This paper aims to develop a multisensor data fusion technology-based smart home system by integrating wearable intelligent technology, artificial intelligence, and sensor fusion technology. We have developed the following three systems to create an intelligent smart home environment: (1) a wearable motion sensing device to be placed on residents’ wrists and its corresponding 3D gesture recognition algorithm to implement a convenient automated household appliance control system; (2) a wearable motion sensing device mounted on a resident’s feet and its indoor positioning algorithm to realize an effective indoor pedestrian navigation system for smart energy management; (3) a multisensor circuit module and an intelligent fire detection and alarm algorithm to realize a home safety and fire detection system. In addition, an intelligent monitoring interface is developed to provide in real-time information about the smart home system, such as environmental temperatures, CO concentrations, communicative environmental alarms, household appliance status, human motion signals, and the results of gesture recognition and indoor positioning. Furthermore, an experimental testbed for validating the effectiveness and feasibility of the smart home system was built and verified experimentally. The results showed that the 3D gesture recognition algorithm could achieve recognition rates for automated household appliance control of 92.0%, 94.8%, 95.3%, and 87.7% by the 2-fold cross-validation, 5-fold cross-validation, 10-fold cross-validation, and leave-one-subject-out cross-validation strategies. For indoor positioning and smart energy management, the distance accuracy and positioning accuracy were around 0.22% and 3.36% of the total traveled distance in the indoor environment. For home safety and fire detection, the classification rate achieved 98.81% accuracy for determining the conditions of the indoor living environment.
A previous optimal chemical-mechanical model (C.-S. Poon. J. Appl. Physiol. 62: 2447-2459, 1987) suggested that the normal ventilatory responses to CO2 and exercise inputs and mechanical loading can be predicted by the minimization of a controller objective function consisting of the total chemical and mechanical costs of breathing. In this study the model was generalized to include a description of the inspiratory neuromuscular drive as the control output. With a mechanical work rate index for both inspiration and expiration, the general optimization model accurately reproduced the observed responses in the waveshape of inspiratory drive, breathing pattern, and total ventilation under differing conditions of CO2 inhalation, exercise, and inspiratory/expiratory mechanical loads. The simulation results are in general agreement with a wide range of respiratory phenomena, including exercise hyperpnea, CO2 chemoreflex, and post-inspiratory (postinflow) inspiratory activity, as well as respiratory neural compensations for mechanical loading, respiratory muscle fatigue, and muscle weakness.
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