A Network Architecture and Routing Protocol for the MEDIcal WARNing System

Leonardi, Luca; Bello, Lucia Lo; Patti, Gaetano; Ragusa, Orazio

doi:10.3390/jsan10030044

Cited by 9 publications

(2 citation statements)

References 40 publications

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“…In the literature, passive (also called deviceless) remote sensing of human beings was first developed using ad hoc RF transmitters and receivers. Next, WiFi off-the-shelf technology, already successfully applied to a variety of other applications, such as patient monitoring [8][9][10] and factory automation [11], was adopted for this goal. The reason for relying on WiFi mainly resides in the high transmission rate, which allows high-frequency sampling, and in the availability of very detailed Channel State Information (CSI), which allows a stable and reliable extraction of the presence, position and activity information of the human subject.…”

Section: Introductionmentioning

confidence: 99%

A Perspective on Passive Human Sensing with Bluetooth

Iannizzotto

Milici

Nucita

et al. 2022

Sensors

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Passive human sensing approaches based on the analysis of the radio signals emitted by the most common wireless communication technologies have been steadily gaining momentum during the last decade. In this context, the Bluetooth technology, despite its widespread adoption in mobile and IoT applications, so far has not received all the attention it deserves. However, the introduction of the Bluetooth direction finding feature and the application of Artificial Intelligence techniques to the processing and analysis of the wireless signal for passive human sensing pave the way for novel Bluetooth-based passive human sensing applications, which will leverage Bluetooth Low Energy features, such as low power consumption, noise resilience, wide diffusion, and relatively low deployment cost. This paper provides a reasoned analysis of the data preprocessing and classification techniques proposed in the literature on Bluetooth-based remote passive human sensing, which is supported by a comparison of the reported accuracy results. Building on such results, the paper also identifies and discusses the multiple factors and operating conditions that explain the different accuracy values achieved by the considered techniques, and it draws the main research directions for the near future.

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Section: Introductionmentioning

confidence: 99%

A Perspective on Passive Human Sensing with Bluetooth

Iannizzotto

Milici

Nucita

et al. 2022

Sensors

Self Cite

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“…Therefore, a sensor data middleware for medical settings must provide QoS to the applications. Currently, some studies are focusing on improving network performance using routing protocols [13,14]. However, they still suffer from problems such as network node overload [13] or lack of focus on acute care environments such as the operating room [14].…”

Section: Introductionmentioning

confidence: 99%

Smart Hospitals and IoT Sensors: Why Is QoS Essential Here?

Rodrigues

Righi

Costa

et al. 2022

JSAN

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Background: the increasing adoption of smart and wearable sensors in the healthcare domain empowers the development of cutting-edge medical applications. Smart hospitals can employ sensors and applications for critical decision-making based on real-time monitoring of patients and equipment. In this context, quality of service (QoS) is essential to ensure the reliability of application data. Methods: we developed a QoS-aware sensor middleware for healthcare 4.0 that orchestrates data from several sensors in a hybrid operating room. We deployed depth imaging sensors and real-time location tags to monitor surgeries in real-time, providing data to medical applications. Results: an experimental evaluation in an actual hybrid operating room demonstrates that the solution can reduce the jitter of sensor samples up to 90.3%. Conclusions: the main contribution of this article relies on the QoS Service Elasticity strategy that aims to provide QoS for applications. The development and installation were demonstrated to be complex, but possible to achieve.

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Intelligent Decision-Support System for Epidemiological Diagnostics. I. A Concept of Architecture Design

et al. 2022

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The problems of decision support for epidemiological diagnostics are investigated. The basis for supporting decision-making is mathematical tools for analyzing morbidity data, as well as modeling of epidemic processes. The current state of research in this area is analyzed. The features of decision-making in epidemiology and public health are formalized. Principles for the development of an intelligent information system for decision-making support for epidemiological diagnostics are proposed. A systemic model of the system, a model of the interaction of elements of the epidemiological diagnostics system and the interaction of logical components of the information system has been developed. Taking into account the identified features of these processes, the concept of the architecture of such an intelligent information system is proposed.

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A Network Architecture and Routing Protocol for the MEDIcal WARNing System

Cited by 9 publications

References 40 publications

A Perspective on Passive Human Sensing with Bluetooth

A Perspective on Passive Human Sensing with Bluetooth

Smart Hospitals and IoT Sensors: Why Is QoS Essential Here?

Intelligent Decision-Support System for Epidemiological Diagnostics. I. A Concept of Architecture Design

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