Architecture Integrating Wireless Body Area Networks with Web Services for Ubiquitous Healthcare Service Provisioning
Recent advancements in sensor technologies and
Wireless Body Area Networks (WBANs) have led to the
development of cost-effective healthcare devices which can be used
to monitor and analyse a person-s physiological parameters from
remote locations. These advancements provides a unique opportunity
to overcome current healthcare challenges of low quality service
provisioning, lack of easy accessibility to service varieties, high costs
of services and increasing population of the elderly experienced
globally. This paper reports on a prototype implementation of an
architecture that seamlessly integrates Wireless Body Area Network
(WBAN) with Web services (WS) to proactively collect
physiological data of remote patients to recommend diagnostic
services. Technologies based upon WBAN and WS can provide
ubiquitous accessibility to a variety of services by allowing
distributed healthcare resources to be massively reused to provide
cost-effective services without individuals physically moving to the
locations of those resources. In addition, these technologies can
reduce costs of healthcare services by allowing individuals to access
services to support their healthcare. The prototype uses WBAN body
sensors implemented on arduino fio platforms to be worn by the
patient and an android smart phone as a personal server. The
physiological data are collected and uploaded through GPRS/internet
to the Medical Health Server (MHS) to be analysed. The prototype
monitors the activities, location and physiological parameters such as
SpO2 and Heart Rate of the elderly and patients in rehabilitation.
Medical practitioners would have real time access to the uploaded
information through a web application.
[1] Bouten, C., Koekkoek, K., Verduin, M., Kodde, R. and Janssen, J.
(1997). A triaxial accelerometer and portable data processing unit for
the assessment of daily physical activity. IEEE Transactions on
Biomedical Engineering, 44(3), 136 - 147.
[2] Hao, Y. and Foster, R. (2008). Wireless body sensor networks for
health-monitoring. Physiological Measurement, 29(11), 27 - 56.
[3] Jovanov, E., Milenkovic, A., Otto, C. and De Groen, P.C. (2005). A
wireless body area network of intelligent motion sensors for computer
assisted physical rehabilitation. Journal of Neuro Engineering and
Rehabilitation, 2005, 2(1), 6
[4] Jung, J., Ha, K., Lee, J., Kim, Y. and Kim, D. (2008). Wireless body
area network in a ubiquitous healthcare system for physiological signal
monitoring and health consulting. International Journal of Signal
Processing, Image Processing and Pattern Recognition, 1(1), 47 - 54.
[5] Kim, S. (2002). Ubiquitous healthcare: the OnkoNet mobile agents
architecture. Proceeding Workshop on Mobile Computing in Medicine,
105 - 118.
[6] Konstantas, D. and Herzog, R. (2003). Continuous monitoring of vital
constants for mobile users: the MobiHealth approach. Proceedings of
the 25th Annual International Conference of the IEEE EMBS, Cancun,
Mexico. 4(25) 3728 - 3731.
[7] Konstantas, D. (2007). An overview of wearable and implantable
medical sensors. Year book of Medical Informatics (2007) 66 - 69.
[8] Latre, B., Braem, B., Moerman, I., Blondia, C. and Demeester, P.
(2011). A survey on wireless body area networks. Journal of Wireless
Networks, 17(1), 1 - 18.
[9] Mendelson, M., Duckworth, R.J. and Comtois, G. (2006). A Wearable
Reflectance Pulse Oximeter for Remote Physiological Monitoring. 2006
International Conference of the IEEE Engineering in Medicine and
Biology Society (2006), 912 - 915.
[10] Morón, M.J., Luque J.R., Gómez-Jaime,A., Casilari, E. and Díaz-
Estrella,A (2009). Prototyping of a remote monitoring system for a
medical Personal Area Network using Python. 3rd International
Conference on Pervasive Computing Technologies for Healthcare, 2009.
PervasiveHealth 1 - 5.
[11] Nikolidakis, S.A., Georgakakis, E., Giotsas, V., Vergados, D.D. and
Douligeris, C. (2010). Secure ubiquitous healthcare system based on
IMS and the HL7 standards. Proceedings of the 3rd International
Conference on Pervasive Technologies Related to Assistive
Environments, (PETRA-10), Samos Greece, 42, 1 - 7.
[12] Olugbara, O.O., Adigun, M.O., Ojo, S.O. and Mudali, P. (2007). Utility
grid computing and body area network as enabler for ubiquitous rural ehealthcare
service provisioning. Proceedings of IEEE 9th International
Conference on e-Health Networking, Application and Services, 19-22
June, 2007, Taipei, Taiwan. 202 - 207.
[13] Olugbara, O.O., Ojo, S.O. and Adigun, M.O. (2011). A Grid enabled
framework for ubiquitous healthcare service provisioning, Advances in
Grid Computing. Zoran Constantinescu (Ed.), InTech, Croatia, ISBN:
978-953-307-301-9, 229-252.
[14] Purwar, A., Jeong, D. and Chung W. (2007). Activity Monitoring from
Real-Time Accelerometer data using sensor Network. International
Conference on Control, Automation and Systems, COEX, Seoul Korea.,
2402 - 2406.
[15] Shaikh, A., Memon, M., Memon, M. and Misbahuddin, M. (2009). The
Role of Service Oriented Architecture in Telemedicine Healthcare
System. International Conference on Complex, Intelligent and Software
Intensive Systems CISIS ÔÇÿ09. IEEE, Fukuoka, Japan, 208 - 214.
[16] Sneha, S., Virginia, L. and Bick, M. (2010). Ubiquitous and Pervasive
Computing in Healthcare. 15th Americas Conference on Information
Systems. San Francisco, California (2010).
[17] Sneha, S and Varshney, U. (2006). Ubiquitous healthcare: a new
frontier in e-health. Proceedings of Americas Conference on Information
Systems (2006), 319.
[18] Tapia, I.D., Rodriguez, S., Bajo, J., Corchado, J.M. and Garcia, O.
(2010). Wireless sensor networks for data acquisition and information
fusion: a case study. 13th IEEE International Conference on Information
Fusion. Salamanca, Spain, 1 - 8.
[19] Tremper, K.K. and Barker, S.J (1989). Pulse oximetry. Anesthesiology,
70(1):98 - 108, January 1989.
[20] Wang, H. Choi,H., Agoulmine, N., Deen, M.J. and Hong, J.W. (2010).
Information-based sensor tasking wireless body area networks in Uhealth
systems. CNSM 2010. 517 - 522.
[21] Watthanawisuth, N., Lomas,L., Wisitsoraat, A. and Tuantranont, A.
(2010). Wireless Wearable Pulse Oximeter for Health Monitoring using
ZigBee Wireless Sensor Network. International conference on Electrical
Engineering/Electronics and Information Technology (ECTI-CON),
Chiang Mai, 575 - 579.
[22] Yick, J. Mukherjee, B. and Ghosal, D. (2008). Wireless sensor networks
survey. Computer Networks, 52. 2292 2330.
[1] Bouten, C., Koekkoek, K., Verduin, M., Kodde, R. and Janssen, J.
(1997). A triaxial accelerometer and portable data processing unit for
the assessment of daily physical activity. IEEE Transactions on
Biomedical Engineering, 44(3), 136 - 147.
[2] Hao, Y. and Foster, R. (2008). Wireless body sensor networks for
health-monitoring. Physiological Measurement, 29(11), 27 - 56.
[3] Jovanov, E., Milenkovic, A., Otto, C. and De Groen, P.C. (2005). A
wireless body area network of intelligent motion sensors for computer
assisted physical rehabilitation. Journal of Neuro Engineering and
Rehabilitation, 2005, 2(1), 6
[4] Jung, J., Ha, K., Lee, J., Kim, Y. and Kim, D. (2008). Wireless body
area network in a ubiquitous healthcare system for physiological signal
monitoring and health consulting. International Journal of Signal
Processing, Image Processing and Pattern Recognition, 1(1), 47 - 54.
[5] Kim, S. (2002). Ubiquitous healthcare: the OnkoNet mobile agents
architecture. Proceeding Workshop on Mobile Computing in Medicine,
105 - 118.
[6] Konstantas, D. and Herzog, R. (2003). Continuous monitoring of vital
constants for mobile users: the MobiHealth approach. Proceedings of
the 25th Annual International Conference of the IEEE EMBS, Cancun,
Mexico. 4(25) 3728 - 3731.
[7] Konstantas, D. (2007). An overview of wearable and implantable
medical sensors. Year book of Medical Informatics (2007) 66 - 69.
[8] Latre, B., Braem, B., Moerman, I., Blondia, C. and Demeester, P.
(2011). A survey on wireless body area networks. Journal of Wireless
Networks, 17(1), 1 - 18.
[9] Mendelson, M., Duckworth, R.J. and Comtois, G. (2006). A Wearable
Reflectance Pulse Oximeter for Remote Physiological Monitoring. 2006
International Conference of the IEEE Engineering in Medicine and
Biology Society (2006), 912 - 915.
[10] Morón, M.J., Luque J.R., Gómez-Jaime,A., Casilari, E. and Díaz-
Estrella,A (2009). Prototyping of a remote monitoring system for a
medical Personal Area Network using Python. 3rd International
Conference on Pervasive Computing Technologies for Healthcare, 2009.
PervasiveHealth 1 - 5.
[11] Nikolidakis, S.A., Georgakakis, E., Giotsas, V., Vergados, D.D. and
Douligeris, C. (2010). Secure ubiquitous healthcare system based on
IMS and the HL7 standards. Proceedings of the 3rd International
Conference on Pervasive Technologies Related to Assistive
Environments, (PETRA-10), Samos Greece, 42, 1 - 7.
[12] Olugbara, O.O., Adigun, M.O., Ojo, S.O. and Mudali, P. (2007). Utility
grid computing and body area network as enabler for ubiquitous rural ehealthcare
service provisioning. Proceedings of IEEE 9th International
Conference on e-Health Networking, Application and Services, 19-22
June, 2007, Taipei, Taiwan. 202 - 207.
[13] Olugbara, O.O., Ojo, S.O. and Adigun, M.O. (2011). A Grid enabled
framework for ubiquitous healthcare service provisioning, Advances in
Grid Computing. Zoran Constantinescu (Ed.), InTech, Croatia, ISBN:
978-953-307-301-9, 229-252.
[14] Purwar, A., Jeong, D. and Chung W. (2007). Activity Monitoring from
Real-Time Accelerometer data using sensor Network. International
Conference on Control, Automation and Systems, COEX, Seoul Korea.,
2402 - 2406.
[15] Shaikh, A., Memon, M., Memon, M. and Misbahuddin, M. (2009). The
Role of Service Oriented Architecture in Telemedicine Healthcare
System. International Conference on Complex, Intelligent and Software
Intensive Systems CISIS ÔÇÿ09. IEEE, Fukuoka, Japan, 208 - 214.
[16] Sneha, S., Virginia, L. and Bick, M. (2010). Ubiquitous and Pervasive
Computing in Healthcare. 15th Americas Conference on Information
Systems. San Francisco, California (2010).
[17] Sneha, S and Varshney, U. (2006). Ubiquitous healthcare: a new
frontier in e-health. Proceedings of Americas Conference on Information
Systems (2006), 319.
[18] Tapia, I.D., Rodriguez, S., Bajo, J., Corchado, J.M. and Garcia, O.
(2010). Wireless sensor networks for data acquisition and information
fusion: a case study. 13th IEEE International Conference on Information
Fusion. Salamanca, Spain, 1 - 8.
[19] Tremper, K.K. and Barker, S.J (1989). Pulse oximetry. Anesthesiology,
70(1):98 - 108, January 1989.
[20] Wang, H. Choi,H., Agoulmine, N., Deen, M.J. and Hong, J.W. (2010).
Information-based sensor tasking wireless body area networks in Uhealth
systems. CNSM 2010. 517 - 522.
[21] Watthanawisuth, N., Lomas,L., Wisitsoraat, A. and Tuantranont, A.
(2010). Wireless Wearable Pulse Oximeter for Health Monitoring using
ZigBee Wireless Sensor Network. International conference on Electrical
Engineering/Electronics and Information Technology (ECTI-CON),
Chiang Mai, 575 - 579.
[22] Yick, J. Mukherjee, B. and Ghosal, D. (2008). Wireless sensor networks
survey. Computer Networks, 52. 2292 2330.
@article{"International Journal of Information, Control and Computer Sciences:51824", author = "Ogunduyile O. Oluwgbenga", title = "Architecture Integrating Wireless Body Area Networks with Web Services for Ubiquitous Healthcare Service Provisioning", abstract = "Recent advancements in sensor technologies and
Wireless Body Area Networks (WBANs) have led to the
development of cost-effective healthcare devices which can be used
to monitor and analyse a person-s physiological parameters from
remote locations. These advancements provides a unique opportunity
to overcome current healthcare challenges of low quality service
provisioning, lack of easy accessibility to service varieties, high costs
of services and increasing population of the elderly experienced
globally. This paper reports on a prototype implementation of an
architecture that seamlessly integrates Wireless Body Area Network
(WBAN) with Web services (WS) to proactively collect
physiological data of remote patients to recommend diagnostic
services. Technologies based upon WBAN and WS can provide
ubiquitous accessibility to a variety of services by allowing
distributed healthcare resources to be massively reused to provide
cost-effective services without individuals physically moving to the
locations of those resources. In addition, these technologies can
reduce costs of healthcare services by allowing individuals to access
services to support their healthcare. The prototype uses WBAN body
sensors implemented on arduino fio platforms to be worn by the
patient and an android smart phone as a personal server. The
physiological data are collected and uploaded through GPRS/internet
to the Medical Health Server (MHS) to be analysed. The prototype
monitors the activities, location and physiological parameters such as
SpO2 and Heart Rate of the elderly and patients in rehabilitation.
Medical practitioners would have real time access to the uploaded
information through a web application.", keywords = "Android Smart phone, Arduino Fio, Web application
server, Wireless Body Area Networks.", volume = "6", number = "12", pages = "1604-8", }
