A java-based enterprise system architecture for implementing a continuously supported and entirely web-based exercise solution

A java-based enterprise system architecture for implementing a continuously supported and entirely web-based exercise solution

Since machine-based exercise still uses local facilities, it is affected by time and place. We designed a web-based system architecture based on the Java 2 Enterprise Edition that can accomplish continuously supported machine-based exercise. In this system, exercise programs and machines are loosely...

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Veröffentlicht in:IEEE journal of biomedical and health informatics 2006-04, Vol.10 (2), p.403-411
Hauptverfasser: Zhihui Wang, Kiryu, T.
Format: Artikel
Sprache:eng
Schlagworte:
Biosignal-based workload control
Communication system control
Control systems
Electronic mail
exercise system
Exercise Therapy - instrumentation
Exercise Therapy - methods
functionally distributed design
Health Promotion - methods
Humans
Internet
Internet telephony
Java
Monitoring
Pharmaceutical technology
Programming Languages
Protocols
Remote Consultation - methods
self-describing strategy
Software
Therapy, Computer-Assisted - methods
Time factors
User-Computer Interface
Virtual manufacturing
web-based
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creator Zhihui Wang
Kiryu, T.
description Since machine-based exercise still uses local facilities, it is affected by time and place. We designed a web-based system architecture based on the Java 2 Enterprise Edition that can accomplish continuously supported machine-based exercise. In this system, exercise programs and machines are loosely coupled and dynamically integrated on the site of exercise via the Internet. We then extended the conventional health promotion model, which contains three types of players (users, exercise trainers, and manufacturers), by adding a new player: exercise program creators. Moreover, we developed a self-describing strategy to accommodate a variety of exercise programs and provide ease of use to users on the web. We illustrate our novel design with examples taken from our feasibility study on a web-based cycle ergometer exercise system. A biosignal-based workload control approach was introduced to ensure that users performed appropriate exercise alone
doi_str_mv 10.1109/TITB.2005.863868
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source IEEE Electronic Library (IEL)
subjects Biosignal-based workload control
Communication system control
Control systems
Electronic mail
exercise system
Exercise Therapy - instrumentation
Exercise Therapy - methods
functionally distributed design
Health Promotion - methods
Humans
Internet
Internet telephony
Java
Monitoring
Pharmaceutical technology
Programming Languages
Protocols
Remote Consultation - methods
self-describing strategy
Software
Therapy, Computer-Assisted - methods
Time factors
User-Computer Interface
Virtual manufacturing
web-based
title A java-based enterprise system architecture for implementing a continuously supported and entirely web-based exercise solution
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