Body Sensor Networks: A Holistic Approach From Silicon to Users

Calhoun, Benton H.; Lach, John; Stankovic, John A.; Wentzloff, David D.; Whitehouse, Kamin; Barth, Adam T.; Brown, Jonathan K.; Li, Qiang; Oh, Sangyoon; Roberts, Nathan E.; Zhang, Yanqing

doi:10.1109/jproc.2011.2161240

Cited by 65 publications

(40 citation statements)

References 52 publications

(63 reference statements)

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“…The steep progress in sensor engineering throughout the last decade brought the progress that was needed to use physiological sensors for various applications (e.g., [25]). Sensors that enable physiological signal recording have declined in price, have become more reliable, and can be applied wireless [25]. Next, I will discuss the advantages and disadvantages of physiological signals as biometrics.…”

Section: Processing Physiological Signalsmentioning

confidence: 99%

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Physiological Signals: The Next Generation Authentication and Identification Methods!?

Broek¹,

Spitters²

2013

2013 European Intelligence and Security Informatics Conference

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Abstract-Throughout the last 40 years, the security breach caused by human error is often disregarded. To relief the latter problem, this article introduces a new class of biometrics that is founded on processing physiological personal features, as opposed to physical and behavioral features. After an introduction on authentication, physiological signals are discussed, including their advantages, disadvantages, and initial directives for obtaining them. This new class of authentication methods can increase biometrics' robustness and enables cross validation. I close this article with a brief discussion in which a recap of the article is provided, law, privacy, and ethical issues are discussed, some suggestions for the processing pipeline of this new class of authentication methods are done, and conclusions are drawn.

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Section: Processing Physiological Signalsmentioning

confidence: 99%

“…As mentioned, the rapid development of non-invasive wireless sensors [25] have made them suitable for a wide range of applications [21], [23], [26]. As such, physiological signals can act a new class of interfaces (e.g., authentication and identification) between man and machine.…”

Section: A Advantagesmentioning

confidence: 99%

Physiological Signals: The Next Generation Authentication and Identification Methods!?

Broek¹,

Spitters²

2013

2013 European Intelligence and Security Informatics Conference

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“…BSNs are typically governed by more stringent constraints on their resource consumption (e.g., energy and computational resources), as well as mobility and device size constraints (see [3] for discussion of such issues). More importantly, BSNs are operated in scenarios typically outside a clinical environment.…”

Section: Introductionmentioning

confidence: 99%

Towards a Framework for Safety Analysis of Body Sensor Networks

Asare¹,

Lach²,

Stankovic³

et al. 2013

Proceedings of the 8th International Conference on Body Area Networks

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Body sensor networks (BSNs) are an emerging class of medical cyber-physical systems which have the potential to change the healthcare paradigm. However, they present many new challenges, chief of which (like any medical device) is assuring patient safety. This requires not only a precise definition of safety, but also techniques for assessing the safety of BSN designs. Although solutions are possible and important for specific BSNs used in specific applications, addressing this issue on a case-by-case basis usually results in an ad-hoc process, and more importantly, makes the translation of experiences and solutions between different applications more difficult.A generic and conceptual framework for guiding the safety analysis process would provide all stakeholders a common basis for communicating, discussing, and examining the safety of BSN designs, and provide manufacturers with an exemplary process that they can follow to improve and gain confidence in the safety of their devices. This paper presents our current efforts in developing such a framework. In particular, we present a theoretical foundation for modeling and analyzing BSNs, and identify the general class of hazards based on this foundation. These efforts explore critical issues that deserve attention in designing safe BSN systems, and more importantly, can help advance the understanding of BSNs and their safety.

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“…This can be done by minimizing the size of the energy harvester, matching the sensing locations to the location of the energy harvester, integrating most of the system components onto small printed circuit boards, and by integrating sensors into textiles. 4. System Flexibility and Modularity Optimization (Section VIII) -Real-world deployments for a BSN can be unpredictable and its functional requirements can change as new information is acquired during research.…”

Section: Design Challengesmentioning

confidence: 99%

“…To address user acceptance, researchers have emphasized the importance of making BSNs wearable and wireless [3]. To address battery life, researchers have emphasized the importance of making BSNs ultra-low power so that they can operate for long periods of time on a small battery or even be powered by an energy harvester attached to the body [4]. If an energy harvester is used and the power that it generates is greater than the power that the system consumes, then the BSN achieves self-powered operation.…”

Section: Introductionmentioning

confidence: 99%

Design Considerations for Self-Powered Wearable Wireless Multimodal Vigilant Sensing Systems

Ridder¹

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Body Sensor Networks (BSNs) are cyber-physical sensor systems that address the weaknesses of traditional remote patient monitoring methods in healthcare and provide the opportunity for the continuous collection of high-quality data. However, they must overcome the obstacles of user acceptance and battery life in order for widespread adoption to occur. User acceptance can be addressed by designing BSNs to be wearable and wireless while battery life can be addressed by designing them to have self-powered operation. BSNs must also have multimodal vigilant sensing so that they do not miss any critical events for their given application. One application is cardiac and activity monitoring and it can potentially reduce the number of hospitalizations in patients with a cardiovascular disease (CVD) by tracking CVD symptoms and alerting healthcare professionals when one is detected.One such BSN that performs this kind of monitoring is the testbed for the Self-Powered and Adaptive Low Power Sensing Platform (SAP).This thesis presents the design of the SAP testbed, which is a self-powered wearable sensor system designed to perform vigilant long-term cardiac and activity monitoring by continuously sensing and wirelessly streaming ECG and motion data to a smartphone. It consumes only 370 μW on average and is powered solely by indoor solar allowing it to maintain its monitoring at a vigilant sampling rate so that it does not miss any critical cardiac and activity events. The testbed was deployed on several subjects in the laboratory to validate this behavior. Designing BSNs with similar characteristics to the SAP testbed presents a number of design challenges that must be addressed. These challenges include power management, energy harvesting optimization, system wearability optimization, and system flexibility and modularity optimization. Therefore, in addition to the presentation of the SAP testbed, this thesis discusses the design considerations that must be made in order to make intelligent design decisions when addressing these challenges.

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Body Sensor Networks: A Holistic Approach From Silicon to Users

Cited by 65 publications

References 52 publications

Physiological Signals: The Next Generation Authentication and Identification Methods!?

Physiological Signals: The Next Generation Authentication and Identification Methods!?

Towards a Framework for Safety Analysis of Body Sensor Networks

Design Considerations for Self-Powered Wearable Wireless Multimodal Vigilant Sensing Systems

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