Simulasi Penggunaan Frekuensi Milimeter Wave Untuk Akses Komunikasi Jaringan 5G Indoor

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Toha Ardi Nugraha Alfin Hikmaturokhman


Millimeter Wave (mmWave) is a solution to overcome of frequency limitations in 5G technology implementations using high frequency domain. This research discusses about mmWave frequency selection for 5G technology using empirical models in indoor propagation model. Several MmWave frequencies are simulated on indoor office environment. Based on simulation with InH placed in each room 5x5 meter size, it will be more effective using 60GHz, compared to 38Ghz, 28GHz, and 5GHz and also unlicenced 2.4. The average SIR will better at mmWave frequencies in the 60GHz with 33.97 dB and the average received signal is -73.87 dBm. Overall, it can also be concluded that the InH device with low frequency is not suitable applied indoors with massive deployement, it can be interference, for exampe using unlicenced 2.4GHz and 5GHz,  receiver only gets average SIR of approximately 5dB.

Keywords-5G, Indoor, Milimeter Wave, Indoor Hotspot



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NUGRAHA, Toha Ardi; HIKMATUROKHMAN, Alfin. Simulasi Penggunaan Frekuensi Milimeter Wave Untuk Akses Komunikasi Jaringan 5G Indoor. JURNAL INFOTEL, [S.l.], v. 9, n. 1, p. 24-30, feb. 2017. ISSN 2460-0997. Available at: <>. Date accessed: 27 may 2017. doi:


[1] Admaja, Awangga Febian Surya. "Kajian Awal 5G Indonesia [5G Indonesia Early Preview]." Buletin Pos dan Telekomunikasi 13.2 (2015): 97-114.
[2] Report ITU-R M.2376-0, “Technical Feasibility of IMT in Band Above 6GHz” ITU 2015
[3] Li, Yong, et al. "Simulation and Analysis of Millimeter-Wave Propagation Characteristics in Complex Office Environment." Journal of Computer and Communications 3.03 (2015): 56.
[4] T.S. Rappaport et al., “Milimeter Wave Mobile Communications for 5G Cellluar: It Will Works!” IEEE Access, Vol. 1. No. 1, pp. 335-349, 2013.
[5] Niu, Yong, et al. "A survey of millimeter wave communications (mmWave) for 5G: opportunities and challenges." The Journal of Mobile Communication, Computation and Information, Springer Wireless Networks 21.8 (2015): 2657-2676.
[6] Lee, J., Liang, J., Kim, M.D., Park, J.J., Park, B. and Chung, H.K., 2016. Measurement-Based Propagation Channel Characteristics for Millimeter-Wave 5G Giga Communication Systems. ETRI Journal, 38(6), pp.1031-1041.
[7] Hikmaturokhman, Alfin, Solichah Larasati, and Eka Setia Nugraha. "Analysis Cost 231 MultiWall Model on 4G LTE FDD 1800 and 900 Mhz Femtocell Network Planning." JAICT 1.1 (2016)
[8] Chandra, Kishor, et al. "CogCell: cognitive interplay between 60 GHz picocells and 2.4/5 GHz hotspots in the 5G era." IEEE Communications Magazine 53.7 (2015): 118-125.
[9] Shin, Soo Young, and Toha Ardi Nugraha. "Cooperative water filling (coopwf) algorithm for small cell networks." 2013 International Conference on ICT Convergence (ICTC). IEEE, 2013.
[10] Pal, Shovon Kumar, et al. "Resource Allocation Strategy using optimal power control for mitigating two-tier interference in heterogeneous networks." Wireless Communications and Networking Conference Workshops (WCNCW), 2014 IEEE. IEEE, 2014.
[11] Nugraha, Toha Ardi, and Soo Young Shin. "Inter-Cell Interference Coordination in Heterogeneous Networks with Open Access of Small Cells." 2014 ?? ??????? ???????? (2014): 446-449.
[12] Firdaus and Nugraha, Toha Ardi. "The Next Generation of ICT Network; NGN, FTTH, M2M, WSN, IoT." (2016).
[13] Yilmaz, T., Gokkoca, G. and Akan, O.B., 2016. Millimetre Wave Communication for 5G IoT Applications. In Internet of Things (IoT) in 5G Mobile Technologies (pp. 37-53). Springer International Publishing.
[14] Hikmaturokhman, Alfin, and Lingga Wardana. "4G Handbook Edisi Bahasa Indonesia Jilid 2." Jakarta: Penerbit nulis buku (2015).