2017 39th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC) 2017
DOI: 10.1109/embc.2017.8037330
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Wearable Internet of Things - from human activity tracking to clinical integration

Abstract: Abstract-Wearable devices for human activity tracking have been emerging rapidly. Most of them are capable of sending health statistics to smartphones, smartwatches or smart bands. However, they only provide the data for individual analysis and their data is not integrated into clinical practice. Leveraging on the Internet of Things (IoT), edge and cloud computing technologies, we propose an architecture which is capable of providing cloud based clinical services using human activity data. Such services could … Show more

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Cited by 24 publications
(14 citation statements)
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“…However, wearable sensors can overcome this problem. Kumari et al 26 proposed the WIoT architecture that interfaced the accelerometer, gyroscope, and magnetometer sensors with particle photon board. Using WiFi interface the particle photon board is connected to Raspberry Pi to collect the data and send it to ThingSpeak cloud for storage.…”
Section: Background and Related Workmentioning
confidence: 99%
“…However, wearable sensors can overcome this problem. Kumari et al 26 proposed the WIoT architecture that interfaced the accelerometer, gyroscope, and magnetometer sensors with particle photon board. Using WiFi interface the particle photon board is connected to Raspberry Pi to collect the data and send it to ThingSpeak cloud for storage.…”
Section: Background and Related Workmentioning
confidence: 99%
“…As a result, within the IoT, including IIoT (industrial IoT [72]) and IoMT (internet of medical things [73,74]), the EC devices are extremely diverse, and the volume of data they are generating and processing is rapidly increasing. Data formats include time and frequency space signals, complex images, sound and voice, and a plethora of protected health [74,75,76], personal, and sensitive data. Due to the variety of EC devices, data types, and algorithms [77], many AI-based or smart offloading and transmission strategies are being proposed, such as employing machine and deep learning methods [75,78], or mimicking human brain networks [79].…”
Section: Edge Computingmentioning
confidence: 99%
“…Similarly, traffic lights augmented with hyperspectral imaging and chem-bio sensors can be made locally smart when combined with weather sensors and the unique local population and infrastructure signatures. More concrete EC applications include scalable framework for early fire detection [99], disaster management services [100], accelerometers for structural health monitoring [101], micro-seismic monitoring platform for hydraulic fracture [102], a framework for searchable personal health records [75,76,103], smart health monitoring [76,104] and healthcare framework [105], improved multimedia traffic [106], a field-programmable gate array (FPGA)-based system for cyber-physical systems [107] and for space applications [108], biomedical wearables for IoMT [73,76,109], air pollution monitoring systems [110], precision agriculture [111,112], diabetes [74] and ECG [109] devices, and marine sensor networks [113].…”
Section: Edge Computingmentioning
confidence: 99%
“…Some researches on human activities, which works on offline recognition, are using machine learning tools such as WEKA [18][19][20]. Nowadays, some of clouding systems are being used for online recognition [21] [22].…”
Section: Offline Versus Online Har Systemsmentioning
confidence: 99%