DOCSLIB.ORG

Self-Piloted Cars: the Future of Road Transport?

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Self-Piloted Cars: the Future of Road Transport? DIRECTORATE-GENERAL FOR INTERNAL POLICIES POLICY DEPARTMENT B: STRUCTURAL AND COHESION POLICIES TRANSPORT AND TOURISM RESEARCH FOR TRAN COMMITTEE – SELF-PILOTED CARS: THE FUTURE OF ROAD TRANSPORT? STUDY Provisional version This document was requested by the European Parliament's Committee on Transport and Tourism. AUTHORS Steer Davies Gleave: Roberta Frisoni, Andrea Dall’Oglio, Craig Nelson, James Long, Christoph Vollath, Davide Ranghetti, Sarah McMinimy RESPONSIBLE ADMINISTRATOR Piero Soave Policy Department Structural and Cohesion Policies European Parliament B-1047 Brussels E-mail: [email protected] EDITORIAL ASSISTANCE Adrienn Borka LINGUISTIC VERSIONS Original: EN ABOUT THE PUBLISHER To contact the Policy Department or to subscribe to its monthly newsletter please write to: [email protected] Manuscript completed in March 2016. © European Union, 2016. Print ISBN 978-92-823-9055-9 doi:10.2861/685052 QA-01-16-341-EN-C PDF ISBN 978-92-823-9056-6 doi:10.2861/66390 QA-01-16-341-EN-N This document is available on the Internet at: http://www.europarl.europa.eu/supporting-analyses DISCLAIMER The opinions expressed in this document are the sole responsibility of the author and do not necessarily represent the official position of the European Parliament. Reproduction and translation for non-commercial purposes are authorized, provided the source is acknowledged and the publisher is given prior notice and sent a copy. DIRECTORATE-GENERAL FOR INTERNAL POLICIES POLICY DEPARTMENT B: STRUCTURAL AND COHESION POLICIES TRANSPORT AND TOURISM RESEARCH FOR TRAN COMMITTEE – SELF-PILOTED CARS: THE FUTURE OF ROAD TRANSPORT? STUDY Provisional version Abstract The study provides an analysis of the development of automated vehicles inside and outside the EU, including both the technologies which are already on the market and those under testing and research. The EU is giving increasing attention to automated and connected vehicles as they could have huge impacts on road safety, travel behaviour and urban development. The study reports on state of the art key research projects and large scale testing in this area and discusses future pathways and potential impacts of increasing vehicle automation. It concludes with recommendations on aspects that should be considered when shaping policies to sustain the research and development, and bringing to market, of highly automated and connected vehicles. IP/B/TRAN/FWC/2010-006/Lot1/C1/SC11 2016 PE 573.434 EN Self-piloted cars: the future of road transport? ____________________________________________________________________________________________ CONTENTS LIST OF ABBREVIATIONS 7 LIST OF TABLES 11 LIST OF FIGURES 11 EXECUTIVE SUMMARY 13 1. INTRODUCTION 17 1.1. Preface 17 1.2. Study requirement 17 1.3. Organisation of the research study 17 2. AUTOMATED VEHICLES CLASSIFICATIONS 19 2.1. Introduction 19 2.2. Definitions 19 2.3. Automated vehicle classifications 19 2.4. Technology 23 3. ONGOING RESEARCH, TESTING AND ACTUAL IMPLEMENTATION 29 3.1. Introduction 29 3.2. Stakeholders and goals 29 3.3. Projects and application contexts 39 3.4. Legislative framework for testing and place into market 52 4. WHERE AUTOMATED CARS CAN BRING THE MOST BENEFITS 61 4.1. Introduction 61 4.2. Future pathways 61 4.3. Potential impacts of automated vehicles 66 5. CONCLUSION AND RECOMENDATIONS 89 5.1. Introduction 89 5.2. Findings and Conclusions 89 5.3. Recommendations 93 REFERENCES 99 5 Policy Department B: Structural and Cohesion Policies ____________________________________________________________________________________________ 6 Self-piloted cars: the future of road transport? ____________________________________________________________________________________________ LIST OF ABBREVIATIONS AAMVA American Association of Motor Vehicle Administrators ABI Association of British Insurers ABS Anti-lock Braking Systems ACASS Accident Causation Analysis with Seven Steps ACC Adaptive Cruise Control ADAS Advanced Driver Assistance Systems AEB Autonomous Emergency Breaking AEBS Advanced Emergency Braking Systems AI Artificial Intelligence ARTS Automated Road Transport Systems CACC Cooperative Adaptive Cruise Control CCF Connected Car Forum CES Consumer Electronic Show CIS Center for Internet and Society C-ITS Cooperative Intelligent Transport Systems DAE Digital Agenda for Europe DARPA Defense Advanced Research Projects Agency DAVI Dutch Automated Vehicle Initiative DfT Department for Transport (UK) DSRC Dedicated Short-Range Communication EPoSS European Technology Platform on Smart Systems Integration EPSRC Engineering and Physical Sciences Research Council ERTRAC European Road Transport Research Advisory Council ESC Electronic Stability Control 7 Policy Department B: Structural and Cohesion Policies ____________________________________________________________________________________________ ESP Electronic Stability Program EU European Union FCA Fiat Chrysler Automobile FCW Forward Collision Warning Fordonsstrategisk Forskning och Innovation FFI (Strategic Vehicle Research and Innovation – Finland) FHWA Federal Highway Administration FIA Federation Internationale de l'Automobile GHG GreenHouse Gas GIS Geographic Information Systems GPS Global Positioning Systems IIHS Insurance Institute for Highway Safety ITF International Transport Forum ITS Intelligent Transportation System LCA Lane Change Assist LDW Lane Departure Warning LKA Lane Keeping Assist MIT Massachusetts Institute of Technology NHTSA National Highway Traffic Safety Administration OECD Organisation for Economic Co-operation and Development OICA International Organization of Motor Vehicle Manufacturer OTA Over The Air PA Park Assist PDC Park Distance Control PROUD Public Road Urban Driverless PRT Personal Rapid Transit 8 Self-piloted cars: the future of road transport? ____________________________________________________________________________________________ R&D Research & Development SAE Society of Automotive Engineers SARTRE Safe Road Trains for the Environment SNACS SafetyNet Accident Causation System StVO Straßenverkehrsordnung (German Road Traffic Code) TCS Traction Control System TLN Transport en Logistiek Nederland Toegepast Natuurwetenschappelijk Onderzoek (Netherlands TNO Organisation for Applied Scientific Research) TTI Texas Transportation Institute UK United Kingdom UNECE United Nations Economic Commission for Europe US United States USDOT United States Department of Transportation Eidgenössisches Departement für Umwelt, Verkehr, Energie und Kommunikation UVEK (Federal Department of Environment, Transport, Energy and Communications - Switzerland) VDA German Association of Automotive Industry V2I Vehicle to Infrastructure V2V Vehicle-‐to‐-Vehicle VMT Vehicle-Miles Travelled VRAIN Vehicular Risk Awareness Intelligence Network Väg- och TransportforsknIngsinstitut VTI (Swedish National Road and Transport Research Institute) 9 Policy Department B: Structural and Cohesion Policies ____________________________________________________________________________________________ 10 Self-piloted cars: the future of road transport? ____________________________________________________________________________________________ LIST OF TABLES TABLE 1 Examples of application of automated vehicles in private cars under the evolutionary approach 40 TABLE 2 Examples of application of automated vehicles in private cars under the revolutionary approach 45 TABLE 4 Examples of application of automation on urban mobility and in public transport vehicles 49 TABLE 5 SWOT analysis about vehicle automation 93 TABLE 6 Lesson learned, recommendations and an assessment of developments in vehicle automation 94 LIST OF FIGURES FIGURE 1 SAE International’s Levels of Automation 20 FIGURE 2 SAE International versus NHTSA automated vehicles classification 22 FIGURE 3 Major categories of stakeholders involved in automated vehicle deployment 30 FIGURE 4 Road fatalities in the EU since 1995 67 FIGURE 5 Number of fatalities, number of injury accidents and million passenger-km in the EU, 1995-2013 (1995 = 100) 68 11 Policy Department B: Structural and Cohesion Policies ____________________________________________________________________________________________ 12 Self-piloted cars: the future of road transport? ____________________________________________________________________________________________ EXECUTIVE SUMMARY Existing implementation A variety of driving assistance systems of Level 0 (no automation), Level 1 (driver assistance) and a smaller number of Level 2 (part automation) technologies are currently available on the market, mainly implemented on passenger cars to support driving on motorways or for parking. Vehicle manufacturers are investing in R&D of more advanced automation systems up to Level 3 (conditional automation), which are expected to further improve the driving safety and comfort of private vehicles. Concurrently, research and testing of higher automated systems (level 4 – high automation and level 5 – full automation) is already underway. The concept of “self-driving vehicle” represents the pinnacle of vehicle automation, although, at the moment, the implementation of fully automated vehicles still requires a considerable amount of research and technological advancement. In the EU a number of countries – namely the UK, Sweden, Germany, France and The Netherland - are taking significant steps to be at the forefront of research in this sector; in many cases actions in this area are led by vehicle manufacturers. Outside Europe, the United States
Load more

Recommended publications
  • Optimized Route Network Graph As Map Reference for Autonomous Cars Operating on German Autobahn
    Optimized Route Network Graph as Map Reference for Autonomous Cars Operating on German Autobahn Paul Czerwionka, Miao Wang Artificial Intelligence Group Institute of Computer Science Freie Universitat¨ Berlin, Germany Abstract— This paper describes several optimization tech- mapping errors are more crucial when driving at high speeds, niques used to create an adequate route network graph for performing lane changes or overtaking maneuvers. autonomous cars as a map reference for driving on German An universal format to define such digital road maps has autobahn or similar highway tracks. We have taken the Route Network Definition File Format (RNDF) specified by DARPA been issued by the Defense Advanced Research Projects and identified multiple flaws of the RNDF for creating digital Agency (DARPA) for its autonomous vehicle competitions in maps for autonomous vehicles. Thus, we introduce various desert terrain in 2004 and 2005, and in urban environments enhancements to it to form a digital map graph called RND- in 2007. The Grand Challenges 2004 and 2005 used a route FGraph, which is well suited to map almost any urban trans- definition data format (RDDF) which consists of a list of portation infrastructure. We will also outline and show results of fast optimizations to reduce the graph size. The RNDFGraph longitudes, latitudes, speed limits, and corridor widths that has been used for path-planning and trajectory evaluation by define the course boundary. It was later updated to a route the behavior module of our two autonomous cars “Spirit of network definition file (RNDF) for the Urban Challenge Berlin” and “MadeInGermany”. We have especially tuned the including stop signs, parking spots and intersections.
    [Show full text]
  • Anna University:: Chennai 600 025 University Departments Curriculum – R 2013 B.E. (Part – Time) – Automobile Engineering
    ANNA UNIVERSITY:: CHENNAI 600 025 UNIVERSITY DEPARTMENTS CURRICULUM – R 2013 B.E. (PART – TIME) – AUTOMOBILE ENGINEERING I – VII SEMESTERS CURRICULA & SYLLABI SEMESTER I SL. CODE NO. COURSE TITLE L T P C NO. THEORY 1 PTMA8151 Applied Mathematics 3 0 0 3 2 PTPH8151 Engineering Physics 3 0 0 3 3 PTCY8152 Engineering Chemistry 3 0 0 3 4 PTGE8153 Engineering Mechanics 3 0 0 3 5 PTGE8151 Computing Techniques 3 0 0 3 TOTAL 15 0 0 15 SEMESTER II SL. CODE NO. COURSE TITLE L T P C NO. THEORY 1 PTAU8201 Electrical and Electronics Engineering 3 0 0 3 2 PTAU8202 Manufacturing Processes 3 0 0 3 3 PTAU8203 Measurement System for Automobiles 3 0 0 3 4 PTAU8204 Thermodynamics and Thermal Engineering 3 0 0 3 5 PTMA8251 Numerical Methods 3 0 0 3 TOTAL 15 0 0 15 SEMESTER III SL. CODE NO. COURSE TITLE L T P C NO. THEORY 1 PTAU8301 Automotive Chassis 3 0 0 3 2 PTAU8302 Automotive Electrical and Electronics 3 0 0 3 3 PTAU8303 Automotive Petrol Engines 3 0 0 3 4 PTAU8304 Solid Mechanics 3 0 0 3 5 PTAU8305 Theory of fuels and Lubricants 3 0 0 3 TOTAL 15 0 0 15 1 SEMESTER IV SL. CODE NO. COURSE TITLE L T P C NO. THEORY 1 PTAU8401 Automotive Diesel Engines 3 0 0 3 2 PTAU8402 Automotive Transmission 3 0 0 3 3 PTAU8403 Two and Three Wheeler Technology 3 0 0 3 4 PTPR8351 Kinematics and Dynamics of Machines 3 0 0 3 PRACTICAL 5 PTAU8411 Automotive Engine and Chassis Components 0 0 3 2 Laboratory TOTAL 12 0 3 14 SEMESTER V SL.
    [Show full text]
  • Human Centred Design of First and Last Mile Mobility Vehicles
    Coventry University DOCTOR OF PHILOSOPHY Human centred design of first and last mile mobility vehicles Wasser, Joscha Award date: 2020 Awarding institution: Coventry University Link to publication General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of this thesis for personal non-commercial research or study • This thesis cannot be reproduced or quoted extensively from without first obtaining permission from the copyright holder(s) • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal Take down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Download date: 11. Oct. 2021 Human Centred Design of First and Last Mile Mobility Vehicles by 1,2,4 Joscha Wasser A thesis submitted in partial fulfilment of the University’s requirements for the Degree of Doctor of Philosophy. Supervisors: Andrew Parkes1, Cyriel Diels3, Michael Tovey1 and Anthony Baxendale2 1 The National Transport Design Centre, Swift Road, Coventry CV1 2TT, UK 2 HORIBA MIRA Ltd, Watling Street, Nuneaton, Warwickshire, CV10 0TU, UK 3 Royal College of Art, Kensington Gore, Kensington, London SW7 2EU, UK 4 Fraunhofer FKIE, Fraunhoferstraße 20, 53343 Wachtberg, Germany Content removed on data protection grounds 2 3 4 5 6 Content removed on data protection grounds 7 Content removed on data protection grounds 8 Content removed on data protection grounds 9 10 Acknowledgements I would like to express my sincere gratitude to Dr.
    [Show full text]
  • Scenarios for Autonomous Vehicles – Opportunities and Risks for Transport Companies
    Position Paper / November 2015 Scenarios for Autonomous Vehicles – Opportunities and Risks for Transport Companies Imprint Verband Deutscher Verkehrsunternehmen e. V. (VDV) Kamekestr. 37–39 · 50672 Cologne · Germany T +49 221 57979-0 · F +49 221 57979-8000 [email protected] · www.vdv.de Contact Martin Röhrleef üstra Hannover, Head of the Mobility Association Department Chairman of the VDV working group “Multimodal Mobility” T +49 511 1668-2330 F +49 511 1668-962330 [email protected] Dr. Volker Deutsch VDV, Head of the Traffic Planning Department T +49 221 57979-130 F +49 221 57979-8130 [email protected] Dr. Till Ackermann VDV, Head of the Business Development Department T +49 221 57979-110 F +49 221 57979-8110 [email protected] Figure sources Title, page 18 VDV Page 5 VDA Page 9 Morgan Stanley Summary: Autonomous vehicles: opportunities and risks for public transport The development and operation of fully automated, driverless vehicles (“autonomous vehicle”) will have a disruptive impact on the transport market and thoroughly mix up the present usage patterns as well as the present ownership and business models. The autonomous vehicle is a game changer, not least because the traditional differences between the various modes of transport become indistinct as an autonomous vehicle can be everything, in principle: a private car, a taxi, a bus, a car-sharing vehicle or a shared taxi. To express it dramatically: the autonomous vehicle could be part of the public transport system – but it could also seriously threaten the existence of today’s public and long-distance transport: The autonomous vehicle can threaten the existence of public transport because it makes driving much more attractive.
    [Show full text]
  • Industry Ponders Natural Gas Applications
    160 years of innovation theengineer.co.uk March 2016 | £3.70 FIRST FOR TECHNOLOGY & INNOVATION Fossil future Industry ponders natural gas applications N • 1 O 6 I 0 T Y A E V A O R N S N I O F & E G N N G I I R N E E Mono mania Taking aim Space spin-off How a Liverpool-based SME HVM Catapult technology Ultrasound technology is leaving bigger supercar chief Dr Phill Cartwright developed to monitor manufacturers outlines his vision for astronauts comes in its wake »31 the future »34 back down to Earth »49 58 »Careers feature Britain’s booming automotive sector has a pressing skills shortage TE_010316 1 02/03/2016 18:42 Your One-Stop Shop for Process Measurement and Control Products • 100,000 products online • Easy online ordering • Same day shipping on instock items • Full technical support Platinum Series Series High accuracy, fast responding,respo low cost temperature and process controllers Flow and Environmental Products Large selection of flow and environmental devices including handheld, ultrasonic, controllers and much more PXM309 series Available in absolute or gauge pressure and sealed to IP65 /IP67 We are here to serve you With our manufacturing know-how and extensive warehousing around the world, OMEGA offers the most impressive range of products in the industry. Probes and Assemblies Our sales representatives are able to swiftly dispatch For all environments and applications your order and provide instantaneous updates. At OMEGA, no request or order is too big or too small. omega.co.uk 0800 488 488 Temperature Pressure Automation Flow DAS pH Heaters [email protected] © COPYRIGHT 2015 OMEGA ENGINEERING,LTD.
    [Show full text]
  • Regulatory Landscape
    REGULATORY LANDSCAPE: Regulation is one 12 of the major drivers of change within the automotive sector; changes happening at almost every level are forcing an evolution of the sector THE INNOVATION GAME: 34 David Moss, Nissan's Vice President, Vehicle Design and Development, discusses LCV innovation The UK automotive sector operates in a unique environment, with strategic alignment between industry and government support Ian Constance, While the internal combustion chief executive engine will remain part of the of the Advanced Propulsion Centre automotive ecosystem for some time to come, there is an increasing need to conserve fuel and minimise emissions lobal climate-change Europe. The UK automotive sector common technical interest. while maintaining compelling and air-quality operates in a unique environment, At the APC we have identified consumer propositions. agendas are driving with strategic alignment between a number of opportunity areas This is leading to increased rapid technological industry and government support. that align strong capability and electrification of the vehicle change within The UK combines world-leading good potential for growth in powertrain, which in turn the automotive research, world-renowned organisations operating in the UK is disrupting incumbent sector. This, in aptitude for innovation and with likely market demand. These supply chains, and providing turn, is creating world-class manufacturing provide the potential for the UK opportunities for organisations new opportunities productivity. to assert a strong future supply- willing to embrace change. globally, as Combining these advantages chain position, given suitable Organisations operating international, in a collaborative approach investment. Identifying these in the UK can build upon the national and local underpins the aims of the opportunities is a step towards advantages and capabilities regulations drive Advanced Propulsion Centre (APC) providing a foundation for further afforded by the British action on CO2 emissions and programme.
    [Show full text]
  • Sustainable Mobility in Rural Areas Based on Autonomous Vehicles and Mobility On-Demand
    Die approbierte Originalversion dieser Diplom-/ Masterarbeit ist in der Hauptbibliothek der Tech- nischen Universität Wien aufgestellt und zugänglich. MSc Program http://www.ub.tuwien.ac.at Environmental Technology & International Affairs The approved original version of this diploma or master thesis is available at the main library of the Vienna University of Technology. http://www.ub.tuwien.ac.at/eng Sustainable Mobility in Rural Areas based on Autonomous Vehicles and Mobility On-Demand A Pre-feasibility Study for Lower Austria A Master’s Thesis submitted for the degree of “Master of Science” supervised by em. Univ.-Prof. Dr. Günther Brauner Mag. (FH) Laura Beitz 1428134 Vienna, 05 June 2016 Affidavit I, LAURA BEITZ , hereby declare 1. that I am the sole author of the present Master’s Thesis, "SUSTAINABLE MOBILITY IN RURAL AREAS BASED ON AUTONOMOUS VEHICLES AND MOBILITY ON-DEMAND. A PRE- FEASIBILITY STUDY FOR LOWER AUSTRIA", 90 pages, bound, and that I have not used any source or tool other than those referenced or any other illicit aid or tool, and 2. that I have not prior to this date submitted this Master’s Thesis as an examination paper in any form in Austria or abroad. Vienna, 05.06.2016 Signature Abstract In the past century, private automobiles have shaped personal mobility by enabling fast and convenient point-to-point travel. However, this development is having a serious effect on the sustainable nature of our transport system. To transform personal transportation to a sustainable mobility system, two fields of research are currently receiving considerable attention: autonomous vehicles and mobility on-demand.
    [Show full text]
  • Driving Changes: Automated Vehicles in Toronto
    Driving Changes: Automated Vehicles in Toronto Discussion paper David Ticoll Distinguished Research Fellow Innovation Policy Lab Munk School of Global Affairs University of Toronto October 15, 2015 ii Mercedes-Benz F015 driverless concept car in San Francisco (Jordan 2015) Yonge Street looking north from Adelaide Street, 1929 (Taylor 2014) Yonge Street looking north from Adelaide Street, 1900 (Galbraith Photograph Company n.d.) Driving Changes: Automated Vehicles in Toronto iii Contents 1 ABOUT THIS PROJECT 1 2 DRIVING CHANGES: EXECUTIVE SUMMARY 3 3 TOPICS FOR CONSIDERATION 9 3.1 STRATEGIC PATHWAYS 9 3.2 TRANSPORTATION PLANNING 10 3.3 CITY PLANNING 11 3.4 INFRASTRUCTURE & TECHNOLOGY 11 3.5 REGULATION 12 3.6 ECONOMIC DEVELOPMENT 13 4 AUTOMATED VEHICLES: A PRIMER FOR POLICY MAKERS 14 4.1 THE IDEA IN BRIEF 14 4.2 SAE LEVELS OF AUTOMATION 14 4.3 COMPETING MODELS OF AV DEPLOYMENT 17 4.4 ADOPTION TIMING 18 4.5 2030S: THREE SCENARIOS 20 4.6 THE TRANSITION 22 4.7 URBAN AND SOCIAL TRENDS 22 5 BENEFITS OF AVS FOR TORONTO 23 5.1 SAFETY 23 5.2 EQUITY AND ACCESSIBILITY 25 5.3 ENVIRONMENT 27 5.4 OPERATING COSTS 28 5.5 CONGESTION 31 5.6 CITY FLEET SERVICES 33 6 AV IMPACTS AND IMPLEMENTATION CONSIDERATIONS 34 6.1 LEADERSHIP 34 6.2 TRANSPORTATION PLANNING AND URBAN DESIGN 35 6.3 INTELLIGENT TRANSPORTATION SYSTEMS 36 6.4 PUBLIC TRANSIT 38 6.5 FREIGHT 39 6.6 WINTER CONDITIONS 39 6.7 DATA POLICIES 40 6.8 REGULATION 43 6.9 FISCAL IMPACT 45 6.10 ECONOMIC IMPACT 46 7 GOVERNMENT INITIATIVES 50 7.1 CANADA 50 7.2 UNITED STATES 50 7.3 EUROPE 51 iv 7.4 ASIA & AUSTRALIA 53 8 APPENDICES 54 8.1 AV TECHNOLOGIES AND THEIR IMPLICATIONS 54 8.2 NHTSA LEVELS OF VEHICLE AUTOMATION 58 9 WORKS CITED 59 Driving Changes: Automated Vehicles in Toronto 1 1 About this project This report was commissioned by City of Toronto Transportation Services Division as part of a broader project under the University of Toronto Transportation Research Institute (UTTRI).
    [Show full text]
  • The Impact of Automated Transport on the Role, Operations and Costs of Road Operators and Authorities in Finland
    The impact of automated transport on the role, operations and costs of road operators and authorities in Finland EU-EIP Activity 4.2 Facilitating automated driving Risto Kulmala, Juhani Jääskeläinen, Seppo Pakarinen Traficomin tutkimuksia ja selvityksiä Traficoms forskningsrapporter och utredningar Traficom Research Reports 6/2019 Traficom Research Reports 6/2019 Julkaisun päivämäärä 12.3.2019 Julkaisun nimi The impact of automated transport on the role, operations and costs of road operators and authorities in Finland (Automaattiajoneuvojen vaikutukset tienpitäjien ja viranomaisten rooliin, toimintaan ja kustannuksiin Suomessa) Tekijät Risto Kulmala, Juhani Jääskeläinen, Seppo Pakarinen Toimeksiantaja ja asettamispäivämäärä Liikennevirasto ja Trafi 22.3.2018 Julkaisusarjan nimi ja numero ISSN verkkojulkaisu) 2342-0294 Traficomin tutkimuksia ja selvityksiä ISBN (verkkojulkaisu) 978-952-311-306-0 6/2019 Asiasanat Automaattiajaminen, tieliikenne, automaattiauto, vaikutus, tienpitäjä. viranomainen, rooli, kustannukset, toiminta, Suomi Tiivistelmä Tämä kansallinen tutkimus tehtiin osana työpakettia ”Facilitating automated driving” EU:n CEF- ohjelman hankkeessa EU EIP keskittyen viiteen korkean tason automaattiajamisen sovellukseen: moottoritieautopilotti, automaattikuorma-autot niille osoitetuilla väylillä, automaattibussit sekaliikenteessä, robottitaksit sekä automaattiset kunnossapito- ja tietyöajoneuvot. Raportti kuvaa automaattiajamiseen liittyvät säädöspuitteet ja viranomaisstrategiat eri puolilla maailmaa ja etenkin Euroopassa. Tutkimus
    [Show full text]
  • La Computación En México Por Especialidades Académicas
    La Computación en México por Especialidades Académicas ACADEMIA MEXICANA DE COMPUTACIÓN 2017 ACADEMIA MEXICANA DE COMPUTACIÓN A. C. Presidente Dr. Luis Alberto Pineda Cortés Vicepresidente Dr. Luis Enrique Sucar Succar Tesorero Dr. Carlos Artemio Coello Coello Secretarios Dr. Christian Lemaitre León Dr. Francisco Javier Cantú Ortiz Vocal Dr. Jesús Favela Vara Coordinadores de Secciones Académicas Conocimiento y Razonamiento Dr. Ramón Felipe Brena Pinero Aprendizaje e Inteligencia Computacional Dr. Carlos Alberto Reyes García Tecnologías de Lenguaje Dr. Luis Villaseñor Pineda Robótica de Servicio Dr. Alejandro Aceves López Ingeniería de Software Dra. Hanna Oktaba Interacción Humano-Computadora Dr. Luis Adrián Castro Análisis de Señales y Procesamiento de Patrones Dra. Pilar Gómez-Gil Computación Evolutiva Dr. Carlos Artemio Coello Coello La Computación en México por especialidades académicas Luis Alberto Pineda Cortés Coordinador y editor ACADEMIA MEXICANA DE COMPUTACIÓN, A, C. 2017 La Computación en México por especialidades académicas Coordinador general: Luis Alberto Pineda Cortés. Primera edición: 2017 Academia Mexicana de Computación, A. C. Todos los derechos reservados conforme a la ley. ISBN: 978-607-97357-1-5 Corrección de estilo: Luis Alberto Pineda Cortés Formación: Homero Buenrostro Trujillo. Diseño de portada: Mario Alberto Vélez Sánchez. Cuidado de la edición: Nydia De Ávila Jiménez y Homero Buenrostro Trujillo. Este libro se realizó con el apoyo del CONACyT: Proyecto 271979 “Programa Anual de Actividades de la Academia Mexicana de Computación 2016” Queda prohibida la reproducción parcial o total, directa o indirecta, del contenido de esta obra, sin contar con autorización escrita de los autores, en términos de la Ley Federal del Derecho de Autor y, en su caso, de los tratados internacionales aplicables.
    [Show full text]
  • Demonstrating Safe Autonomous Vehicles for Everyday Commute
    U.S. Department of Transportation NOFO # 693JJ319NF00001 Demonstrating Safe Autonomous Vehicles For Everyday Commute Submitted by: University of Virginia Charlottesville, VA Albemarle County, VA JAUNT Inc. Sonny Merryman, Inc. Charlottesville/Albemarle, VA Evington, VA Perrone Robotics, Inc. ARBOC Specialty Vehicles Crozet, VA Middlebury, IN Demonstrating Safe Autonomous Vehicles For Everyday Commute – Project Narrative and Technical Approach University_of_Virginia_Part1 U.S. Department of Transportation (USDOT) Federal Highway Administration (FHWA) 1200 New Jersey Avenue, SE Washington DC 20590 Attn: Sarah Tarpgaard, HCFA-32 Dear Ms. Tarpgaard: We are excited to respond to the U.S. Department of Transportation’s Automated Driving System Demonstration Grant (NOFO Number 693JJ319NF00001) with our enclosed proposal entitled: SAVvy Mobility - Demonstrating Safe Autonomous Vehicles For Everyday Commute submitted by the University of Virginia in collaboration with JAUNT Inc, Perrone Robotics Inc., Albemarle County, VA, Sonny Merryman, and ARBOC. We are requesting a total budget of $10M for a demonstration period of 24 months (Sep 2019-Aug 2021). Automated vehicles are rapidly becoming significant components of our nation’s critical infrastructure. While they hold promise for considerable benefits, they also bring with them urgent safety-critical challenges that must be addressed. In addition, as journeys become fully automated, the experience itself will need to become more accessible to all in our population. The safety, mobility, and economic benefits of highly automated vehicles should be accessible to everyone, and everywhere. The majority of automated driving demonstrations to date have focused on operation and impact in urban settings, with the testing of automated cab services. The perspective of the proposed demonstration is much broader: Automated transit vehicles could be the key to catalyzing the mobility for people living in small and medium sized suburban areas.
    [Show full text]
  • The Future of Autonomous Cars a Scenario Analysis of Emergence and Adoption Master’S Thesis in Management and Economics of Innovation
    The Future of Autonomous Cars A Scenario Analysis of Emergence and Adoption Master’s thesis in Management and Economics of Innovation LUDVIG BARREHAG Department of Technology Management and Economics CHALMERS UNIVERSITY OF TECHNOLOGY Gothenburg, Sweden 2018 The Future of Autonomous Cars A Scenario Analysis of Emergence and Adoption LUDVIG BARREHAG © LUDVIG BARREHAG, 2018 Technical report no E2018:114 Department of Technology Management and Economics Chalmers University of Technology SE-412 96 Göteborg Sweden Telephone +46 (0)31-772 1000 Department of Technology Management and Economics Göteborg, Sweden 2018 "The horse is here to stay, but the automobile is only a novelty – a fad," Stated by the president of the Michigan Savings Bank while advising Henry Ford's lawyer not to invest in Ford Motor Co. Something the lawyer did nonetheless which earned him the fortune of his life. Acknowledgments Several people have been of great help in the making of this study. First of all, I would like to thank Erik Bohlin, my tutor who has guided my work and continuously provided good advice in terms of structuring and making sense of the results. An extra appreciation goes to his great patience in a time when this study got put on hold. I also owe a large appreciation to Berg Insight and in particular Johan Fagerberg who made this study possible through a combination of good advice, access to extensive amount of data as well as a beautiful office to work in with an excellent coffee machine. For anyone interested in reading a market research analysis version of this study I refer to the title The Future of Autonomous Cars available at Berg Insight.
    [Show full text]