E-Book, Englisch, 221 Seiten
Yurur / Liu Generic and Energy-Efficient Context-Aware Mobile Sensing
Erscheinungsjahr 2014
ISBN: 978-1-4987-0011-5
Verlag: CRC Press
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
E-Book, Englisch, 221 Seiten
ISBN: 978-1-4987-0011-5
Verlag: CRC Press
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
Elaborating on the concept of context awareness, this book presents up-to-date research and novel framework designs for context-aware mobile sensing. Generic and Energy-Efficient Context-Aware Mobile Sensing proposes novel context-inferring algorithms and generic framework designs that can help readers enhance existing tradeoffs in mobile sensing, especially between accuracy and power consumption.
The book presents solutions that emphasize must-have system characteristics such as energy efficiency, accuracy, robustness, adaptability, time-invariance, and optimal sensor sensing. Numerous application examples guide readers from fundamental concepts to the implementation of context-aware-related algorithms and frameworks.
Covering theory and practical strategies for context awareness in mobile sensing, the book will help readers develop the modeling and analysis skills required to build futuristic context-aware framework designs for resource-constrained platforms.
- Includes best practices for designing and implementing practical context-aware frameworks in ubiquitous/mobile sensing
- Proposes a lightweight online classification method to detect user-centric postural actions
- Examines mobile device-based battery modeling under the scope of battery nonlinearities with respect to variant loads
- Unveils a novel discrete time inhomogeneous hidden semi-Markov model (DT-IHS-MM)-based generic framework to achieve a better realization of HAR-based mobile context awareness
Supplying theory and equation derivations for all the concepts discussed, the book includes design tips for the implementation of smartphone programming as well as pointers on how to make the best use of MATLAB® for the presentation of performance analysis. Coverage includes lightweight, online, and unsupervised pattern recognition methods; adaptive, time-variant, and optimal sensory sampling strategies; and energy-efficient, robust, and inhomogeneous context-aware framework designs.
Researchers will learn the latest modeling and analysis research on mobile sensing. Students will gain access to accessible reference material on mobile sensing theory and practice. Engineers will gain authoritative insights into cutting-edge system designs.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Context Awareness for Mobile Sensing
Introduction
Context Awareness Essentials Contextual Information Context Representation ContextModeling Context-Aware Middleware Context Inference Context-Aware Framework Designs
Context-Aware Applications Health Care andWell-Being Based Human Activity Recognition Based Transportation and Location Based Social Networking Based Environmental Based
Challenges and Future Trends Energy Awareness Adaptive and Opportunistic Sensory Sampling Modeling the Smart Device Battery Behavior for Energy Optimizations Data Calibration and Robustness Efficient Context Inference Algorithms Generic Context-Aware Framework Designs Standard Context-Aware Middleware Solutions Mobile Cloud Computing Security, Privacy, and Trust
Context Inference: Posture Detection
Discussions
Proposed Classification Method
Standalone Mode
Assisting Mode Feature Extraction Pattern Recognition–Based Classification Gaussian Mixture Model k-Nearest Neighbors Search Linear Discriminant Analysis Online Processing: Dynamic Training Statistical Tool–Based Classification
Performance Evaluation
Context-Aware Framework: A Basic Design
Discussions
Proposed Framework Preliminaries User State Representation System Adaptability Time-Variant User State Transition Matrix Time-Variant Observation Emission Matrix Update on System Parameters Entropy Rate Scaling Problem
Simulations Preparations Applied Process Power Consumption Model Accuracy Model Parameter Setups Results and Discussions
Validation by a Smartphone Application Observation Analysis Construction of Observation Emission Matrix Applied Process Performance Evaluation
Energy Efficiency in Physical Hardware
Discussions
Battery Modeling
Modeling of Energy Consumption by Sensors Preliminaries Modeling of Sensory Operations
Validation by a Smartphone Application
Sensor Management Battery Case Sensor Utilization Case
Performance Analysis Method I (MI) Method II (MII) Method III (MIII)
Context-Aware Framework: A Complex Design
Proposed Framework
Context Inference Module Inhomogeneous Statistical Machine Basic Definitions and Inhomogeneity Underlying Process User State Representation Time-Variant User State TransitionMatrix Adaptive Observation Emission Matrix Accuracy Notifier and Definition of Actions
Sensor Management Module Sensor Utilization Trade-Off Analysis Intuitive Solutions Method I (MI) Method II (MII) Method III (MIII) Constrained Markov Decision Process–Based Solution Partially Observable Markov Decision
Process–Based Solution Myopic Strategy and Sufficient Statistics
Performance Evaluation
Probabilistic Context Modeling
Construction of Hidden Markov Models General Model Parallel HMMs Factorial HMMs Coupled/Joint HMMs Observation Decomposed/Multiple Observation HMMs Hierarchical HMMs Dynamic Bayesian Networks
Evaluation
Inference Learning: Forward–Backward Procedure Extended Forward–Backward Procedure
Model for Multiple Sensors Use
Appendix
References
Index
