Power-efficient joint compressed sensing of multi-lead ECG signals

Mamaghanian, Hossein; Ansaloni, Giovanni; Atienza, David

doi:10.1109/icassp.2014.6854435

Cited by 25 publications

(29 citation statements)

References 10 publications

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“…For this application, the measured sensitivity and specificity of retrieved fiducial points are above 90% in all cases, which is at the target level for medical use in this field. Figure 5 compares the averaged signal-to-noise ratio (SNR) results over different compression ratios (CR) for singlelead and multi-lead CS compression [6]. These results show that an averaged SNR over 20 dB (corresponding to good reconstruction quality [16]) is reached for CR = 65.9% and CR = 72.7% for single and multi-lead CS, respectively.…”

Section: Resultsmentioning

confidence: 82%

“…Second, in case of the multi-lead ECG compression, there is a strong correlation between the sparsity structure among the leads, each lead therefore conveying useful information about other leads. In particular, non-zero coefficients are partitioned in subsets or groups, and this information can be employed to enhance the compression performance across all leads [6].…”

Section: A Software Optimizationsmentioning

confidence: 99%

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Ultra-Low Power Design of Wearable Cardiac Monitoring Systems

Braojos

Mamaghanian

Dias

et al. 2014

Proceedings of the 51st Annual Design Automation Conference

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Abstract-This paper presents the system-level architecture of novel ultra-low power wireless body sensor nodes (WBSNs) for real-time cardiac monitoring and analysis, and discusses the main design challenges of this new generation of medical devices. In particular, it highlights first the unsustainable energy cost incurred by the straightforward wireless streaming of raw data to external analysis servers. Then, it introduces the need for new cross-layered design methods (beyond hardware and software boundaries) to enhance the autonomy of WBSNs for ambulatory monitoring. In fact, by embedding more onboard intelligence and exploiting electrocardiogram (ECG) specific knowledge, it is possible to perform real-time compressive sensing, filtering, delineation and classification of heartbeats, while dramatically extending the battery lifetime of cardiac monitoring systems. The paper concludes by showing the results of this new approach to design ultra-low power wearable WBSNs in a real-life platform commercialized by SmartCardia. This wearable system allows a wide range of applications, including multi-lead ECG arrhythmia detection and autonomous sleep monitoring for critical scenarios, such as monitoring of the sleep state of airline pilots.

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Section: Resultsmentioning

confidence: 82%

Section: A Software Optimizationsmentioning

confidence: 99%

Ultra-Low Power Design of Wearable Cardiac Monitoring Systems

Braojos

Mamaghanian

Dias

et al. 2014

Proceedings of the 51st Annual Design Automation Conference

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“…This process enables a relaxation of the traditional reliability requirements (i.e., 100% computational precision is not needed), which can be exploited by the CS application. In particular, the maximum required output SNR to get almost a 100% reconstruction quality is only 35 dB in the case of multi-lead ECG [10] and 40 dB in the case of a single lead ECG [11]. Thus, as Fig.…”

Section: Characterization Of Biomedical Applicationsmentioning

confidence: 87%

“…It helps to reduce airtime over energy-hungry wireless links. We have implemented our own version of the algorithm presented by the authors of [10], which takes as input a vector of ECG samples and applies a 50% lossy compression algorithm to convert it into a smaller one (half the size of the input vector).…”

Section: ) Compressed Sensing (Cs)mentioning

confidence: 99%

Energy vs. Reliability Trade-offs Exploration in Biomedical Ultra-Low Power Devices

Duch

Valle

Ganapathy

et al. 2016

Proceedings of the 2016 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE)

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Abstract-State-of-the-art wearable devices such as embedded biomedical monitoring systems apply voltage scaling to lower as much as possible their energy consumption and achieve longer battery lifetimes. While embedded memories often rely on Error Correction Codes (ECC) for error protection, in this paper we explore how the characteristics of biomedical applications can be exploited to develop new techniques with lower power overhead. We then introduce the Dynamic eRror compEnsation And Masking (DREAM) technique, that provides partial memory protection with less area and power overheads than ECC. Different tradeoffs between the error correction ability of the techniques and their energy consumption are examined to conclude that, when properly applied, DREAM consumes 21% less energy than a traditional ECC with Single Error Correction and Double Error Detection (SEC/DED) capabilities.

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“…In such a situation, where non-zero coefficients are naturally partitioned in subsets or groups, the best choice could be using a group-sparsity inducing term [22]. In a recent prior work [21], we proposed to replace the ℓ1 norm with mixed ℓ1/ℓ2 norm. It behaves like an ℓ1-norm on the vector ( αi 2 )i∈L in R |L| , and therefore, induces group sparsity.…”

Section: Multi-lead Ecg and Joint Compressionmentioning

confidence: 99%

Approximate compressed sensing

Bortolotti

Mamaghanian

Bartolini

et al. 2014

Proceedings of the 2014 International Symposium on Low Power Electronics and Design

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Technology scaling enables the design of low cost biosignal processing chips suited for emerging wireless body-area sensing applications. Energy consumption severely limits such applications and memories are becoming the energy bottleneck to achieve ultra-low-power operation. When aggressive voltage scaling is used, memory operation becomes unreliable due to the lack of sufficient Static Noise Margin. This paper introduces an approximate biosignal Compressed Sensing approach. We propose a digital architecture featuring a hybrid memory (6T-SRAM/SCMEM cells) designed to control perturbations on specific data structures. Combined with a statistically robust reconstruction algorithm, the system tolerates memory errors and achieves significant energy savings with low area overhead.

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Power-efficient joint compressed sensing of multi-lead ECG signals

Cited by 25 publications

References 10 publications

Ultra-Low Power Design of Wearable Cardiac Monitoring Systems

Ultra-Low Power Design of Wearable Cardiac Monitoring Systems

Energy vs. Reliability Trade-offs Exploration in Biomedical Ultra-Low Power Devices

Approximate compressed sensing

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