–2404
2016
-
[22]
Multi-task temporal shift attention networks for on-device contact- less vitals measurement,
X. Liu, J. Fromm, S. Patel, and D. McDuff, “Multi-task temporal shift attention networks for on-device contact- less vitals measurement,” inProc. Adv. Neural Inf. Pro- cess. Syst. (NeurIPS), 2020, vol. 33, pp. 19400–19411
2020
-
[23]
Physformer: Facial video-based physiological mea- surement with temporal difference transformer,
Z. Yu, Y . Shen, J. Shi, H. Zhao, P. Torr, and G. Zhao, “Physformer: Facial video-based physiological mea- surement with temporal difference transformer,” in Proc. IEEE/CVF Conf. Comput. Vis. Pattern Recognit. (CVPR), 2022, pp. 4176–4186
2022
-
[24]
Need for a revision of the normal limits of resting heart rate,
P. Palatini, “Need for a revision of the normal limits of resting heart rate,”Hypertension, vol. 33, no. 2, pp. 622–625, 1999
1999
-
[25]
Rhythmnet: End-to-end heart rate estimation from face via spatial- temporal representation,
X. Niu, S. Shan, H. Han, and X. Chen, “Rhythmnet: End-to-end heart rate estimation from face via spatial- temporal representation,”IEEE Trans. Image Process., vol. 29, pp. 2409–2423, 2020
2020
-
[26]
Unified physiological and illumination modeling for heart rate estimation using dynamic mode decomposi- tion and rgb/nir sensor,
K. Kurihara, Y . Maeda, D. Sugimura, and T. Hamamoto, “Unified physiological and illumination modeling for heart rate estimation using dynamic mode decomposi- tion and rgb/nir sensor,”IEICE Trans. Inf. & Syst., vol. E109.D, no. 1, pp. 95–106, 2026
2026
-
[27]
Model- based deep learning: On the intersection of deep learn- ing and optimization,
N. Shlezinger, Y . C. Eldar, and S. P. Boyd, “Model- based deep learning: On the intersection of deep learn- ing and optimization,”IEEE Access, vol. 10, pp. 115384–115398, 2022
2022
-
[28]
Deep unfolding-based image reconstruction for quanta image sensors,
W. Otobe, K. Kurihara, Y . Maeda, and T. Hamamoto, “Deep unfolding-based image reconstruction for quanta image sensors,” inProc. IEEE Int. Conf. Image Process. (ICIP), 2025, pp. 2648–2653
2025
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