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There exist many environmental and earth resource problems to be solved for the 21st century. Hybridization of both internal combustion powertrains and fuel cell powertrains holds great promise for next generation vehicles. This paper describes the lessons learned during design, development, production and marketing of nearly 700,000 hybrid vehicles to date. We review the evolution of major components with a focus on reducing cost, mass and volume while increasing power and efficiency. We also describe the future prospects for hybrid vehicles.

There exist many environmental and earth resources problems to be solved for the 21st century. Internal combustion engine / electric motor hybrid and fuel cell hybrid vehicles are promising next generation vehicles. This paper describes the current status of the electric power train of ICE hybrids. Based on the mutual features of both ICE and fuel cell hybrid vehicles, this paper also addresses the future opportunities to strive towards sustainable development in future automobiles. We also examine some test cycle to in-use efficiency issues.

Following its introduction into the Japanese market, the Prius, Toyota Motor Corporation's hybrid vehicle, was released onto the American and European markets in Mid-2000. This lecture will take the form of an explanation of the new technology used to meet the demands of the western market, including improved driving performance, lower emissions, down-sizing of the system and lower costs. The lecture will also look briefly at the new Toyota hybrid system, the THS-C, which is currently being developed. The talk will include a look at the future of the hybrid vehicle.

An advanced and practical fuel injection control system to reduce exhaust gas emissions has been developed. This control uses an exhaust air-fuel ratio (EAFR) sensor and a heated exhaust oxygen (HEO) sensor. The air fuel ratio of exhaust gas is precisely converged to stoichiometry. The integrated deviation of the mass of fuel inducted into the cylinder is rapidly converged to zero, so as to maximize the conversion efficiency of catalysts. The controller is derived from the models that express the dynamic phenomena. The experimental results show the effectiveness of this system for future exhaust emissions and enhanced evaporative emissions.