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arxiv_cv 80% Match Research Paper Biomedical Engineers,Healthcare Professionals,Machine Learning Researchers,Signal Processing Engineers 2 days ago

LifWavNet: Lifting Wavelet-based Network for Non-contact ECG Reconstruction from Radar

speech-audio › audio-generation
📄 Abstract

Abstract: Non-contact electrocardiogram (ECG) reconstruction from radar signals offers a promising approach for unobtrusive cardiac monitoring. We present LifWavNet, a lifting wavelet network based on a multi-resolution analysis and synthesis (MRAS) model for radar-to-ECG reconstruction. Unlike prior models that use fixed wavelet approaches, LifWavNet employs learnable lifting wavelets with lifting and inverse lifting units to adaptively capture radar signal features and synthesize physiologically meaningful ECG waveforms. To improve reconstruction fidelity, we introduce a multi-resolution short-time Fourier transform (STFT) loss, that enforces consistency with the ground-truth ECG in both temporal and spectral domains. Evaluations on two public datasets demonstrate that LifWavNet outperforms state-of-the-art methods in ECG reconstruction and downstream vital sign estimation (heart rate and heart rate variability). Furthermore, intermediate feature visualization highlights the interpretability of multi-resolution decomposition and synthesis in radar-to-ECG reconstruction. These results establish LifWavNet as a robust framework for radar-based non-contact ECG measurement.
Authors (5)
Soumitra Kundu
Gargi Panda
Saumik Bhattacharya
Aurobinda Routray
Rajlakshmi Guha
Submitted
October 31, 2025
arXiv Category
cs.CV
arXiv PDF

Key Contributions

LifWavNet is a novel lifting wavelet network for non-contact ECG reconstruction from radar signals. It utilizes learnable lifting wavelets and a multi-resolution STFT loss to adaptively capture radar signal features and synthesize physiologically meaningful ECG waveforms, outperforming prior methods.

Business Value

Enables continuous, unobtrusive cardiac monitoring without physical contact, improving patient comfort and enabling early detection of cardiac issues, particularly valuable for remote patient care and wearable devices.

Paper Metadata

Innovation Type

Novel Network Architecture

Deployment Feasibility

Moderate, requires radar hardware and integration into healthcare monitoring systems.

Limitations Addressed

Limitations of fixed wavelet approaches in radar-to-ECG reconstruction, and the need for improved reconstruction fidelity and downstream vital sign estimation accuracy.

Performance Gains

Outperforms state-of-the-art methods in ECG reconstruction and downstream vital sign estimation.

Technical Tags

ECG reconstructionradar signalslifting wavelet networkmulti-resolution analysisnon-contact monitoringdeep learningsignal processingvital sign estimation

Research Topics

Biomedical Signal ProcessingNon-contact SensingDeep Learning for Signal ReconstructionCardiac Monitoring

Methods & Architectures

LifWavNetLifting Wavelet NetworkMulti-Resolution Analysis and Synthesis (MRAS)Learnable Lifting WaveletsMulti-resolution STFT loss Lifting Wavelet Network

Applications & Tasks

Healthcare Wearable Technology Remote Patient Monitoring Biomedical Engineering Non-contact ECG ReconstructionVital Sign EstimationSignal Fidelity Improvement ECG Reconstruction from RadarHeart Rate EstimationHeart Rate Variability Estimation

Datasets & Benchmarks

Datasets
two public datasets

Related Fields

Biomedical EngineeringSignal ProcessingMachine LearningRadar Technology

Keywords

ECG reconstructionradarlifting waveletnon-contactcardiac monitoringdeep learningsignal processingvital signsbiomedicalhealthcarewavelet network

Academic Context

#Biomedical Signal Processing#Non-contact Sensing#Deep Learning for Signal Reconstruction#Cardiac Monitoring

Commercial Potential

Potential Products
Non-contact vital sign monitorsSmart home health monitoring systemsWearable health trackers with advanced ECG analysis
Target Industries
HealthcareMedical DevicesWearable TechnologyTelemedicine
Use Case Examples
Continuous heart monitoring for elderly patients at homeTracking cardiac health during sleep without disturbing the userIntegrating vital sign monitoring into smart clothing
Competitive Edge
Offers a novel deep learning approach using learnable lifting wavelets for radar-based ECG reconstruction, aiming for higher fidelity and accuracy than previous methods.
Market Opportunity
Large and growing market for remote patient monitoring and wearable health tech.
Revenue Models
Sale of medical deviceslicensing of technology to healthcare providers.

Resource Requirements

Compute Needs
Requires GPU for training; inference can be optimized for embedded systems.
Data Requirements
Requires synchronized radar and ECG data.
Deployment Constraints
Integration with radar hardware and medical device regulations.
Scalability
Scalability depends on the efficiency of the network and the processing hardware.
Regulatory Considerations
FDA approval or equivalent for medical devices.

Production Readiness

Maturity Level

Research

Time to Market

Medium to Long (requires clinical validation and regulatory approval)

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