2012
DOI: 10.2174/2210327911101020102
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The OPPORTUNITY Framework and Data Processing Ecosystem for Opportunistic Activity and Context Recognition

Abstract: Opportunistic sensing can be used to obtain data from sensors that just happen to be present in the user's surroundings. By harnessing these opportunistic sensor configurations to infer activity or context, ambient intelligence environments become more robust, have improved user comfort thanks to reduced requirements on body-worn sensor deployment and they are not limited to a predefined and restricted location, defined by sensors specifically deployed for an application. We present the OPPORTUNITY Framework a… Show more

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Cited by 28 publications
(15 citation statements)
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“…Noticeably, the effect of this process is similar to what is achieved by approaches addressing the concept drift problem (Widmer and Kubat, 1996) in activity classification, as in (Kurz and Ferscha, 2010). Concept drift addresses slow changes in the mapping between sensor signals and activity classes in the feature space.…”
Section: Discussionmentioning
confidence: 77%
“…Noticeably, the effect of this process is similar to what is achieved by approaches addressing the concept drift problem (Widmer and Kubat, 1996) in activity classification, as in (Kurz and Ferscha, 2010). Concept drift addresses slow changes in the mapping between sensor signals and activity classes in the feature space.…”
Section: Discussionmentioning
confidence: 77%
“…In our case, the estimated shift provides a direct estimation of the changes in the feature distribution [2]. Such measure can be used to infer an online estimation of the system reliability, a critical point for systems that have to deal with dynamic changing environments [13,21]. For example, if a sensor is considered non reliable (e.g., when the estimated shift Θ exceeds a given threshold), compensatory actions can be taken, such as its removal from a sensor network [13,23,22].…”
Section: Discussionmentioning
confidence: 99%
“…Such measure can be used to infer an online estimation of the system reliability, a critical point for systems that have to deal with dynamic changing environments [13,21]. For example, if a sensor is considered non reliable (e.g., when the estimated shift Θ exceeds a given threshold), compensatory actions can be taken, such as its removal from a sensor network [13,23,22]. Figure 10 shows how the mean and standard deviation of the estimated shift correlates with the change in performance with respect to the original location, for both sensor displacement and rotation.…”
Section: Discussionmentioning
confidence: 99%
“…Many works have also addressed the prediction of what an inhabitant will do in the near future, in order to enable planning and scheduling of services ahead of time [4,15], for instance, to implement energy-efficient control of appliances [16,17]. Typically, activity recognition solutions rely on static sensors placed throughout an environment [15,[18][19][20][21], but more recently frameworks have been produced to recognize human activities with limited guarantees about placement, nature and run-time availability of sensors, including static and wearable ones [22,23]. However, the strict computational and energy constraints imposed by WSN-based environments have constituted a major obstacle to translating the full potential benefits of these results in robotic ecologies.…”
Section: Learningmentioning
confidence: 99%