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SOA-BD: Service Oriented Architecture for Biomedical Devices
Lacerda, João Marcos Teixeira; Paiva, Jailton Carlos de; Carvalho, Diego Rodrigues de; Morais, Philippi Sedir Grilo de; Fernandes, Yáskara Ygara Menescal Pinto; Valentim, Ricardo Alexsandro de Medeiros.
Affiliation
  • Lacerda, João Marcos Teixeira; Federal University of Rio Grande do Norte. Laboratory for Technological Innovation in Healthcare. Natal. BR
  • Paiva, Jailton Carlos de; Federal University of Rio Grande do Norte. Laboratory for Technological Innovation in Healthcare. Natal. BR
  • Carvalho, Diego Rodrigues de; Federal University of Rio Grande do Norte. Laboratory for Technological Innovation in Healthcare. Natal. BR
  • Morais, Philippi Sedir Grilo de; Federal University of Rio Grande do Norte. Laboratory for Technological Innovation in Healthcare. Natal. BR
  • Fernandes, Yáskara Ygara Menescal Pinto; Federal University of Rio Grande do Norte. Laboratory for Technological Innovation in Healthcare. Natal. BR
  • Valentim, Ricardo Alexsandro de Medeiros; Federal University of Rio Grande do Norte. Laboratory for Technological Innovation in Healthcare. Natal. BR
Res. Biomed. Eng. (Online) ; 33(2): 166-172, Apr.-June 2017. tab, graf
Article de En | LILACS | ID: biblio-1040969
Bibliothèque responsable: BR1.1
ABSTRACT

Introduction:

The communication of information systems with biomedical devices has become complex not only due to the existence of several private communication protocols, but also to the immutable way that software is embedded into these devices. In this sense, this paper proposes a service-oriented architecture to access biomedical devices as a way to abstract the mechanisms of writing and reading data from these devices, thus contributing to enable the focus of the development team of biomedical software to be intended for its functional requirements, i.e. business rules relevant to the problem domain. Methods The SOA-BD architecture consists of five main components A Web Service for transport and conversion of the device data, Communication Protocols to access the devices, Data Parsers to preprocess data, a Device Repository to store data and transmitted information and Error handling, for error handling of these information. For the development of SOA-BD, technologies such as the XML language and the Java programming language were used. Besides, Software Engineering concepts such as Design Patterns were also used. For the validation of this work, data has been collected from vital sign monitors in an Intensive Care Unit using HL7 standards. Results The tests obtained a difference of about only 1 second in terms of response time with the use of SOA-BD. Conclusion SOA-BD achieves important results such as the reduction on the access protocol complexity, the opportunity for treating patients over long distances, allowing easier development of monitoring applications and interoperability with biomedical devices from diverse manufacturers.
Mots clés

Texte intégral: 1 Indice: LILACS langue: En Texte intégral: Res. Biomed. Eng. (Online) Thème du journal: Engenharia Biom‚dica Année: 2017 Type: Article

Texte intégral: 1 Indice: LILACS langue: En Texte intégral: Res. Biomed. Eng. (Online) Thème du journal: Engenharia Biom‚dica Année: 2017 Type: Article