An improved extreme learning machine model for the prediction of human scenarios in smart homes

One of the main objectives of smart homes is healthcare monitoring and assistance, especially for elderly and disabled people. Therefore, an accurate prediction of the inhabitant behavior is very helpful to provide the required assistance. This work aims to propose a prediction model that satisfies the accuracy as well as the rapidity of the learning phase. To do so, we propose to improve the existing extreme learning machine (ELM) model by defining a recurrent form. This form ensures a temporal relationship of inputs between observations at different time steps. The new model uses feedback connections to the input layer from the output layer which allows the output to be included in the long-term prediction. A recurrent dynamic network, with feedback connections of the output of the network, is proposed to predict the future series representing future activities of the inhabitant. The resulting model, called Recurrent Extreme Learning Machine (RELM), provides the ability to learn the human behavior and ensures a good balance between the learning time and the prediction accuracy. The input data is based on the real data representing the activities of persons belonging to the profile of first level (i.e. P1) as measured by the dependency model called Functional Autonomy Measurement System (SMAF) used in the geriatric domain. The experimental results reveal that the proposed RELM model requires a minimum time during the learning phase with a better performance compared to existing models.

[1]  Yu Huang,et al.  Integrated optimization model of laser brazing by extreme learning machine and genetic algorithm , 2016, The International Journal of Advanced Manufacturing Technology.

[2]  Rong Xie,et al.  Activity recognition and intensity estimation in youth from accelerometer data aided by machine learning , 2016, Applied Intelligence.

[3]  Naif Alajlan,et al.  Differential Evolution Extreme Learning Machine for the Classification of Hyperspectral Images , 2014, IEEE Geoscience and Remote Sensing Letters.

[4]  Carla L Graf,et al.  The Lawton instrumental activities of daily living (IADL) scale. , 2008, Medsurg nursing : official journal of the Academy of Medical-Surgical Nurses.

[5]  Huiru Zheng,et al.  Human Activity Detection in Smart Home Environment with Self-Adaptive Neural Networks , 2008, 2008 IEEE International Conference on Networking, Sensing and Control.

[6]  Young-Koo Lee,et al.  A Smoothed Naive Bayes-Based Classifier for Activity Recognition , 2010 .

[7]  J. C. A. Barata,et al.  The Moore–Penrose Pseudoinverse: A Tutorial Review of the Theory , 2011, 1110.6882.

[8]  Philippe Roose,et al.  An Improved Elman Neural Network for Daily Living Activities Recognition , 2016, ISDA.

[9]  Zhigang Liu,et al.  Posture recognition algorithm for the elderly based on BP neural networks , 2015, The 27th Chinese Control and Decision Conference (2015 CCDC).

[10]  Ahmad Lotfi,et al.  Smart homes for the elderly dementia sufferers: identification and prediction of abnormal behaviour , 2012, J. Ambient Intell. Humaniz. Comput..

[11]  Qiang Shen,et al.  Extreme Learning Machine for Mammographic Risk Analysis , 2010 .

[12]  Hong Yan,et al.  Fast prediction of protein-protein interaction sites based on Extreme Learning Machines , 2014, Neurocomputing.

[13]  Jozsef Suto,et al.  Human activity recognition using neural networks , 2014, Proceedings of the 2014 15th International Carpathian Control Conference (ICCC).

[14]  Guoqiang Peter Zhang,et al.  Time series forecasting using a hybrid ARIMA and neural network model , 2003, Neurocomputing.

[15]  P. Subashini,et al.  Combining Zernike moments with Regional features for classification of handwritten ancient Tamil scripts using Extreme Learning Machine , 2013, 2013 IEEE International Conference ON Emerging Trends in Computing, Communication and Nanotechnology (ICECCN).

[16]  Young-Koo Lee,et al.  EEM: evolutionary ensembles model for activity recognition in Smart Homes , 2012, Applied Intelligence.

[17]  Qiang Shen,et al.  Extreme learning machine for mammographie risk analysis , 2010, 2010 UK Workshop on Computational Intelligence (UKCI).

[18]  M. Tousignant,et al.  [Development of indicators to promote measures for the prevention and rehabilitation of functional decline in older people]. , 2012, Revue d'epidemiologie et de sante publique.

[19]  Mehdi Adda,et al.  Smart Home Design for Disabled People based on Neural Networks , 2014, EUSPN/ICTH.

[20]  Wenyin Gong,et al.  Self-adaptive Differential Evolution Extreme Learning Machine and Its Application in Water Quality Evaluation , 2015 .

[21]  Gaige Wang,et al.  Self-adaptive extreme learning machine , 2015, Neural Computing and Applications.

[22]  Michel Tousignant,et al.  Développement d’indicateurs pour valoriser des actions de prévention et de réadaptation de la perte d’autonomie des personnes âgées , 2012 .

[23]  Ahmad Lotfi,et al.  Behavioural pattern identification and prediction in intelligent environments , 2013, Appl. Soft Comput..

[24]  Chee Kheong Siew,et al.  Extreme learning machine: Theory and applications , 2006, Neurocomputing.

[25]  Guang-Bin Huang,et al.  Trends in extreme learning machines: A review , 2015, Neural Networks.

[26]  Karl Aberer,et al.  Robust Online Time Series Prediction with Recurrent Neural Networks , 2016, 2016 IEEE International Conference on Data Science and Advanced Analytics (DSAA).

[27]  M. C. Soriano,et al.  A Unified Framework for Reservoir Computing and Extreme Learning Machines based on a Single Time-delayed Neuron , 2015, Scientific Reports.

[28]  Tobias Teich,et al.  Design of a Prototype Neural Network for Smart Homes and Energy Efficiency , 2014 .

[29]  Ferhat Özgür Çatak,et al.  Classification with boosting of extreme learning machine over arbitrarily partitioned data , 2015, Soft Computing.

[30]  Sharat C. Prasad,et al.  Deep Recurrent Neural Networks for Time Series Prediction , 2014, ArXiv.

[31]  Per Lynggaard,et al.  Smart Cities and the Ageing Population , 2014 .

[32]  Jozsef Suto,et al.  Activity Recognition in Adaptive Assistive Systems Using Artificial Neural Networks , 2016 .

[33]  XuanLong Nguyen,et al.  Stochastic gradient based extreme learning machines for stable online learning of advanced combustion engines , 2016, Neurocomputing.

[34]  Tayeb Lemlouma,et al.  Context-Aware Adaptive Framework for e-Health Monitoring , 2015, 2015 IEEE International Conference on Data Science and Data Intensive Systems.

[35]  Manas Ranjan Senapati,et al.  An adaptive local linear optimized radial basis functional neural network model for financial time series prediction , 2015, Neural Computing and Applications.

[36]  Philippe Roose,et al.  A Markovian-based Approach for Daily Living Activities Recognition , 2016, SENSORNETS.

[37]  Md. Zia Uddin,et al.  Independent shape component-based human activity recognition via Hidden Markov Model , 2010, Applied Intelligence.

[38]  Lei He,et al.  BP Neural Network for Human Activity Recognition in Smart Home , 2012, 2012 International Conference on Computer Science and Service System.

[39]  Carla L Graf,et al.  The Lawton Instrumental Activities of Daily Living (IADL) Scale. , 2008, Medsurg nursing : official journal of the Academy of Medical-Surgical Nurses.

[40]  Christof Teuscher,et al.  A Comparative Study of Reservoir Computing for Temporal Signal Processing , 2014, ArXiv.