WSN Based Personal Mobile Physiological Monitoring and Management System for Chronic Disease

Toh, Sing-Hui; Lee, Seung−Chul; Chung, Wan-Young

doi:10.1109/iccit.2008.392

Cited by 24 publications

(11 citation statements)

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“…Toh et al . () proposed a collection of wearable sensors to monitor several physiologic functions including heart rate, heart rhythm, blood pressure and blood sugar. The sensors transmit the data automatically to a cell phone based system that can display data in a user‐friendly manner.…”

Section: Resultsmentioning

confidence: 99%

“…One system was rated as 'modification' (Fu et al 2009) and two systems were rated 'augmentation' (Villalba et al 2009, Triantafyllidis et al 2014 according to the SAMR model. Toh et al (2008) proposed a collection of wearable sensors to monitor several physiologic functions including heart rate, heart rhythm, blood pressure and blood sugar.…”

Section: Sensor-based Technologiesmentioning

confidence: 99%

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Computer technology for self‐management: a scoping review

Jacelon

Gibbs

Ridgway

2016

Journal of Clinical Nursing

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Section: Resultsmentioning

confidence: 99%

Section: Sensor-based Technologiesmentioning

confidence: 99%

Computer technology for self‐management: a scoping review

Jacelon

Gibbs

Ridgway

2016

Journal of Clinical Nursing

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“…Mobile phones could transmit information through Bluetooth, WAP, Wi-Fi, GSM and code division multiple access (CDMA) among others [38]. Since each of them has both merits and shortcomings, the matter lies in how to choose proper protocols for the specific application.…”

Section: Communication Protocolsmentioning

confidence: 99%

Mobile phone-enabled control of medical care and handicapped assistance

Liu

2011

Expert Review of Medical Devices

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Mobile phones are now playing an ever more crucial role in people's daily lives. They are serving not only as a way of talking and delivering messages, but also for exchanging various information. Nevertheless, the functional limit of the phone is still far from being reached. Among the many promising applications, using mobile phones as an actuating element to control data or devices is useful in quite a few emerging medical care and handicapped assistance settings owing to its wireless communication feature. In this article, selected progresses of mobile phone-enabled controlling have been summarized, with more focus on evaluating its emerging roles in medical care. Several typical applications in the area are illustrated and some potential technical challenges and key issues worthy of pursuit are outlined. The intent of the article is to provide an elementary knowledge for people with different backgrounds, such as electrical or biomedical engineers, as well as people who are working on interdisciplinary areas. It is expected that medical care at any time and anywhere will be possible via the actuation platform provided by the mobile phone and mobile medicine will be pushed forward to a new height in the coming years.

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“…The ability to detect the onset of adverse health conditions relatively earlier than without BANs will revolutionize the health care industry. Some examples of related and current research include monitoring of ambulatory ECG [11][12][13], blood glucose [14,15] and pulse oximetry [16]. Regardless of the application, BANs are faced with many challenges.…”

Section: Introductionmentioning

confidence: 99%

FPGA based reconfigurable body area network using Nios II and uClinux

Voykin

Bui

Bolton

2013

2013 26th IEEE Canadian Conference on Electrical and Computer Engineering (CCECE)

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ii Abstract This research is focused on identifying an appropriate design for a reconfigurable Body Area Network (BAN).In order to investigate the benefits and drawbacks of the proposed design, a BAN system prototype was built. This system consists of two distinct node types: a slave node and a master node. These nodes communicate using ZigBee radio transceivers.The microcontroller-based slave node acquires sensor data and transmits digitized samples to the master node. The master node is FPGA-based and runs uClinux on a soft-core microcontroller. The purpose of the master node is to receive, process and store digitized sensor data. In order to verify the operation of the BAN system prototype and demonstrate reconfigurability, a specific application was required.Pattern recognition in electrocardiogram (ECG) data was the application used in this work and the MIT-BIH Arrhythmia Database was used as the known data source for verification. A custom test platform was designed and built for the purpose of injecting data from the MIT-BIH Arrhythmia Database into the BAN system. The BAN system designed and built in this work demonstrates the ability to record raw ECG data, detect R-peaks, calculate and record R-R intervals, detect premature ventricular and atrial contractions. As this thesis will identify, many aspects of this BAN system were designed to be highly reconfigurable allowing it to be used for a wide range of BAN applications, in addition to pattern recognition of ECG data.iii

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WSN Based Personal Mobile Physiological Monitoring and Management System for Chronic Disease

Cited by 24 publications

References 1 publication

Computer technology for self‐management: a scoping review

Computer technology for self‐management: a scoping review

Mobile phone-enabled control of medical care and handicapped assistance

FPGA based reconfigurable body area network using Nios II and uClinux

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