The Communication System of Building from Outdoor to Indoor with AMC at 10 GHz
Main Article Content
Abstract
The propagation model of communication systems was used propagation from outdoor to indoor of building. In the inside that building used partition with brick. That propagation condition used downlink condition from mobile station side. The communication frequency used 10 GHz. Some parameter variation was used in this research such as radio base station coverage, mobile station location of building, and code rate communication. The coverage variation of radio base station used femtocell and picocell. As the result described signal to noise ratio (SNR)at every node communication, adaptive modulation and coding (AMC) variation, and coverage area percentage in the building. The modulation and coding scheme (MCS) was used consist of QPSK, 16 QAM, and 64 QAM
Downloads
Download data is not yet available.
Article Details
How to Cite
[1]
A. Eska, “The Communication System of Building from Outdoor to Indoor with AMC at 10 GHz”, INFOTEL, vol. 12, no. 1, pp. 13-17, Apr. 2020.
Section
Telecommunication
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
Authors who publish with this journal agree to the following terms:
- Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
- Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work
References
[1] G.R. MacCartney, T.S. Rappaport, S. Sun, and S. Deng, “Indoor Office Wideband Millimeter-Wave Propagation Measurements and Channel Models at 28 and 73 GHz for Ultra-Dense 5G Wireless Networks,” IEEE Access, 2015.
[2] G.Castro, R.Feick, M.Rodriguez, R.Vanezuela, and D.Chizhik, “Outdoor-to-Indoor Empirical Path Loss Models: Analysis For Pico and Femto Cells in Street Canyons,” IEEE Wireless Communications Letters, 2016.
[3] G.Bartoli, R.Fantacci, D. Marabissi, and M.Pucci, “Resource Allocation Schemes for Cognitive LTE-A Femto-cells using Zero-Forcing Beamforming and Users Selection, ”Globecom Wireless Communications Symposium, 2014.
[4] C.Niu, Y.Li, R.Qingyang, and F.Ye, “Femtocell-enhanced multi-target spectrum allocation strategy in LTE-A HetNets,” IET communications, 2016
[5] A.C. Eska, “Pengaruh Code Rate untuk Komunikasi RBS Femtocell Frekuensi 47 GHz pada Tiang Lampu Jalan,” Jurnal Infotel, Vol.9, No.4, 2017.
[6] A.C. Eska, “Propagasi Komunikasi Radio Base Station Femtocell padaTiang Lampu Jalan Frekuensi 10 GHz,” Jurnal Infotel, Vol.9, No.4, 2017.
[7] A.C. Eska, and G. Hendrantoro, “Preliminary study on the effect of building-induced diffraction upon millimeter wave mobile communications systems with macrodiversity,” TSSA, 2012.
[8] A.C. Eska, “Komunikasi Bergerak Frekuensi 2.3 GHz Melewati Pepohonan Menggunakan Metode Giovanelli Knife Edge,” Jurnal Infotel, Vol. 8, No.1, 2016.
[9] T.W. Wu, and C.D. Chung, “Spectrally Precoded DFT-Based OFDM and OFDMA with Oversampling,” IEEE Transactions on Vehicular Technology, Vol. 63, No.6, 2014.
[10] A. Shanin, and H. Arslan, “Edge Windowing for OFDM Based Systems,” IEEE Communications Letters, Vol. 15, No.11, 2011.
[11] S. Wang, “Efficient Resource Allocation Algorithm for Cognitive OFDM Systems,” IEEE Communications Letters, Vol. 14, No.8, 2010.
[12] A.C. Eska, “Determination of MS Location through Building Using AoA Method of Frequency 47 GHz,” IJITEE, Vol.1, No.3, 2017.
[13] A.C. Eska, “Multipath Effects in Building Environment Toward Bandwidth Enhancement for Mobile Communication of 47 GHz Frequency,” Jurnal Infotel, Vol. 10, No.1, 2018.
[14] T.S. Rappaport, G.R. MacCartney, S. Sun, H. Yan, and S. Deng, “Small-Scale, Local Area, and Transitional Millimeter Wave Propagation for 5G Communications,” IEEE Transactions on Antennas and Propagation, Vol. 65, No.12, 2017.
[15] T.S. Rappaport, Y. Xing, G.R. MacCartney, A.F. Molisch, and E. Mellios, J. Zhang, “Overview of Millimeter Wave Communications for Fifth-Generation (5G) Wireless Networks-With a Focus on Propagation Models,” IEEE Transactions on Antennas and Propagation, Vol. 65, No.12, 2017.
[16] T.S. Rappaport, E.B. Dor, J.N. Murdock, and Y. Qiao, “38 GHz and 60 GHz Angle-dependent Propagation for Cellular & Peer-to-Peer Wireless Communications,” IEEE ICC Wireless Communications Symposium, 2012.
[17] A.C. Eska, “Propagation of Mobile Communication with Tree Obstacle used OFDM-QAM at 10 GHz,” JurnalInfotel, Vol.11, No.3, 2019.
[18] A. Lukowa, V. Venkatasubramanian, P. Marsch,“Dynamic Self – Backhauling in 5G Networks,” IEEE 29th Annual International Symposium on PIMRC, 2018.
[19] A. Lukowa, V. Venkatasubramanian, “Dynamic In-Band Selft-Backhauling with Interference Cancellation,” IEEE Conference on Standards for Communications and Networking (CSCN), 2018.
[20] A.Lukowa, V. Venkatasubramanian, “Dynamic In-band Self-backhauling for 5G Systems with Inter-cell Resource Coordination,” International Journal of Wireless Information Networks, 2019.
[21] A.C. Eska, “Adaptive Modulation and Coding around Building Environment for Mobile Station Communication at The Train,” EMITTER, Vol.6, No.2, 2018.
[22] J.S. Seybold, Introduction to RF Propagation. John Wiley & Sons (New Jersey), 2005.
[23] A.C. Eska, Jaringan Komunikasi Selular, UPT Percetakan & Penerbitan Universitas Jember. ISBN: 978-602-5617-43-0, 2018.
[24] ITU, ITU-R Radio Communication Sector of ITU (Attenuation by atmospheric gases) ITU-R P.676-10. Electronic Publication (Geneva), 2013.
[25] O. Werther, LTE System Specifications, and their Impact on RF & Base Band Circuits. Rohde &Schwarz, 2013.
[2] G.Castro, R.Feick, M.Rodriguez, R.Vanezuela, and D.Chizhik, “Outdoor-to-Indoor Empirical Path Loss Models: Analysis For Pico and Femto Cells in Street Canyons,” IEEE Wireless Communications Letters, 2016.
[3] G.Bartoli, R.Fantacci, D. Marabissi, and M.Pucci, “Resource Allocation Schemes for Cognitive LTE-A Femto-cells using Zero-Forcing Beamforming and Users Selection, ”Globecom Wireless Communications Symposium, 2014.
[4] C.Niu, Y.Li, R.Qingyang, and F.Ye, “Femtocell-enhanced multi-target spectrum allocation strategy in LTE-A HetNets,” IET communications, 2016
[5] A.C. Eska, “Pengaruh Code Rate untuk Komunikasi RBS Femtocell Frekuensi 47 GHz pada Tiang Lampu Jalan,” Jurnal Infotel, Vol.9, No.4, 2017.
[6] A.C. Eska, “Propagasi Komunikasi Radio Base Station Femtocell padaTiang Lampu Jalan Frekuensi 10 GHz,” Jurnal Infotel, Vol.9, No.4, 2017.
[7] A.C. Eska, and G. Hendrantoro, “Preliminary study on the effect of building-induced diffraction upon millimeter wave mobile communications systems with macrodiversity,” TSSA, 2012.
[8] A.C. Eska, “Komunikasi Bergerak Frekuensi 2.3 GHz Melewati Pepohonan Menggunakan Metode Giovanelli Knife Edge,” Jurnal Infotel, Vol. 8, No.1, 2016.
[9] T.W. Wu, and C.D. Chung, “Spectrally Precoded DFT-Based OFDM and OFDMA with Oversampling,” IEEE Transactions on Vehicular Technology, Vol. 63, No.6, 2014.
[10] A. Shanin, and H. Arslan, “Edge Windowing for OFDM Based Systems,” IEEE Communications Letters, Vol. 15, No.11, 2011.
[11] S. Wang, “Efficient Resource Allocation Algorithm for Cognitive OFDM Systems,” IEEE Communications Letters, Vol. 14, No.8, 2010.
[12] A.C. Eska, “Determination of MS Location through Building Using AoA Method of Frequency 47 GHz,” IJITEE, Vol.1, No.3, 2017.
[13] A.C. Eska, “Multipath Effects in Building Environment Toward Bandwidth Enhancement for Mobile Communication of 47 GHz Frequency,” Jurnal Infotel, Vol. 10, No.1, 2018.
[14] T.S. Rappaport, G.R. MacCartney, S. Sun, H. Yan, and S. Deng, “Small-Scale, Local Area, and Transitional Millimeter Wave Propagation for 5G Communications,” IEEE Transactions on Antennas and Propagation, Vol. 65, No.12, 2017.
[15] T.S. Rappaport, Y. Xing, G.R. MacCartney, A.F. Molisch, and E. Mellios, J. Zhang, “Overview of Millimeter Wave Communications for Fifth-Generation (5G) Wireless Networks-With a Focus on Propagation Models,” IEEE Transactions on Antennas and Propagation, Vol. 65, No.12, 2017.
[16] T.S. Rappaport, E.B. Dor, J.N. Murdock, and Y. Qiao, “38 GHz and 60 GHz Angle-dependent Propagation for Cellular & Peer-to-Peer Wireless Communications,” IEEE ICC Wireless Communications Symposium, 2012.
[17] A.C. Eska, “Propagation of Mobile Communication with Tree Obstacle used OFDM-QAM at 10 GHz,” JurnalInfotel, Vol.11, No.3, 2019.
[18] A. Lukowa, V. Venkatasubramanian, P. Marsch,“Dynamic Self – Backhauling in 5G Networks,” IEEE 29th Annual International Symposium on PIMRC, 2018.
[19] A. Lukowa, V. Venkatasubramanian, “Dynamic In-Band Selft-Backhauling with Interference Cancellation,” IEEE Conference on Standards for Communications and Networking (CSCN), 2018.
[20] A.Lukowa, V. Venkatasubramanian, “Dynamic In-band Self-backhauling for 5G Systems with Inter-cell Resource Coordination,” International Journal of Wireless Information Networks, 2019.
[21] A.C. Eska, “Adaptive Modulation and Coding around Building Environment for Mobile Station Communication at The Train,” EMITTER, Vol.6, No.2, 2018.
[22] J.S. Seybold, Introduction to RF Propagation. John Wiley & Sons (New Jersey), 2005.
[23] A.C. Eska, Jaringan Komunikasi Selular, UPT Percetakan & Penerbitan Universitas Jember. ISBN: 978-602-5617-43-0, 2018.
[24] ITU, ITU-R Radio Communication Sector of ITU (Attenuation by atmospheric gases) ITU-R P.676-10. Electronic Publication (Geneva), 2013.
[25] O. Werther, LTE System Specifications, and their Impact on RF & Base Band Circuits. Rohde &Schwarz, 2013.