Tracking and behavior augmented activity recognition for multiple inhabitants
We develop CACE (Constraints And Correlations mining Engine), a framework that significantly improves the recognition accuracy of complex daily activities in multi-inhabitant smarthomes. CACE views the implicit relationships between the activities of multiple people as an asset, and exploits such co...
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2021
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sg-smu-ink.sis_research-79102022-02-07T02:36:02Z Tracking and behavior augmented activity recognition for multiple inhabitants UL ALAM, Mohammad Arif ROY, Nirmalya MISRA, Archan We develop CACE (Constraints And Correlations mining Engine), a framework that significantly improves the recognition accuracy of complex daily activities in multi-inhabitant smarthomes. CACE views the implicit relationships between the activities of multiple people as an asset, and exploits such constraints and correlations in a hierarchical fashion, taking advantage of both person-specific sensor data (generated by wearable devices) and person-independent ambient sensor data (generated by ambient sensors). To effectively utilize such couplings, CACE first uses a multi-target particle filtering approach over ambient sensors captured movement data, to identify the number of distinct users and infer individual-specific movement trajectories. We then utilize a Hierarchical Dynamic Bayesian Network (HDBN)-based model for activity recognition. This model utilizes the inter-and-intra individual correlations and constraints, at both micro-activity and macro-activity levels, to recognize individual activities accurately. These constraints are learnt automatically using data-mining techniques, and help to dramatically reduce the computational complexity of HDBN-based inferencing. Empirical studies using a real-world testbed of five multi-inhabitant smarthomes shows that CACE is able to achieve an activity recognition accuracy of approximate to 95%, with a 16-fold reduction in computational overhead compared to traditional hybrid classification approaches. 2021-01-01T08:00:00Z text https://ink.library.smu.edu.sg/sis_research/6907 info:doi/10.1109/TMC.2019.2936382 Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University Multiple inhabitants multi-modal sensing scalable activity recognition tracking Numerical Analysis and Scientific Computing Software Engineering |
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Multiple inhabitants multi-modal sensing scalable activity recognition tracking Numerical Analysis and Scientific Computing Software Engineering |
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Multiple inhabitants multi-modal sensing scalable activity recognition tracking Numerical Analysis and Scientific Computing Software Engineering UL ALAM, Mohammad Arif ROY, Nirmalya MISRA, Archan Tracking and behavior augmented activity recognition for multiple inhabitants |
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We develop CACE (Constraints And Correlations mining Engine), a framework that significantly improves the recognition accuracy of complex daily activities in multi-inhabitant smarthomes. CACE views the implicit relationships between the activities of multiple people as an asset, and exploits such constraints and correlations in a hierarchical fashion, taking advantage of both person-specific sensor data (generated by wearable devices) and person-independent ambient sensor data (generated by ambient sensors). To effectively utilize such couplings, CACE first uses a multi-target particle filtering approach over ambient sensors captured movement data, to identify the number of distinct users and infer individual-specific movement trajectories. We then utilize a Hierarchical Dynamic Bayesian Network (HDBN)-based model for activity recognition. This model utilizes the inter-and-intra individual correlations and constraints, at both micro-activity and macro-activity levels, to recognize individual activities accurately. These constraints are learnt automatically using data-mining techniques, and help to dramatically reduce the computational complexity of HDBN-based inferencing. Empirical studies using a real-world testbed of five multi-inhabitant smarthomes shows that CACE is able to achieve an activity recognition accuracy of approximate to 95%, with a 16-fold reduction in computational overhead compared to traditional hybrid classification approaches. |
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text |
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UL ALAM, Mohammad Arif ROY, Nirmalya MISRA, Archan |
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UL ALAM, Mohammad Arif ROY, Nirmalya MISRA, Archan |
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UL ALAM, Mohammad Arif |
| title |
Tracking and behavior augmented activity recognition for multiple inhabitants |
| title_short |
Tracking and behavior augmented activity recognition for multiple inhabitants |
| title_full |
Tracking and behavior augmented activity recognition for multiple inhabitants |
| title_fullStr |
Tracking and behavior augmented activity recognition for multiple inhabitants |
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Tracking and behavior augmented activity recognition for multiple inhabitants |
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tracking and behavior augmented activity recognition for multiple inhabitants |
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Institutional Knowledge at Singapore Management University |
| publishDate |
2021 |
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https://ink.library.smu.edu.sg/sis_research/6907 |
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