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dc.contributor.authorWitheephanich K.
dc.contributor.authorEscano J.M.
dc.contributor.authorMunoz De La Pena D.
dc.contributor.authorHayes M.J.
dc.date.accessioned2021-04-05T03:32:51Z-
dc.date.available2021-04-05T03:32:51Z-
dc.date.issued2014
dc.identifier.issn19328184
dc.identifier.other2-s2.0-84913529312
dc.identifier.urihttps://ir.swu.ac.th/jspui/handle/123456789/14010-
dc.identifier.urihttps://www.scopus.com/inward/record.uri?eid=2-s2.0-84913529312&doi=10.1109%2fJSYST.2013.2271388&partnerID=40&md5=98e84f745aa51ab251b2ca3d63898856
dc.description.abstractThis paper addresses the problem of transmission power control within a network of resource-constrained wireless sensors that operate within a particular ambient healthcare environment. Sensor data transmitted to a remote base station within the network arrive subject to node location, orientation, and movement. Power is optimally allocated to all channels using a novel resource efficient algorithm. The proposed algorithm is based on a computationally efficient min-max model predictive controller that uses an uncertain linear state-space model of the tracking error that is estimated via local received signal strength feedback. An explicit solution for the power controller is computed offline using a multiparametric quadratic solver. It is shown that the proposed design leads to a robust control law that can be implemented quite readily on a commercial sensor node platform where computational and memory resources are extremely limited. The design is validated using a fully IEEE 802.15.4 compliant testbed using Tmote Sky sensor nodes mounted on fully autonomous MIABOT Pro miniature mobile robots. A repeatable representative selection of scaled ambulatory scenarios is presented that is quite typical of the data that will be generated in this space. The experimental results illustrate that the algorithm performs optimal power assignments, thereby ensuring a balance between energy consumption and a particular outage-based quality of service requirement while robustly compensating for disturbance uncertainties such as channel fading, interference, quantization error, noise, and nonlinear effects. © 2007-2012 IEEE.
dc.subjectAlgorithms
dc.subjectControllers
dc.subjectEnergy utilization
dc.subjectFading channels
dc.subjectFeedback
dc.subjectMachine design
dc.subjectOutages
dc.subjectPower control
dc.subjectPower management (telecommunication)
dc.subjectPredictive control systems
dc.subjectQuality of service
dc.subjectRobust control
dc.subjectSensor nodes
dc.subjectStandards
dc.subjectState space methods
dc.subjectAffine function
dc.subjectIEEE 802.15.4
dc.subjectMin-max model predictive controls
dc.subjectMulti-parametric programming
dc.subjectReceived signal strength indicators
dc.subjectWireless sensor
dc.subjectWireless sensor network (WSNs)
dc.subjectModel predictive control
dc.titleA min-max model predictive control approach to robust power management in ambulatory wireless sensor networks
dc.typeArticle
dc.rights.holderScopus
dc.identifier.bibliograpycitationIEEE Systems Journal. Vol 8, No.4 (2014), p.1060-1073
dc.identifier.doi10.1109/JSYST.2013.2271388
Appears in Collections:Scopus 1983-2021

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