Applications Based on Service-Oriented Architecture (SOA) in the Field of Home Healthcare
Abstract
:1. Introduction
2. Methods
2.1. Literature Search
2.2. Selection Criteria
3. Service Oriented Architecture: SOA
- Operations: Units of functions operating on received data, having specific interfaces and returning structured responses.
- Services: Logical groupings of operations.
- Business processes: Actions or activities to perform specific business goals by invoking multiple services.
- Infrastructure services: Includes security, management and monitoring.
- Business-neutral services: Includes service brokers and notification, scheduling and workflow services.
- Business services: Includes services based on the business logic.
- Layer 1: Operational systems layer; this layer integrates existing systems using SOA integration techniques.
- Layer 2: Enterprise components layer is responsible for realizing functionality and maintaining the quality of service (QoS) of the exposed services.
- Layer 3: Services layer; in this layer, the services selected to be consumed are located.
- Layer 4: Business processes layer, which defines the services exposed in layer 3.
- Layer 5: Access layer; it is created to provide end-to-end solutions to compositions of services.
- Layer 6: Integration layer; it allows the integration of different services.
- Layer 7: Management and security; it is responsible to monitor, manage and maintain security.
Security in SOA Applications
4. Revised SOA Applications
4.1. SOA Application in Healthcare Industry
4.2. SOA Applications in Home Healthcare
5. Analysis from the Perspective of Implemented Functionalities
5.1. Measured Variables
- Blood pressure: Pressure of the blood on the walls of the arteries as the heart pumps it around the body.
- Heart rate: Speed of the heartbeat.
- Blood sugar: Sugar concentration in the blood.
- Body temperature.
- SpO2: Oxygen saturation in the blood.
- Body composition: Related to fat, weight, and muscle mass.
- Electrocardiogram (ECG): Reading of electrical activity of the heart.
- Photoplethysmograph PPG: It is used to estimate blood flow to the skin using infrared light [53].
- Breathing rate: Number of breaths per minute.
- Acceleration: Used to detect body movements; it helps to detect abnormal behavior.
- Environmental temperature.
- Humidity.
- Dust concentration.
- Pollution.
5.2. Semantic Interoperability
6. Analysis from the Perspective of Security Implementations
7. Conclusions
Conflicts of Interest
References
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Key Words | Database | Results |
---|---|---|
Healthcare system using SOA | IEEE | 57 |
Science Direct | 665 | |
Scopus | 326 | |
SOA and healthcare systems | IEEE | 87 |
Science Direct | 665 | |
Scopus | 326 | |
Security aspects in SOA | IEEE | 89 |
Science Direct | 1732 | |
Scopus | 180 | |
SOA architecture | IEEE | 4688 |
Science Direct | 4199 | |
Scopus | 12,985 | |
SOA applications review | IEEE | 84 |
Science Direct | 6366 | |
Scopus | 162 |
Category Sensor | Device | Parameters |
---|---|---|
Physiological sensor | Body scale | Body composition |
Blood pressure monitor | Blood pressure, heart rate | |
Pulse oximenter | SpO2, heart rate, PPG | |
Wearable vital signal monitor | Heart rate, breathing rate, body temperature | |
ECG | Electrical activity of the heart | |
Environmental sensor | Accelerometer | Acceleration, body movements |
Environmental monitor | Environmental temperature, humidity, dust concentration, pollution |
Reference | Physiological Sensor | Environmental Sensor |
---|---|---|
Vaidehi et al. [3] | Blood Pressure, Heart Rate, Body Temperature, SpO2, ECG, Breathing rate | N/A |
Ganapathy et al. [6] | Blood Pressure, Heart Rate | N/A |
Omar et al. [28] | Blood pressure | N/A |
Lee et al. [29] | SpO2, Body Composition, Blood Sugar, Blood pressure | N/A |
Hein et al. [30] | Blood Pressure, SpO2, ECG | N/A |
Koutkias et al. [31] | Blood Pressure, Heart Rate | N/A |
Rao et al. [32] | Blood Pressure, Heart Rate, SpO2 | N/A |
Rocha et al. [33] | Body Temperature, SpO2, ECG, PPG | Acceleration |
Benharref et al. [34] | Blood Pressure, Heart Rate, Blood Sugar, Body Temperature, SpO2 | N/A |
Gazzarata et al. [35] | Blood Pressure, Heart Rate, Body Temperature, SpO2, Body Composition | Environmental temperature, Humidity, Dust concentration, Pollution |
Yeh [36] | ECG, Blood pressure, Temperature | Humidity |
Gope et al. [37] | ECG, Blood pressure, Temperature | N/A |
Fortino et al. [38] | ECG, PPG | N/A |
Meng et al. [39] | N/A | Acceleration |
Tan et al. [40] | N/A | Acceleration |
Kañtoch [41] | ECG, PPG | N/A |
Kañtoch [42] | ECG, Temperature | Humidity |
Nandkistor et al. [43] | ECG, Temperature, Heart rate | N/A |
Andres et al. [44] | ECG, Blood Pressure, SpO2 | N/A |
Singh et al. [45] | ECG | Acceleration |
Chen et al. [46] | Blood Pressure, ECG | N/A |
Hofer et al. [47] | Blood Pressure, Heart Rate, Body Temperature, SpO2 | Acceleration |
Ganapathy et al. [48] | Heart Rate, ECG, Breathing rate | Acceleration |
Abousharkh et al. [49] | ECG, Blood Pressure, Body Temperature, SpO2, Heart Rate | N/A |
Abousharkh et al. [50] | ECG, Blood Pressure, Body Temperature, SpO2, Heart Rate | N/A |
Iancu-Constantin et al. [51] | ECG, Blood Pressure, SpO2, Heart Rate | Acceleration |
Bazzani et al. [52] | Blood Pressure, Blood Sugar, Body Temperature, SpO2 | N/A |
Reference | Type of Solution | Standards Used |
---|---|---|
[54] | 2 types of intermediate agents | Not defined |
[55] | 3 types of intermediate agents | XML |
[56] | Mid-tier agents | RDF, OWL |
[57] | Ontology mappers | OWL |
[58] | Semantic mediator layer | RDF, SPARQL |
[59] | Ontology to represent concepts and data | XML |
[60] | Ontology decoders and encoders based on cloud | XML, RDF |
Reference | Reference Year | How Security Was Implemented? |
---|---|---|
Hein et al. [30] | 2009 | Data encryption |
Koutkias et al. [31] | 2010 | DPWS protocol |
Benharref et al. [34] | 2014 | HTTPS |
Gazzarata et al. [35] | 2014 | HTTPS |
Yeh [36] | 2016 | Login |
Gope et al. [37] | 2016 | Login |
Hofer et al. [47] | 2015 | Login |
Ganapathy et al. [48] | 2013 | Login |
Abousharkh et al. [49] | 2012 | Login |
Iancu-Constantin et al. [51] | 2015 | Data encryption, login |
Bazzani et al. [52] | 2012 | Data encryption, login |
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Avila, K.; Sanmartin, P.; Jabba, D.; Jimeno, M. Applications Based on Service-Oriented Architecture (SOA) in the Field of Home Healthcare. Sensors 2017, 17, 1703. https://doi.org/10.3390/s17081703
Avila K, Sanmartin P, Jabba D, Jimeno M. Applications Based on Service-Oriented Architecture (SOA) in the Field of Home Healthcare. Sensors. 2017; 17(8):1703. https://doi.org/10.3390/s17081703
Chicago/Turabian StyleAvila, Karen, Paul Sanmartin, Daladier Jabba, and Miguel Jimeno. 2017. "Applications Based on Service-Oriented Architecture (SOA) in the Field of Home Healthcare" Sensors 17, no. 8: 1703. https://doi.org/10.3390/s17081703
APA StyleAvila, K., Sanmartin, P., Jabba, D., & Jimeno, M. (2017). Applications Based on Service-Oriented Architecture (SOA) in the Field of Home Healthcare. Sensors, 17(8), 1703. https://doi.org/10.3390/s17081703