Pervasive and Personalized Ambient Parameters Monitoring: A Wearable, Modular, and Configurable Watch

Haghi, Mostafa; Stoll, Norbert; Thurow, Kerstin

doi:10.1109/access.2019.2897845

Cited by 23 publications

(10 citation statements)

References 41 publications

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“…In addition, only some of the developers have reported the final cost of the prototypes, which encompasses fabrication, components, and layout design. References [ 68 , 69 , 70 , 71 ] have reported 150$, 130$, 150$, and 140$ as the final cost of the prototypes, respectively.…”

Section: Resultsmentioning

confidence: 99%

Wearable Devices in Health Monitoring from the Environmental towards Multiple Domains: A Survey

Haghi

Danyali

Ayasseh

et al. 2021

Sensors

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The World Health Organization (WHO) recognizes the environmental, behavioral, physiological, and psychological domains that impact adversely human health, well-being, and quality of life (QoL) in general. The environmental domain has significant interaction with the others. With respect to proactive and personalized medicine and the Internet of medical things (IoMT), wearables are most important for continuous health monitoring. In this work, we analyze wearables in healthcare from a perspective of innovation by categorizing them according to the four domains. Furthermore, we consider the mode of wearability, costs, and prolonged monitoring. We identify features and investigate the wearable devices in the terms of sampling rate, resolution, data usage (propagation), and data transmission. We also investigate applications of wearable devices. Web of Science, Scopus, PubMed, IEEE Xplore, and ACM Library delivered wearables that we require to monitor at least one environmental parameter, e.g., a pollutant. According to the number of domains, from which the wearables record data, we identify groups: G1, environmental parameters only; G2, environmental and behavioral parameters; G3, environmental, behavioral, and physiological parameters; and G4 parameters from all domains. In total, we included 53 devices of which 35, 9, 9, and 0 belong to G1, G2, G3, and G4, respectively. Furthermore, 32, 11, 7, and 5 wearables are applied in general health and well-being monitoring, specific diagnostics, disease management, and non-medical. We further propose customized and quantified output for future wearables from both, the perspectives of users, as well as physicians. Our study shows a shift of wearable devices towards disease management and particular applications. It also indicates the significant role of wearables in proactive healthcare, having capability of creating big data and linking to external healthcare systems for real-time monitoring and care delivery at the point of perception.

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Section: Resultsmentioning

confidence: 99%

Wearable Devices in Health Monitoring from the Environmental towards Multiple Domains: A Survey

Haghi

Danyali

Ayasseh

et al. 2021

Sensors

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“…Each generation might have several versions, considering the features, characteristics, and optimization. As examples, in this definition, wearables that measure either three-dimensional (3D) motion tracking (physical activity) via inertial measurement units (IMUs) [34], air pollutants (environmental) [35], vital signs (physiological) [36], and emotion and stress (psychological) are widely used and represent the first generation of wearables (G 1 ) [37]. However, version of the generation varies from one wearable to another depending on the wearability, computation methodology, and processing, which is not the focus here.…”

Section: Generation Of Wearables: Current Statusmentioning

confidence: 99%

General Conceptual Framework of Future Wearables in Healthcare: Unified, Unique, Ubiquitous, and Unobtrusive (U4) for Customized Quantified Output

Haghi

Deserno

2020

Chemosensors

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We concentrate on the importance and future conceptual development of wearable devices as the major means of personalized healthcare. We discuss and address the role of wearables in the new era of healthcare in proactive medicine. This work addresses the behavioral, environmental, physiological, and psychological parameters as the most effective domains in personalized healthcare, and the wearables are categorized according to the range of measurements. The importance of multi-parameter, multi-domain monitoring and the respective interactions are further discussed and the generation of wearables based on the number of monitoring area(s) is consequently formulated.

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“…22 Typically, sensors measure environmental data (e.g., outside temperature) behavioral data (e.g., movement), and vital signs (e.g., heart/respiration rate, blood pressure, body temperature). 23 Wearable devices have a multitude of potential applications, ranging from well-being (e.g., monitoring the number of steps per day) to safety-critical applications (e.g., monitoring fatigue of workers in hazardous environments).…”

Section: Introductionmentioning

confidence: 99%

Proposing an International Standard Accident Number for Interconnecting Information and Communication Technology Systems of the Rescue Chain

Spicher

Barakat

et al. 2021

Methods Inf Med

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Background The rapid dissemination of smart devices within the internet of things (IoT) is developing toward automatic emergency alerts which are transmitted from machine to machine without human interaction. However, apart from individual projects concentrating on single types of accidents, there is no general methodology of connecting the standalone information and communication technology (ICT) systems involved in an accident: systems for alerting (e.g., smart home/car/wearable), systems in the responding stage (e.g., ambulance), and in the curing stage (e.g., hospital). Objectives We define the International Standard Accident Number (ISAN) as a unique token for interconnecting these ICT systems and to provide embedded data describing the circumstances of an accident (time, position, and identifier of the alerting system). Materials and Methods Based on the characteristics of processes and ICT systems in emergency care, we derive technological, syntactic, and semantic requirements for the ISAN, and we analyze existing standards to be incorporated in the ISAN specification. Results We choose a set of formats for describing the embedded data and give rules for their combination to generate an ISAN. It is a compact alphanumeric representation that is generated easily by the alerting system. We demonstrate generation, conversion, analysis, and visualization via representational state transfer (REST) services. Although ISAN targets machine-to-machine communication, we give examples of graphical user interfaces. Conclusion Created either locally by the alerting IoT system or remotely using our RESTful service, the ISAN is a simple and flexible token that enables technological, syntactic, and semantic interoperability between all ICT systems in emergency care.

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Pervasive and Personalized Ambient Parameters Monitoring: A Wearable, Modular, and Configurable Watch

Cited by 23 publications

References 41 publications

Wearable Devices in Health Monitoring from the Environmental towards Multiple Domains: A Survey

Wearable Devices in Health Monitoring from the Environmental towards Multiple Domains: A Survey

General Conceptual Framework of Future Wearables in Healthcare: Unified, Unique, Ubiquitous, and Unobtrusive (U4) for Customized Quantified Output

Proposing an International Standard Accident Number for Interconnecting Information and Communication Technology Systems of the Rescue Chain

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