Autonomous driving technology and ITS 10 March 2016 Sophia Antipolis, France Takanori MASHIKO Deputy Director, New-Generation Mobile Communications Office, Radio Dept., Telecommunications Bureau, Ministry of Internal Affairs and Communications (MIC), Japan
Contents 1 1. Autonomous driving technology in Japan 2.Next generation ITS 3. WRC 19 4. Summary
Autonomous driving demonstration by Toyota 2 Autonomous driving car on highway Inside of autonomous driving car GPS Receiver LIDAR Millimeter wave Radar
Concept car by Nissan 3 Stow steering, And pop-up monitor Nissan IDS Concept IDS : Intelligent Driving System Source: Nissan HP
Autonomous driving demonstration by Honda 4 The autonomous driving car has many sensors! ex. Millimeter wave radar, LIDAR, Camera The picture show the vehicle recognition of surrounding objects.
SIP (Strategic Innovative Promotion Program) - Overview 5 Aiming to realize Science & Technology Innovation through promoting R&D overlooking from basic research to implementation and commercialization by cross-ministerial cooperation. CSTI Governing Board PD (Program Director) PD: H. Watanabe (Toyota motor corporation) Promoting committee PD (chair) Related ministries, Management agencies, Experts from academia and public sector Management Agency (Funding Agency) Cabinet Office National Police Agency Ministry of Economy, Trade and Industry Ministry of Land, Infrastructure and Transport Ministry of Internal Affairs and Communications Research organizations Universities, Corporations, Research institutes, etc. Innovation of Automated Driving for Universal Services (SIP-adus) http://www.sip-adus.jp/ <ICT for Automated Driving> V V Communication and V I Communication Drawing up communications protocol and etc. V P (Pedestrian) Communication Developing direct communications style which uses dedicated terminals, mobile phone network application style system and etc. Infrastructure Radar System Developing 79 GHz band high resolution radar which can identify people, cars and etc.
SIP-adus: Mile stones 6 1.Reducing road crashes and etc. Achieving the national goal : The national infrastructure structure for achieving the national goal 2.Making self-driving system come true and becoming widely used the system: Turning the system into a commercial reality and promoting with research and development through A to Z and concurrent international cooperation 3.Putting into practical use of public transportation system for next-generation: Developing and working with as milestone on the road to Tokyo Olympics and Paralympics 2014 2015 2016 2017 2018 2019 2020 2030 Development and demonstration of Self-driving system Smoother transportation at the sag section on a freeway Creating trucks in one row, that have the same distance between each other and go at the same speed ITS spot Limited Highway Advanced Driving Aid ASV ACC ASV Automatic brake Public Road Advanced Driving Aid Demonstration experiment Quasi self-driving system (level 2) Demonstration experiment National target for road crash fatalities not greater than 2500 people Commercialization of quasi self-driving system (level 2) Pre-Tokyo Olympics & Pre-Paralympics Tokyo Olympics & Paralympics Practical realization in Tokyo of quasi self-driving system (level 3) Commercialization of level 3 Spread of transportation system for next-generation Quasi self-driving system (level 3 ) Spread Complete Self-Driving System DSSS Drive assist system (ITS + automatic brake )
SIP-adus: Six important themes 7 SIP-adus was based on six important themes. Theme leaders are liaison officers for international relations on these themes. Themes Theme Leader Dynamic Map Ryota SHIRATO Nissan Connected Vehicles Norifumi OGAWA Mazda Human Factors Satoshi KITAZAKI National Institute of Advanced Industrial Science and Technology (AIST) Impact Assessment Nobuyuki UCHIDA Japan Automobile Research Institute (JARI) Next Generation Transport Masayuki KAWAMOTO University of Tsukuba Security Satoru TANIGUCHI Toyota Info Technology Center
ITS based on ICT 8 Enhancement of ITS by effective use of Information Communication Technology VICS (Vehicle Information and Communication System) Since 1996 traffic information through FMmultiplex broadcasting, radio beacons and infrared beacons over 47 million vehicles as of June 2015 Probe information Probe information collection by each car maker Providing each users with traffic information ETC DSRC (Dedicated Short Range Communication) ETC (Electronic Toll Collection) since 2001 over 66 million vehicles as of May 2015 ITS Spot since 2011 About 1600 locations mainly on expressways nationwide Providing drivers with safe driving support information DSSS (Driving Safety Support Systems ) V2V, V2I and V2P communications via 700MHz band radio waves Target detection system in front On vehicle radar system using radio waves, supersonic waves and infrared ray, and camera Detecting vehicles and obstacles in front Warning, emergency brake, keeping inter vehicle distance Obstacles detection system around vehicle radar system using radio waves and supersonic waves, and camera Detecting obstacles and warning
(2) Simplified Graphic display type ITS Radio communications in Japan 9 700 MHz ITS (Advanced Driver Assistance Systems) Electronic Toll Collection System (ETC) Millimeter Wave Radar 24/26 GHz Band UWB Radar or 79 GHz Band High resolution Radar Avoiding Vehicle Collisions by vehicleto vehicle communications. 76 GHz Band Longdistance Radar 1620 khz 76~90 MHz 755.5~764.5 MHz 2.5GHz 5770~5850 MHz 22~29 GHz 60~61 GHz 76~77 GHz 78~81 GHz khz GHz Roadside Broadcasting (Highway radio) Vehicle Information and Communication System (VICS) Dedicated Short Range Communication (DSRC ITS Spot) (1) Text display type 左から合流車 注意 ITS spots provide information detected by roadside sensors. (2) Simplified Graphic display type (3) Map display type
ITU-R Recommendation on Radio Interface Standards of V2X 10 ITU-R Recommendation M.2084 Radio interface standards of vehicle-to-vehicle and vehicle-to-infrastructure communications for Intelligent Transport Systems applications World first commercial services of V2V! from TOYOTA in Japan Specifications ETSI IEEE ARIB(Japan) TTA(Korea) Frequency band 5855 5925 MHz 5850 5925 MHz 755.5 764.5 MHz 5855 5925 MHz (Single Channel) Channel width 10 MHz 10 MHz or 20 MHz Less than 9 MHz Less than 10 MHz Modulation system Data transmission rate Media Access Control BPSK OFDM, QPSK OFDM, 16QAM OFDM, 64QAM OFDM 3, 4.5, 6, 9, 12, 18, 24, 27 Mbps 64 QAM OFDM, 16 QAM OFDM, QPSK OFDM, BPSK OFDM 52 subcarriers 3, 4.5, 6, 9, 12, 18, 24, 27 Mbps (10MHz) 6, 9, 12, 18, 24, 36, 48, 54 Mbps (20MHz) BPSK OFDM, QPSK OFDM, 16QAM OFDM, 3, 4.5, 6, 9, 12, 18 Mbps BPSK OFDM, QPSK OFDM, 16QAM OFDM Option : 64QAM OFDM 3, 4.5, 6, 9, 12, 18 Mbps Option : 24, 27 Mbps CSMA/CA CSMA/CA CSMA/CA CSAM/CA, Option : Time slot based CSMA/CA FDD/TDD TDD TDD TDD TDD
What is next generation ITS? 11 Awareness is important for achieving autonomous driving. Autonomous Driving Car Stereo camera awareness of traffic lane Millimeter Radar(~100m) awareness of distance to a car driving ahead awareness of speed of a car driving ahead LIDAR(~several tens of meters ) awareness of around the car Autonomous driving car s on-board sensors are improving. What can ITS do? Next generation ITS can support Awareness!
For the Next generation ITS 12 Next generation ITS will support Awareness. High-Definition map? High data rate App.? ITS Dynamic map? V2V negotiation? V2I with on-road sensor? V2V broadcast? V2P? Com.? On board Sensors Static Dynamic Real-time We can turn on blinkers only when we change lanes. Autonomous driving cars can send the exact message, I d like to change lanes with the V2V communication system.
5G ITS 13 The Dynamic Map system is a core technology of the next generation ITS. Dynamic Map System Real-time Dynamic Static Requirements Low Latency High Data Rate 80 million cars in Japan Network load BIG Massive Device Connectivity 1 million/km² High Data Rate Max 10Gbps 5G Requirements Low Latency 1msec 5G ITS will make safe and more comfortable autonomous driving experience.
1.Overview Date: 25 Feb. 2016 Venue: Nikkei Hall, Tokyo Organizer: MIC, Japan Attendees: 500 Speakers: 14 MIC: ITS workshop ICT for Next Generation ITS 14 2. Presentations ITS radiocommunications related organizations from overseas (Mr. Arndt from ETSI TC ITS, Dr.Kenney from TOYOTA ITC U.S.A.) and Japan made the following presentations: - Status report of ITS development, overseas and in Japan - Report of ITS radiocommunications R&D projects coordinated by MIC
WRC-19: Agenda Item 1.12 15 Global or regional harmonization of frequency bands for ITS applications Resolution 237 COM6/13 (WRC-15) resolves to invite the 2019 World Radiocommunication Conference taking into account the results of ITU Radiocommunication Sector (ITU-R) studies, to consider possible global or regional harmonized frequency bands for the implementation of evolving ITS under existing mobile-service allocations, invites ITU-R to carry out studies on technical and operational aspects of evolving ITS implementation using existing mobile-service allocations, invites administrations to contribute actively to the ITU-R studies on this issue.
Summary 16 1. Autonomous driving is a key word for ITS in Japan. 2. 760MHz band ITS services(v2x) were deployed in Japan Last year. 3. The Dynamic Map system is a core technology of next generation ITS. 4. The Next generation ITS and 5G have good chemistry. but can we wait for the deployment of 5G? 5. WRC-19 agenda item Global or regional harmonization of ITS Spectrum. Let s work together!