IJBTT

Resource Aware Quadratic Discriminative Gentle Steepest Boost Classification for D2D Communication in 5G

Resource Aware Quadratic Discriminative Gentle Steepest Boost Classification for D2D Communication in 5G
	© 2022 by IJETT Journal
	Volume-70 Issue-5
	Year of Publication : 2022
	Authors : Varadala Sridhar, S. Emalda Roslin
	DOI :  10.14445/22315381/IJETT-V70I5P239

How to Cite?

Varadala Sridhar, S. Emalda Roslin, "Resource Aware Quadratic Discriminative Gentle Steepest Boost Classification for D2D Communication in 5G," International Journal of Engineering Trends and Technology, vol. 70, no. 5, pp. 357-366, 2022. Crossref, https://doi.org/10.14445/22315381/IJETT-V70I5P239

Abstract
D2D communication for 5G networks enables mobile devices to communicate directly with other devices. For effective available resources, 5G cellular networks that enable high-speed network communication are the major challenging issues. A novel Resource Aware Quadratic discriminative gentle steepest boost classification (RAQDGDBC) technique for D2D communications is introduced. For each device in the 5G network, energy, bandwidth, and connection speed is measured to improve the continuous flow of data and minimize data loss and latency during the communication. The RAQDGDBC technique uses the ensemble method called gentle adaptive steepest boost classification technique to identify the higher bandwidth, energy-efficient, and speed-aware devices by using the set of the weak learner, i.e., Quadratic discriminative classifier. Weak learner measures the device`s bandwidth, energy, and connection speed with the threshold value. An optimal node is selected for efficient communication based on the likelihood measure. The ensemble method offers accurate outcomes with minimum error with the help of the steepest descent function. Therefore, the device with higher bandwidth, energy efficiency, and connection speed is chosen for data communication. These advanced features of the 5G network provide better data transmission and reduce loss. A comparison of RAQDGDBC and existing techniques indicates that the RAQDGDBC technique achieves a higher Data delivery rate (DDR), throughput, energy efficiency, and lesser Data loss rate (DLR) and latency than the conventional methods.

Keywords
5G Network, Device-to-Device (D2D) Communication, Bandwidth Connection Speed, Quadratic Discriminative Classifier, Gentle Adaptive Steepest Boost.

Reference
[1] Ioannou J, Vassiliou V, Christophorou C, Pitsillides A, Distributed Artificial Intelligence Solution for D2D Communication in 5G Networks, IEEE Systems Journal. 14(3) (2020) 4232-4241. Doi: 10.1109/JSYST.2020.2979044
[2] Sultana A, Woungang I, Anpalagan A, Zhao L, Ferdouse L, Efficient Resource Allocation in SCMA-Enabled Device-to-Device Communication for 5G Networks, IEEE Transactions on Vehicular Technology. 69(5) (2020) 5343-5354. Doi: 10.1109/TVT.2020.2983569
[3] Zhang H, Liao Y, Song L, D2D-U: Device-to-Device Communications in Unlicensed Bands for 5G System, IEEE Transactions on Wireless Communications. 16(6) (2017) 3507-3519. Doi: 10.1109/TWC.2017.2683479
[4] Dahat PA, Das S, Device-to-device Communications Under Transceiver Impairments in OFDMA Cellular Networks, Physical Communication, Elsevier. 40 (2020) 1-25. https://doi.org/10.1016/j.phycom.2020.101058
[5] L Ji, Lei G, Manogaran G, Mastorakis G, Mavromoustakis CX, D2D Communication Mode Selection and Resource Optimization Algorithm with Optimal Throughput in 5G Network, IEEE Access. 7 (2019) 263-25273. Doi: 10.1109/ACCESS.2019.2900422
[6] Mesbahi G, Rahbar AG, Cluster-Based Architecture Capable for Device-to-Device Millimeter-Wave Communications in 5G Cellular Networks, Arabian Journal for Science and Engineering, Springer. 44 (2019) 9719-9733 https://doi.org/10.1007/s13369-019-03830-w
[7] Feng L, Yang Z, Yang Y, Que X, Zhang K, Smart Mode Selection Using Online Reinforcement Learning for VR Broadband Broadcasting in D2D Assisted 5G HetNets, IEEE Transactions on Broadcasting. 66(2) (2020) 600-611. Doi: 10.1109/TBC.2020.2977577
[8] Murkaz A, Hussain R, Ahmed J, Adil M, Omoniwa B, AdeelIqbal, An Intra–Inter-Cell Device-To-Device Communication Scheme to Enhance 5G Network Throughput with Delay Modeling, Telecommunication Systems, Springer. 69(4) (2018) 1-15. Doi:10.1007/s11235-018-0449-x
[9] Huang J, Xing C, Qian Y, Haas ZJ, Resource Allocation for Multicell Device-to-Device Communications Underlaying 5G Networks: A Game-Theoretic Mechanism with Incomplete Information, IEEE Transactions on Vehicular Technology. 67(3) (2018) 2557-2570. Doi: 10.1109/TVT.2017.2765208
[10] Mishra PK, Kumar A, Pandey S, Singh VP, Hybrid Resource Allocation Scheme in Multi-hop Device-to-Device Communication for 5G Networks, Wireless Personal Communications, Springer. 103 (2018) 2553-2573. https://doi.org/10.1007/s11277-018-5946-4
[11] Zhao P, Feng L, Yu P, Li W, Qiu X, A Social-Aware Resource Allocation for 5G Device-to-Device Multicast Communication, IEEE Access. 5 (2017) 15717-15730. Doi: 10.1109/ACCESS.2017.2731805
[12] Chen Y, Ai B, Niu Y, He R, Zhong Z, Han Z, Resource Allocation for Device-to-Device Communications in Multi-Cell Multi-Band Heterogeneous Cellular Networks, IEEE Transactions on Vehicular Technology. 68(5) (2019) 760-4773. Doi: 10.1109/TVT.2019.2903858
[13] Zhou Y, Li L, The 5G Communication Technology-Oriented Intelligent Building System Planning and Design, Computer Communications, Elsevier. 160 (2020) 402-410. https://doi.org/10.1016/j.comcom.2020.06.022
[14] Xu C, Wang M, Chen X, Zhong L, Grieco LA, Optimal Information-Centric Caching in 5G Device-to-Device Communications, IEEE Transactions on Mobile Computing. 17(9) (2018) 2114-2126. Doi: 10.1109/TMC.2018.2794970
[15] Akyildiz IF, Kak IF, Khorov E, Krasilov A, Kureev A, ARBAT: A Flexible Network Architecture for Qoe-Aware Communications in 5G Systems, Computer Networks, Elsevier. 147 (2018) 262-279. https://doi.org/10.1016/j.comnet.2018.10.016
[16] Hamdoun S, Rachedi A, Ghamri-Doudane Y, Graph-Based Radio Resource Sharing Schemes for MTC in D2D-based 5G Networks, Mobile Networks, and Applications, Springer. 25 (2020) 1095-1113. https://doi.org/10.1007/s11036-020-01527-1
[17] Sreedevi AG, Rao TR, Reinforcement Learning Algorithm for 5G Indoor Device-to-Device Communications, Transactions on Emerging Telecommunications Technologies, Wiley. 30(9) (2019) 1-10. https://doi.org/10.1002/ett.3670
[18] JavedIqbal, Iqbal MA, Ahmad A, Khan M, Qamar A, Han K, Comparison of Spectral Efficiency Techniques in Device-to-Device Communication for 5G, IEEE Access. 7 (2019) 57440-57449. Doi: 10.1109/ACCESS.2019.2914486
[19] Gui J, Zhou K, Cellular throughput Optimization by Game-Based Power Adjustment and Outband D2D Communication, EURASIP Journal on Wireless Communications and Networking, Springer. (2018) 1-25. DOI:10.1186/s13638-018-1275-2
[20] Hayat O, Ngah R, Hashim SZM, Performance Analysis of Device Discovery Algorithms for D2D Communication, Arabian Journal for Science and Engineering, Springer. 45 (2020) 1457-1471. Doi:10.1007/s13369-019-04006-2
[21] Nightingale J, Salva-Garcia P, Calero JMA, Wang Q, 5G-QoE: QoE Modelling for Ultra-HD Video Streaming in 5G Networks, in IEEE Transactions on Broadcasting. 64(2) (2018) 621-634. Doi: 10.1109/TBC.2018.2816786.
[22] Liu S, Wu Y, Li L, Liu X, Xu W, A Two-Stage Energy-Efficient Approach for Joint Power Control and Channel Allocation in D2D Communication, in IEEE Access. 7 (2019) 16940-16951. Doi: 10.1109/ACCESS.2019.2894003.
[23] Ghosh A, SahaRay R, Chakrabarty S, Bhadra S, Robust Generalized Quadratic Discriminant Analysis, Pattern Recognition. 117 (2018).
[24] Zhou M, Yin F, Liu C, GPU-Based Fast Training of Discriminative Learning Quadratic Discriminant Function for Handwritten Chinese Character Recognition, 2013 12th International Conference on Document Analysis and Recognition: (2013) 842-846. Doi: 10.1109/ICDAR.2013.172.
[25] Mei J, Wang X, Zheng K, An intelligent self-sustained RAN slicing framework for diverse service provisioning in 5G-beyond and 6G networks, in Intelligent and Converged Networks. 1(3) (2020) 281-294. Doi: 10.23919/ICN.2020.0019