1 / 25

WP 2. Enabling 5G: Case Studies. Technologies under study.

WP 2. Enabling 5G: Case Studies. Technologies under study. Authors: - César Briso Rodríguez (UPM) - Manuel García Sánchez (Uvigo) - Mikel Gómez Laso (Upna) - Ramón Martínez Rodríguez-Osorio (UPM) - Manuel Sierra Castañer (UPM) February 29 th 2016. Index. Challenging Scenarios

dylan
Download Presentation

WP 2. Enabling 5G: Case Studies. Technologies under study.

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. WP 2. Enabling 5G: Case Studies. Technologies under study. Authors: - César Briso Rodríguez (UPM) - Manuel García Sánchez (Uvigo) - Mikel Gómez Laso (Upna) - Ramón Martínez Rodríguez-Osorio (UPM) - Manuel Sierra Castañer (UPM) February 29th 2016

  2. Index Challenging Scenarios Test cases Test scenarios (ITS, Multimedia, Sat) Technology requirements and developments (ITS, Multimedia, Sat)

  3. Scope WP2: Case Studies and Technology requirements and developments This document is the technical report for the following tasks of the proyect Enabling 5G: “ENABLING INNOVATIVE RADIO TECHNOLOGIES FOR 5G NETWORKS” WP2.1. Intelligent Transport Systems WP2.11. Case Study and requirements WP2.12. Technology prospective and work proposal. WP2.2. Multimedia Distribution at 60 GHz WP2.21. Case Study and requirements WP2.22. Technology prospective and work proposal. WP2.3. The use of satellite in 5G networks WP2.31. Case Study and requirements WP2.32. Case Study and requirements

  4. Challenging Scenarios Challenging Scenarios

  5. Challenging Scenarios Performance Requirements 2020+

  6. Challenging Scenarios New ITU-R Microwave frequency bands for 5G

  7. 2- POTENTIAL USE CASES

  8. 2- TEST CASES (TCs) TC1: FUTURE OFFICE • Modern office space working with high resolution tele-presence and virtual reality • REQUIREMENTS: • Users data rate; • 1 Gbps with 95% Availability • 10 Gbps with 30% Availability • Frequency usage: • Communications bands mmWaves • Band V: (40-75 GHz) 60 GHz (57-64 GHz) (interiores) • Band Q (33 a 50 GHz): margen de 36 a 47 GHz. • Band UWB (2.5GHz Bandwidth) • 3.5 a 6 GHz. • 5.925 a 8.5 GHz. • Technology Test trials: • Propagation at mmfrequency bands indoor • Massive MIMO • Mmwave Antennas: • Sectorial • Directive

  9. 2- TEST CASES (TCs) TC2: TRANSPORTATION SYSTEM EFFICIENCY AND SAFETY • Signaling and intelligent driving aids for advanced transportation systems: • Road transportation • Railway. High capacity/ high speed • Unmanned vehicles (UAVs) • Autonomous Driving • REQUIREMENTS: • Users data rate; • 100/20 Mbps with 95% Availability • 10/2 Mbps with 98% availability • Low latency: less than 100ms • Frequency usage: • 4G bandsfrom 1-6 Ghz • Satellitebands : MW and mmW • 10- 100 MHz Bandwidth • Technology requirements: • Accurate propagation modelling for high speed vehicles • Propagation modelling for low altitude unmanned vehicles • MIMO and techniques • Electronic steering antennas, special antennas for transportation systems,Antennas for UAVs.

  10. 2- TEST CASES (TCs) TC3: MASSIVE DEPLOYMENT OF SENSORS AND ACTUATORS • Small sensors and actuators that are mounted to stationary or movable objects and enable a wide range of applications : • REQUIREMENTS: • Users data rate; • < 1 kbps data rate • Protocol efficiency: 80% at 300,000 devices per access node • Availability: 99.9% • Frequency usage: • bands .1-12 Ghz ?? • 10- 1000 Hz Bandwidth • UWB withLow data rate. • Technology requirements: • Low cost and energy efficient transmitters • Propagation modelling: foliage attenuation • Small, low cost UWB antennas

  11. 2- TEST CASES (TCs) TC4: DENSE URBAN ENVIRONMENT • Connectivity required at any place and at any time by humans in dense urban environments. • REQUIREMENTS: • Users data rate; • 500 Gbyte/month/subscriber • 300/60 Mbps in DL / UL with 95% availability • Frequency usage: • mmWaves • 4G bands .8-6Ghz • Technology Test trials: • Propagation at 4G and mmW frequency bands in urban environment • Massive MIMO • mmW Antennas: Sectorial /Directive

  12. 2- TEST CASES (TCs) TC5: VIRTUAL AND AUGMENTED REALITY / IMMERSIVE OR TACTILE INTERNET • These technologies have a number of potential use cases in both entertainment (e.g. gaming) and also more practical scenarios such as manufacturing or medicine, and could extend to many wearable technologies. • REQUIREMENTS: • Users data rate; • 1 Gbps in 95 % locations and 5 Gbps in 20 % locations), both in uplink and downlink • Frequency usage: • mmWaves • Technology Test trials: • Propagation at mmW frequency bands in indoor environment • Massive MIMO • mmW Antennas.

  13. 2- TEST CASES (TCs) Enabling 5G project Case Studies ENABLING 5G – CASE STUDIES SATELLITE USES IN 5G NETWORKS INTELLIGENT TRANSPORT NETWORKS (ITS) 60 GHz MULTIMEDIA DISTRIBUTION Study of Interference Cancellation Technologies Study of radio and propagation technologies for multimedia distribution Study of Satellite Technologies for 5G Objective • - Antennas for beamforming and MIMO. • - Pre-coding, massive MIMO. • - Prototypes in 5GHz band - Propagation in urban picocells at 60 GHz. - Design and measurement of antennas at 60 GHz. - Interaction antenna and MIMO system with human body. - Analysis of use of Q/V/W bands. - Beamforming and Interference cancellation techniques. -Fading compensation in Q/V/W bands. Technologies - Vehicle to infrastructure transmission in smart cities. - New system planning techniques in mm-bands. - Transmission systems in Gbps for airplanes, indoor and urban areas. - The satellite for 5G access network for multimedia applications in airplanes, emergency and remote areas. Application

  14. 3- TEST SCENARIOS: ITS Propagation inside buildings: TEST cases 1 and 4 • Measurements of propagation channel at MW and MMW propagation inside office, train stations and buildings. • Measurements with different types of channel sounders at different frequencies Ultra Wide Band propagation measurements MW bands 3.5- 6 GHz 2.5GHz Bandwidth Development of UWB channelsounder and antenna MmWavepropagationmeasurements. SlidingCorrelatorChannelsoundermeasurements at 60GHZ. VNA measurements at severalmmWbands: 30/ 50/70/90 GHz. Ray tracing simulation at different frequencies in confined environment: Simulation of confinedenvironments at differentfrequencies. Radiationpattern of developedantennas

  15. 3- TEST SCENARIOS: ITS Transportation and sensors communications: TEST cases 2 and 3 • Measurements and proof of concept at RF &MW and mmW frequencies on transportation systems. • Narrow band and wide band measurements • Narrow band propagation at mw and mmW. • Propagation inside trains • Propagation on industrial environment • Ultra Wide Band propagation measurements • MIMO in railway environment • Mmwave propagation measurements. • Narrow band propagation inside trains • Ray tracing simulation at different frequencies in confined environment: • Simulation of confined environments at different frequencies. • Measurements of radiation pattern of developed antennas

  16. 3- TEST SCENARIOS: ITS Bidirectional control link ground to UAV (TC2) MW bands 1- 6 GHz Satellite Multiusers Communications with UAVs (TC1): MW bands 1- 6 GHz mmWaves: 26-40Ghz?? Propagation modelling at Mw 1-6Ghz frequency bands Channel modelling MIMO antennas MW and mmWave antennas: directional, circular polarization Probe of concept using 4G LTE network3 UAVs communications: TEST cases 2 and 3 Stable flying platforms up to 100m height. Requirements and capabilities

  17. 3- TEST SCENARIOS: Multimedia Free space losses Rainfall attenuation Oxygen absorption Penetration losses Foliage looses Human Body Attenuation Urban picocell scenarios Studying propagation impairments at 60 GHz.

  18. 3- TEST SCENARIOS: Multimedia Mm wave short range wireless access. 2 to 7 GHz bandwidth antennas at 60 GHz frequency band Low price antennas. 60 GHz antennas. Indoor propagation scenarios. Indoor fentocell scenarios Antennas for Compact Range Communications at 60 GHz. mmW Antenna Indoor High Speed Coverage area Personal device

  19. 3- TEST SCENARIOS: Sat Ramón Ramón Ramón

  20. 4-TEST AND MEASUREMENT DEVELOPMENTS: ITS MIMO Ultra Wide Band Channel Sounder • Ultra Wide Band 3.5- 6 GHz, 2.5GHz Bandwidth • Narrow pulse technique • Use of frequency shaping filter design HPA 40dBm Conforming filter 3.5-6Ghz Picosecond PULSE GENERATOR MIMO SWITCH 2.5GHz Oscilloscope LNA Matched filter 3.5-6Ghz MIMO SWITCH Responsibles: UPM-Campus Sur & UPNA

  21. 4-TEST AND MEASUREMENT DEVELOPMENTS: ITS Antenna design • Ultra Wide Band Antennas • MW bands 3.5- 6 GHz • Linear or Circular polarized ( for UAVs) • 3d radiation pattern simulation and measurements Responsibles: UAM

  22. 4-TEST AND MEASUREMENT DEVELOPMENTS: ITS Test UAV platform • T810 UAV Hexacopter • Cicular Polarized antennas • Narrowband measurements • 900MHZ 4.4 GHz • System level measurements using Qualipoc R&S 4G test system and LTE network Responsibles: UPM-Campus Sur

  23. 4-TEST AND MEASUREMENT DEVELOPMENTS: Multimedia Propagation in urban scenarios • Measurement scenario. • 60 GHz progagation models. • Analysis of Free space losses, Rainfall attenuation, Oxygen absorption, Penetration losses, Foliage looses, Human Body Attenuation. Responsibles: UVigo

  24. 4-TEST AND MEASUREMENT DEVELOPMENTS: Multimedia RLSA Antenna Design at 60 GHz for Compact Range Communications • Analysis model. • Design methods. • Low cost fabrication at 60 GHz band. • Test methods. Responsibles: UPM-Ciudad Universitaria & UVigo

  25. 4-TEST AND MEASUREMENT DEVELOPMENTS: Sat Ramón • Communication System • Reflector Antennas • Array Antennas • Propagation model (Vigo) • Filtros en banda Q (Navarra) Responsibles: UPM-Ciudad Universitaria & UPNA & UVigo

More Related