Millimeter-wave correspondence is a promising innovation for future 5G cell systems to give exceptionally high data rate (multi-gigabits-persecond) for portable devices. Empowering D2D interchanges over directional mmWave systems is of critical importance to productively use the extensive bandwidth to increment framework capacity. In this article, the spread highlights of mmWave correspondence and the related impacts on 5G cell systems are discussed. We introduce an mmWave+4G framework engineering with TDMA-based MACINTOSH structure as a candidate for 5G cell networks. We propose an compelling asset sharing plan by permitting non-meddling D2D joins to work concurrently. We too discuss neighbor revelation for continuous handoffs in 5G cell networks. In 4g technology capable to provide speed up to 100mbps but battery uses is more. Fifth generation network provide reasonable broadband wireless connectivity (very high speed). Millimeter wave (mmWave) communication is a hopeful solution for future fifth generation (5G) cellular networks to offer extremely high capability. Here we used 5g being developed to accommodate Qos rate requirements set by further development of existing 4g applications. 5g is a next major phase of mobile telecommunication and wireless system. 10 times more capacity than others. In this project, a playout buffer is used to control and preserve the data playout quality. We formulate the difficult of using dynamically allocated bandwidth to charge the buffer as a Markov decision process (MDP), aiming to exploit data playout quality for all the users moving in the whole coverage zone. The proposed technique on playout quality provisioning is effective for real time video applications of the users with great mobility.

Security, k-NN Classifier, Outsourced Databases, Encryption

[1] M. R. Akdeniz, Y. Liu, M. K. Samimi, S. Sun, S. Rangan, T. S. Rapp port, and E. Erkip “Millimeter Wave Channel Modeling and Cellular Capacity Evaluation,” IEEE J. Sel. Areas communication., vol. 32, no. 6, pp. 1164-1179,June 2014.
[2] L. X. Cai, L. Cai, X. Shen, and J. W. Mark, “REX: A Randomized Exclusive Region based Scheduling Scheme for mm Wave WPANs with Directional Antenna,” IEEE Trans. Wireless Common., vol. 9, no. 1, pp.113-121, Jan. 2010.
[3] F. Gutierrez, S. Agarwal, K. Parrish, and T. S. Rapp port, “On-Chip Integrated Antenna Structures in CMOS for 60 GHz WPAN Systems, ”IEEE J. Sel. Areas Common., vol. 27, no. 8, pp. 1367-1378, Oct. 2009.
[4] D. Novato, and E. Hossain, “Bandwidth Allocation in 4G Heterogeneous Wireless Access Networks: A Non co-operative Game Theoretical Approach,” IEEE GLOBECOM pp. 1-5, Nov. 2006.
[5] Pei, T. Jiang, D. Qu, G. Zhu, and J. Liu, “Radio Resource Management and Access Control Mechanism Based on a Novel Economic Model in Heterogeneous Wireless Networks,” IEEE Trans. Veh. Technol., vol.59, no. 6, PP. 3047-3056, Jul. 2010.
[6] Ambreen Fatma Siddiqui, Pankaj Kumar and Raj Gaurang Tiwari, "Reducing Handoff Blocking Probability in Wireless Cellular Networks- A Review", International Journal of Computer Sciences and Engineering, Volume-03, Issue-08, Page No (17-21), Aug -2015
[7] Gurpreet Singh and Amanpreet kaur, "An Improved Fuzzy Logic System for Handoff Controller Design in Micro Cellular Mobile Network", International Journal of Computer Sciences and Engineering, Volume-03, Issue-07, Page No (1-5), Jul -2015
[8] W. Song, H. Jiang, and W. Zhuang, “Performance Analysis of the WLAN-First Scheme in Cellular/WLAN Interworking,” IEEE Trans. On Wireless Communication, vol. 6, no. 5, pp. 1932-1943, May 2007.
[9] S. Singh, F. Ziliotto, U. Madhow, E. M. Belding, and M. J. W. Rodwell, Millimeter Wave WPAN: Cross-Layer Modeling and Multihop Architecture,” in Proc. IEEE INFOCOM, pp. 2336-2240, May 2007.
[10] J. Qiao, L. X. Cai, X. Shen, and J. W. Mark, “Enabling Multi-Hop Concurrent Transmissions in 60 GHz Wireless Personal Area Networks,” IEEE Trans. on Wireless Commun., vol. 10, no. 11, pp. 3824-3833, Nov. 2011.
[11] Alshamrani, X. Shen, and L. Xie, “QoS Provisioning for Heterogeneous Services in Cooperative Cognitive Radio Networks”, IEEE J. Sel. Areas Commun., vol. 29, no. 4, pp. 819-830, April 2011.
[12] Sum, Z. Lan, R. Funada, J. Wang, T. Baykas, M. A. Rahman, and H. Harada, “Virtual Time-Slot Allocation Scheme for Throughput Enhancement in a Millimeter-Wave Multi-Gbps WPAN System,” IEEE J. Sel. Areas Commun., vol. 27, no. 8, pp. 1379-1389, Oct. 2009