TECNOLOGÍAS DE ACCESO DINÁMICO Y USO COMPARTIDO DEL ESPECTRO
DOI:
https://doi.org/10.26512/lstr.v11i2.27018Palavras-chave:
Tecnologías de Acceso Dinâmico. Espectro Compartido. Massive MIMO. Device-to-Device.Resumo
Propósito ”“ En su preocupación por reducir la brecha digital y en busca de incrementar la capacidad de tráfico de las redes móviles para satisfacer la demanda de conectividad futura, el Instituto Federal de Telecomunicaciones (IFT), a través de la Dirección de Ingeniería y Tecnología (DIT).
Metodologia ”“ Analize del estado del arte de las tecnologías de acceso dinámico y uso compartido del espectro radioeléctrico (TADUCE) con la finalidad de identificar aquellas que sean susceptibles de adopción en México. Las tecnologías analizadas en la investigación son aquellas basadas en LTE (Long Term Evolution) que operan en bandas de frecuencia de uso libre; tecnologías emergentes basadas en MIMO; Radio Cognitivo (RC); Comunicaciones Device-to-Device (D2D) y TV White Spaces (TVWS).
Resultados ”“ La DIT establece diferentes recomendaciones que el IFT debe considerar para que dichas tecnologías se implementen óptimamente en el país.
Downloads
Referências
BJÖRNSON, Emil; Larsson, Erick G. y Marzetta, Thomas L. (2016) Massive MIMO: Ten Myths and One Critical Question, IEEE Communications Magazine, 116.
CHEN, Bolin; Chen, Jiming; Gao, Yuan y Zhang, Jie. (2017) Coexistence of LTE-LAA and Wi-Fi on 5 GHz With Corresponding Deployment Scenarios: A Survey, IEEE Communications Surveys & Tutorials, 19, 1, 10.
CISCO. (2017) Forecasting the World’s Digital Transformation, Estados Unidos, disponible en: https://www.cisco.com/c/m/en_us/solutions/service-provider/vni-complete-forecast/infographic.html
CISCO. (2017) The Zettabyte Era: Trends and Anlysis, Estados Unidos, disponible en: https://www.cisco.com/c/en/us/solutions/collateral/service-provider/visual-networking-index-vni/vni-hyperconnectivity-wp.html
DELOITTE. (2014) The Impact of Licensed Shared Use of Spectrum, Reino Unido, GSMA, 15, disponible en: https://www.gsma.com/spectrum/wp-content/uploads/2014/02/The-Impacts-of-Licensed-Shared-Use-of-Spectrum.-Deloitte.-Feb-20142.pdf
FCC. (2002) NOTICE OF INQUIRY. In Matter of Additional Spectrum for Unlicensed Devices Below 900 MHz and in the 3 GHz Band, Estados Unidos, disponible en: https://apps.fcc.gov/edocs_public/attachmatch/FCC-02-328A1.pdf
FCC. (2004) NOTICE OF PROPOSED RULE MAKING. In Matter of Unlicensed Operation in the TV Broadcast Bands, Estados Unidos, disponible en: https://apps.fcc.gov/edocs_public/attachmatch/FCC-04-113A1.pdf
FLORE, Dino. (2016) LAA standardization: coexistence is the key, Third Generation Partnership Project, disponible en: http://www.3gpp.org/news-events/3gpp-news/1789-laa_update
INTEL. (2016) Alternative LTE Solutions in Unlicensed Spectrum: Overview of LWA, Estados Unidos, LTE-LAA and Beyond, 13, disponible en: https://www.intel.com/content/dam/www/public/us/en/documents/white-papers/unlicensed-lte-paper.pdf
ISMAIEL, Bushra; ABOLHASAN, Mehran y SMITH, David. (2017) A Survey and Comparison Of Device-To-Device Architecture Using LTE unlicensed Band, 2017 IEEE 85th Vehicular Technology Conference (VTC Spring), Australia, 2.
Kim, Taisiya; Park, Soo K. y Lee, Bong G. (2015) Korean Mobile Operators' Value Map for LTE D2D, International Journal of Digital Information and Wireless Communications (IJDIWC), Corea, 141-142.
Kwon, Hwan-Joon; Jeon, Jeongho y Bhorkar, Abhijeet. (2017) Licensed-Assisted Access to Unlicensed Spectrum in LTE Release 13, IEEE Communications Magazine, 203.
LTE-U Forum. (2017) LTE-U SDL Coexistence Specifications V1.3, 4, disponible en: http://www.lteuforum.org/uploads/3/5/6/8/3568127/lte-u_forum_lte-u_sdl_coexistence_specifications_v1.3.pdf
Malladi, Durga. (2016) Best use of unlicensed spectrum, Estados Unidos, Qualcomm Technologies, Inc., 6, disponible en: https://www.qualcomm.com/media/documents/files/making-the-best-use-of-unlicensed-spectrum-presentation.pdf
Microsoft. (2016) A Rural Broadband Strategy. Connecting Rural America to New Oportunities, Estados Unidos, 16. Disponible en: https://msblob.blob.core.windows.net/ncmedia/2017/07/Rural-Broadband-Strategy-Microsoft-Whitepaper-FINAL-7-10-17.pdf
Molisch, Andreas F. (2010) Wireless Communications, Reino Unido, John Wiley & Sons, 2a ed., 506.
MULTEFIRE. (2016) MulteFire Release 1.0 Technical Paper. A New Way to Wireless, Estados Unidos, MulteFire Alliance, 3, disponible en: https://www.multefire.org/specification/specification-release-1-0-1download/
Mumtaz, Shahid y Rodriguez, Jonathan. (2014) Smart Device to Smart Device Communication, Suiza, Springer Science + Business Media, 5.
National Instruments. (2017) 5G Massive MIMO Testbed: From Theory to Reality, Estados Unidos, disponible en: http://www.ni.com/white-paper/52382/en/#toc4
NETMANIAS. (2017) Analysis of LTE ”“ WiFi Aggregation Solutions, Corea, disponible en: https://www.netmanias.com/en/post/reports/8532/laa-lte-lte-u-lwa-mptcp-wi-fi/analysis-of-lte-wifi-aggregation-solutions
Ofcom. (2015) Implementing TV White Spaces, Reino Unido, Office of Communications, disponible en: https://www.ofcom.org.uk/__data/assets/pdf_file/0034/68668/tvws-statement.pdf
Ofcom. (2015) New Spectrum for Audio PMSE, Reino Unido, Office of Communications, disponible en: https://www.ofcom.org.uk/consultations-and-statements/category-2/new-spectrum-audio-pmse
Ofcom. (2016) White Space Database Operators, Reino Unido, Office of Communications, disponible en: https://tvws-databases.ofcom.org.uk/
QUALCOMM. (2017) Qualcomm Research. LTE in Unlicensed Spectrum: Harmonious Coexistence with Wi-Fi, Estados Unidos, 6, disponible en: https://www.qualcomm.com/media/documents/files/lte-unlicensed-coexistence-whitepaper.pdf
RICKNÄS, Mikael (2013) Samsung takes first 5G steps with advanced antenna. But not everyone is convinced the underlying technology will work, Australia, PC World From IDG (News), disponible en: https://www.pcworld.idg.com.au/article/461656/
SHEPARD, Clayton; YU, Hang; ANAND, Narendra; Li, Li E.; MARZETTA, Thomas; Yang, Richard y Zhong, Lin. (2012) Argos: Practical Many-Antenna Base Stations, The 18th Annual International Conference on Mobile Computing and Networking, Turquía, 9, disponible en: http://argos.rice.edu/pubs/Shepard-MobiCom12.pdf
Song, Lingyang; Niyato, Dusit; Han, Zhu y Hossain, Ekram. (2015) Wireless Device-to-Device Communications and Networks, Reino Unido, Cambridge University Press, 1a ed., 6, 7.
SUZUKI, Hajime; KENDALL, Rodney y ANDERSON, Kevin. (2012) Highly Spectrally Efficient Ngara Rural Wireless Broadband Access Demonstrator, International Symposium on Communications and Information Technologies (ISCIT), 914.
TEHRANI, Mohsen N.; UYSAL, Murat y YANIKOMEROGLU, Halim. (2014) Device-to-Device Communication in 5G Cellular Networks: Challenges, Solutions, and Future Directions, IEEE Communications Magazine, 86.
UIT-R. (2009) Informe UIT-R SM.2152. Definiciones de sistema radioeléctrico determinado por programas informáticos (RDI) y sistema radioeléctrico cognoscitivo (SRC), Suiza, Sector de Radiocomunicaciones de la UIT (Serie SM, Gestión del Espectro), 2, disponible en: https://www.itu.int/dms_pub/itu-r/opb/rep/R-REP-SM.2152-2009-PDF-S.pdf
UNIVERSITY OF BRISTOl. (2016) Bristol and Lund set a new world record in 5G wireless spectrum efficiency, Reino Unido, University of Bristol (News), disponible en: http://www.bristol.ac.uk/news/2016/march/massive-mimo.html
VIEIRA, Joao; Malkowsky, Steffen y Nieman, Karl. (2014) A flexible 100-antenna testbed for Massive MIMO, IEEE Globecom 2014 Workshop - Massive MIMO: From Theory to Practice, Estados Unidos, 290.
WANG, Cheng-Xian; Hong, Xuemin y Ge, Xiaohu. (2010) Cooperative MIMO Channel Models: A Survey, IEEE Communications Magazine, 81.
WANG, Jianfeng; Ghosh, Monisha y Challapali, Kiran. (2011) Emerging Cognitive Radio Applications: A Survey, IEEE Communications Magazine, 74.
Downloads
Publicado
Como Citar
Edição
Seção
Licença
Ao submeter seu artigo à Revista de Direito, Estado e Telecomunicações,
declaro aceitar a licença de publicação Creative Commons Attribution 4.0 International (CC BY 4.0).
