Toward the Realization of Sustainable Mobility

GIES 2008 Toward the Realization of Sustainable Mobility March 14, 2008 Toyota Motor Corporation Senior Technical Executive Hiroyuki Watanabe 1

What Mobility Has Given us And What s Left 2

Achievements of Automobiles Greater movement ability (persons, things) Freedom and convenience: anytime, anywhere, to anyplace Movable personal space The development of mobility supports economic growth, as well as social and cultural expansion. 3

Challenges in Mobility Environment & Energy 1. CO2 Emission 2. Oil depletion, need for alternative energy 3. Air pollution Society 4. Traffic Accident 5. Traffic Congestion 6. Regional gap of mobility access 4

Environmental Energy Issue 1: CO2 Emission <Global CO2 Emission(by source, 2002)> Households 15% Industry 19% Power generation 43% Transport 23% Source:IEA/WEO 2004 Transport sector accounts for 23% of total emission Integrated approach is necessary in each sector 5

Environmental Energy Issue 2: Future of Petroleum U.S. Bureau of Mines Extractable volume of crude oil may peak in 20-50 years. 6

Amount of Bio Resources 5Livestock waste 43 4Agricultural waste 6Wood waste 49 37 7Crops (food crops, etc.) 3Vegetation (grasslands) 484 2Ocean 935 3007 1Forests (wood) 1438 21 19EJ Currently useable liquefied fuel converted from biomass resources Use of forests, vegetation (2%) 19EJ 38EJ Energy consumed globally by automobiles (2002) 65EJ 2020 EJ=10 18 J 130~150EJ 7

Destruction of forest and impact on the ecosystem Expansion of palm plantations on Sumatra 1960 1980 2000 2010 forecast Red indicates forested areas Since 1980, deforestation in Indonesia and elsewhere is mainly as a result of plantations Due to forest development, various organisms native to the rainforest are facing extinction Plantation development is accompanied by illegal felling (increased illegal felling of inland forests) If we seriously engage in bio-fuels as a business, it will be vital to stop environmental destruction (regulations etc.) 8

Future Energy Sources for Automobiles METI 2100 Sweden 2030 Electricity (Hydrogen) 90 10 20 30 40 50 60 70 80 90 % 10 Bio 80 70 60 50 40 Shell 2050 20 30 40 50 60 30 20 10 80 90 70 METI 2030 Oil Source: Toyota Motor Corporation 9

Changes in Mobility 1. Shift to Hybrid (driven by electric power) Plug-in Hybrid Fuel Cell Hybrid Electric Vehicle 2. Shift to Ubiquitous World 3. Robotization 4. Shift to HMI (Human-Machine Interface) to connect human s hearts with machine 10

LS600h 11

LS600h Fuel economy Fuel efficiency high LS600h Conventional vehicles Top line of existing gasoline engine vehicles 6.0L class 3.0L class low fast Acceleration slow Note: Based on the internal measured figure of Toyota Motor Corporation 12

1Plug In HV Systems(PHV) Potential for diversification of energy sources (flex-fuels), fading out from fossil fuel dependence and reduction of CO2 Two way MG1 MG2 E/G Tank 100 or 240 VAC Battery Breaker Outlet for Household supply Well to Wheel CO2 reduction USA (=Well to Wheel CO2 reduction Prius 1Well to Wheel 2 CO2 )1.0 0.5 Gasoline E85 Japan France Prius Plug in Hybrid Car 13

Inductive Charging System Demonstration Project for Hybrid Truck & Bus (Hino/Ministry of Transport) (National Traffic Safety and Environmental Lab./Waseda Univ./NEDO etc.) Electric-magnetic Induction Secondary Coil Source: Hino Controlling gap: 50mm Air Gap Secondary Core Primary Core Primary Coil 14

Freeze Start & Driving Performance Test of improved TOYOTA FCHV at Timmins, Canada Ambient Air Temp. 外気温 [ ] ( C) 10 10 0 0-10 -10-20 -20-30 -30-40 2/8 C -37 C 2/10 2/12 2/14 2/16 2/18 Date Ambient Air Temperature at Timmins ( F) 50 32 20 0-20 -40 - TOYOTA performed freeze start and driving performance tests at Timmins, Canada. (Minimum temperature : -37 C) - The driving performance immediately after start-up was the same level as conventional gasoline-powered vehicles. - No major problem occurred in the FC unit. 15

Cruising Range of Each Car-maker maker s s FCV Actual Cruising Range (mile) 500 400 300 200 *1 10-15 Japanese test mode (calculated by TMC) *2 Osaka-Tokyo trip ( ) 560 km (*2) Actual range of gasoline vehicles 780 km ( (*1) ) 800 700 600 500 400 300 Actual Cruising Range (km) TOYOTA FCHV FCHV ( 05) Improved TOYOTA FCHV 1000 1500 2000 Vehicle Weight (kg) ( )Each maker s s officially announced mode cruising range (Reference) Actual cruising range of 500 km is required to be competitive with gasoline engine vehicles. Improved TOYOTA FCHV, which is 25% more fuel efficient and can store app. 1.9 times the amount of hydrogen as the 05 model, successfully traveled between Osaka and Tokyo (560 km) without refueling. 16

Classic Theory of Automobile Efficiency Power plant efficiency η= Pd F1 1 F1 Pd Pd :Driving power F1 :Input fuel energy flow V:Vehicle cruising velocity D Pd = D V D = D (Driving resistance, acceleration force) 17

Mobility Performance Index Mobility Performance Index Im = W0 V F0 2 W0 V : Mobility Effect W0 : Weight of object to be moved (Payload) V : Vehicle cruising velocity F0 : Input primary energy flow (Differentiated by time) 18

Mobility Performance: Improvement Average speed (km / h) Tram 20 30 passengers Bicycle Walk 60 50 40 30 20 10 0 0 Performance figure: 7 7 times Suburban driving Corolla, 2-4 passengers, IW = 1,200kg City driving Single-passenger vehicle, IW = 300kg Single-passenger Corolla in Tokyo Performance figure: 1.0 10 20 30 40 Energy consumption ratio (per passenger) Single-passenger Tundra in LA Performance figure: 0.86 ~ 30 passengers 6 passengers 1 passenger Large bus ~ (KJ / secperson) 140 19 19

Average speed (km / h) 60 50 40 30 Optimal combination of diverse transport modes Ubiquitous Technology Performance figure: 7 Tram 20 30 20 passengers Bicycle 10 Walk 0 0 Mobility Performance: Realization 7 times Suburban driving Corolla, 2-4 passengers, IW = 1,200kg City driving Single-passenger vehicle, IW = 300kg Single-passenger Corolla in Tokyo 10 20 30 40 Energy consumption ratio (per passenger) Single-passenger Tundra in LA Performance Performance figure: 0.86 figure: 1.0 30 passengers 6 passengers 1 passenger Large bus (KJ / sec-person) Smooth traffic flow Reduction of energy consumption Innovation of Mobile Units and Energy Conversion ~ ~ ~ 140 - Automated parking Combining urban transit innovation with urban development - Upgrading the urban and road infrastructure - Introduction of ITS - Transportation demand management (TDM) - Reducing size and weight, automated driving, and automated platoon operation - Plug-in hybrid vehicles, electric vehicles, fuel-cell vehicles 20 20

Transportation and Logistics Renaissance Proposal Cutting congestion and CO 2 emission by half Reducing traffic fatality to zero Goals : Actions : Rebirth of urban traffic systems without congestion, CO 2 emission and accidents New generation logistic systems for timely delivery at competitive cost Concurrent efforts from diverse perspectives 1) Effective deployment of transportation infrastructure 2) Active application of advanced IT and ITS technologies 3) Market penetration of new generation vehicles 4) Awareness and participation by citizens and industries 5) Strategic policy decision and its implementation 21 21

Transportation and Logistics Renaissance Road Map 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 Industry Taskforce Task and target setting Model city selection Evaluation method Test plan Simulation Task and target setting Model city selection Evaluation method Test plan Simulation Task and target setting Model city selection Evaluation method Test plan Simulation Large scale Field Operation Test (FOT) FOT Phase I Through Field Evaluation Test (FOT) 1. More advanced technologies applied 2. Lager number of cities participated <Target Items> 1) Congestion 2) CO 2 emission 3) Ftality <Phase I> 1) 20% reduction 2) 20% reduction 3) 20% reduction Evaluation Adjustment Legislation FOT Phase II <Phase I> 1) 30% reduction 2) 30% reduction 3) 30% reduction Evaluation Adjustment Legislature FOT Phase III <Phase III> 1) 50% reduction 2) 50% reduction 3) Zero Implementation Practical operation Deployment and penetration (Confirmed at FOT, operation spreads ) 22

Plan: Project of Accelerating Reduction to the Society Realizing Safe & Smooth Road Transport utilizing Information Technology The Project of Accelerating Reduction to the Society aims to visualize for the citizen the outcome of large demonstration projects at a model city/line in a selected district, and to accelerate the application of successful practice on other areas. The special committee for new transportation & logistics in ITS Japan is taking initiatives in collaboration with industry, committed for realization with government. Council on Competitiveness- Nippon -Make direction -Promote a plan Proposal Advice Transport & Logistics Renaissance Project -Make a proposal -Launch the organization -Support promotion -Follow up outcome General Science & Technology Conference Project of accelerating reduction to the society Road Transport System (ITS)Task Force Policy-making, budget allocation, project promotion Leader: Councilor Mr. Okumura Member: Cabinet secretary, Police Agency Ministry of Internal Affairs and Communication Ministry of Economy, Trade, and Industry Ministry of Land, Infrastructure, Transport and Tourism Specialist: Intellectuals, ITS Japan ITS Japan The special committee for new transport & logistics Project proposal & promotion Town revival WG Auto manufacturers Electronic manufacturers City developer Model city/local district etc. Advanced logistics WG Auto manufacturers Electronic manufacturers Transport company Highway company Railway company etc. Academia 23

Example)Nantes, France: Mobility Demand and Change of Travel Method Traffic became smooth due to park & ride, despite population growth and increasing dependence on automobile. Number of trips Population Automobile method Walk Public transport Bicycle Share of Travel 24

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Integrated Safety Concept Parking Preventive safety Pre-crash safety Crash safety Rescue Coordination of safety systems All driving stages Integrated Safety Concept 26

Automotive Evolution 2004 Crown Majesta Front camera 2006 GS450h Driver monitor camera 2003 Harrier Front millimeterwave radar Front stereo camera Rear millimeter-wave radar Infrastructure-Coordinated Systems Pedestrian also detected 2006 LS460 Pre-crash Safety System Lane keeping Assist Vehicle-road communication Radar cruise control VSC (Vehicle Stability Control) Vehicle-vehicle communication Communication with pedestrians 27

Automotive to Robomotive Recognition Driver status (face direction, etc.) Vehicle behavior, etc. External environment recognition Decision DSS computer (Danger prediction: Optimal control according to extent of danger) Integrated control system DSS: Driver Support System Action HMI Vehicle control External communications Robotization i-unit Toyota Partner Robot 28

Achieving Sustainable Mobility Creating affluence for people, societies, and the world Heart and feelings People and technology lifestyles Ubiquitous technology Communities History, culture Health Diversifying values Appeal, vitality Aging society Harmonizing Technology for smoothing traffic flow Urban spaces, infrastructure Jidoka technology - Connecting - IT ITS RT Automated driving technology Fusion Automated High speed, platoon driving large volume, high efficiency - Expanding the scope of activities - Anytime, anywhere, to anyplace Security, safety, comfort, freedom Coordination Weight reduction technology Plug-in HV FCHV EV Diversification of mobility 29 Robots

Thank You for Your Attention. i Q_CONCEPT i - REAL 30