Novel Deep-Learning Algorithms for the Internet of Things with Smart Applications – An Exploratory Study
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2018-12-09 https://doi.org/10.14419/ijet.v7i4.36.23741 -
Big data, Deep learning, Internet of Things, Machine learning, Smart Applications -
Abstract
The establishment of internetworked mobile and embedded applications leads to vision of the Internet of Things (IoT). It gives rise to a world enriched with sensor devices. The day to day corporeal possessions in our everyday situation are progressively enhanced with computing, detecting and communication competencies. Such proficiencies assure to transfigure the interfaces between individuals and physical objects. Such momentous research exertions have been expended toward developing smarter and more user-friendly solicitations on mobile and embedded expedients and sensors. Also, modern progress in deep learning has significantly reformed the approach that computing strategies process human-centric parameters such as images and audio-visual applications. Application of deep neural networks to IoT devices is proficient in the accomplishment of multifaceted sensing and recognition errands to upkeep a new demesne of communications between humans and their physical environments. This paper investigates various forms of deep learning algorithms in Big data processing and applications using smart IoT devices. The integration of process science with data science is studied and the real-time user-friendly solicitations involving Big data analytics and the Internet of Things is summarized.
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References
[1] Van der Aalst, W. and Damiani, E., 2015. Processes meet big data: Connecting data science with process science. IEEE Transactions on Services Computing, 8(6), pp.810-819.
[2] Brahma, P.P., Wu, D. and She, Y., 2016. Why Deep Learning Works: A Manifold Disentanglement Perspective. IEEE Trans. Neural Netw. Learning Syst., 27(10), pp.1997-2008.
[3] Chen, C.P., Zhang, C.Y., Chen, L. and Gan, M., 2015. Fuzzy restricted Boltzmann machine for the enhancement of deep learning. IEEE Transactions on Fuzzy Systems, 23(6), pp.2163-2173.
[4] Cui, L., Yu, F.R. and Yan, Q., 2016. When big data meets software-defined networking: SDN for big data and big data for SDN. IEEE network, 30(1), pp.58-65.
[5] Fadlullah, Z., Tang, F., Mao, B., Kato, N., Akashi, O., Inoue, T. and Mizutani, K., 2017. State-of-the-art deep learning: Evolving machine intelligence toward tomorrow’s intelligent network traffic control systems. IEEE Communications Surveys & Tutorials, 19(4), pp.2432-2455.
[6] Galanti, T., Wolf, L. and Hazan, T., 2016. A theoretical framework for deep transfer learning. Information and Inference: A Journal of the IMA, 5(2), pp.159-209.
[7] Lane, N.D., Bhattacharya, S., Mathur, A., Georgiev, P., Forlivesi, C. and Kawsar, F., 2017. Squeezing deep learning into mobile and embedded devices. IEEE Pervasive Computing, (3), pp.82-88.
[8] L’heureux, A., Grolinger, K., Elyamany, H.F. and Capretz, M.A., 2017. Machine learning with big data: Challenges and approaches. IEEE Access, 5(5), pp.777-797.
[9] Liu, Y., He, J., Guo, M., Yang, Q. and Zhang, X., 2014. An overview of Big Data industry in China. China Communications, 11(12), pp.1-10.
[10] Maimó, L.F., Gómez, A.L.P., Clemente, F.J.G. and Pérez, M.G., A Self-Adaptive Deep Learning-Based System for Anomaly Detection in 5G Networks.
[11] Jabbar, S., Malik, K.R., Ahmad, M., Aldabbas, O., Asif, M., Khalid, S., Han, K. and Ahmed, S.H., 2018. A Methodology of Real-Time Data Fusion for Localized Big Data Analytics. IEEE Access, 6, pp.24510-24520.
[12] Sun, B., Feng, H., Chen, K. and Zhu, X., 2016. A deep learning framework of quantized compressed sensing for wireless neural recording. IEEE Access, 4, pp.5169-5178.
[13] Wu, D., Zhu, L., Lu, Q. and Sakr, S., 2017. HDM: A Composable Framework for Big Data Processing. IEEE Transactions on Big Data.
[14] Shao, L., Wu, D. and Li, X., 2014. Learning deep and wide: A spectral method for learning deep networks. IEEE Transactions on Neural Networks and Learning Systems, 25(12), pp.2303-2308.
[15] Yao, S., Zhao, Y., Zhang, A., Hu, S., Shao, H., Zhang, C., Su, L. and Abdelzaher, T., 2018. Deep Learning for the Internet of Things. Computer, 51(5), pp.32-41.
[16] Barcelo, M., Correa, A., Llorca, J., Tulino, A.M., Vicario, J.L. and Morell, A., 2016. IoT-Cloud Service Optimization in Next Generation Smart Environments. IEEE Journal on Selected Areas in Communications, 34(12), pp.4077-4090.
[17] Alam, F., Mehmood, R., Katib, I., Albogami, N.N. and Albeshri, A., 2017. Data fusion and IoT for smart ubiquitous environments: A survey. IEEE Access, 5, pp.9533-9554.
[18] Li, Y., Cheng, X., Cao, Y., Wang, D. and Yang, L., 2018. Smart choice for the smart grid: Narrowband Internet of Things (NB-IoT). IEEE Internet of Things Journal, 5(3), pp.1505-1515.
[19] Mohammadi, M., Al-Fuqaha, A., Guizani, M. and Oh, J.S., 2018. Semisupervised deep reinforcement learning in support of IoT and smart city services. IEEE Internet of Things Journal, 5(2), pp.624-635.
[20] Condry, M.W. and Nelson, C.B., 2016. Using smart edge IoT devices for safer, rapid response with industry IoT control operations. Proceedings of the IEEE, 104(5), pp.938-946.
[21] Deepika J, Senthil T, Rajan C, Surendar A, 2018, “Machine learning algorithms: a background artifactâ€, International Journal of Engineering & Technology 7 (1), 143-149.
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How to Cite
A, M., & P. Manimegalai, D. (2018). Novel Deep-Learning Algorithms for the Internet of Things with Smart Applications – An Exploratory Study. International Journal of Engineering & Technology, 7(4.36), 182-185. https://doi.org/10.14419/ijet.v7i4.36.23741Received date: 2018-12-12
Accepted date: 2018-12-12
Published date: 2018-12-09