A vehicle is provided including an electronic power steering system, an electronic throttle control system, and a stability control system.

The start system related to the present invention is for an internal combustion engine of a hybrid vehicle. The hybrid vehicle is configured to use at least one of a differential mechanism and a transmission gear mechanism to temporarily change an engine speed in starting of the internal combustion engine. The start system includes an electronic control unit. The electronic control unit is configured to determine a duration for which the engine speed needs to be changed in starting of the internal combustion engine. The electronic control unit is configured to determine a degree of change in the engine speed in starting of the internal combustion engine. The electronic control unit is configured to determine whether the engine speed needs to be changed by changing the gear position of the transmission gear mechanism based on the degree and the duration.

A control device for a driving device, the driving device includes a transmission and a hydraulic pressure generating device. The hydraulic pressure generating device includes an oil pump and a first mechanism. The first mechanism is configured to decrease hydraulic pressure of an oil passage connected with the oil pump. The control device includes an ECU. The ECU is configured to control the engine rotational speed to a first rotational speed and maintain vehicle speed by gear shifting, in a case where, while a vehicle is running in a predetermined running state, fuel consumption is smaller when the engine is driven at the first rotational speed, compared to fuel consumption in the predetermined running state, the first rotational speed is a rotational speed at which the hydraulic pressure is decreased, the predetermined miming state being a miming state in which the hydraulic pressure is not decreased.

A vehicle control device executes driving force control to set a target driving force in accordance with an engine operating state, and control an output of a driving source and a gear ratio of a continuously variable transmission so that a target driving force is realized. The device includes a power generator which can be driven by the driving source, and in a normal shifting mode, the driving force control is corrected on the basis of a power generating state of the power generator, and in a linear shifting mode giving priority to a revolution speed change of the driving source, the correction of the driving force control is not carried out.

A vehicle control system includes an acceleration generating device (engine, T/M) that generates an acceleration applied to a vehicle, and a vehicle control device that controls the acceleration generating device, based on an accelerator pedal stroke representing an operation of an accelerator pedal by a driver, and a vehicle speed of the vehicle. In the vehicle control system or method, the vehicle control device controls the acceleration generating device, based on a required acceleration that is determined based on a relationship between the accelerator pedal stroke and the required acceleration, including, as a condition, an acceleration corresponding to a given accelerator pedal stroke, which is specified by a relationship between the vehicle speed and the acceleration when the accelerator pedal stroke is held at the given value.

Systems and methods to reduce operating expenses of a vehicle based on control of operation of a vehicle system. The system includes a controller. The controller is structured to receive one or more parameters comprising expense data, adjust operating expenses of a vehicle system based on the one or more parameters, and generate a command structured to adjust operation of the vehicle system responsive to the adjustment of the operating expenses.

A vehicle is provided including an electronic power steering system, an electronic throttle control system, and a stability control system.

Systems and methods for operating an engine with deactivating and non-deactivating valves are presented. In one example, estimates of engine fuel consumption for operating the engine with a plurality of cylinder modes or patterns while a transmission is engaged in different gears are determined and are used as a basis for deactivating engine cylinders.

A power generation system for an internal combustion engine includes: a turbocharger capable of performing a turbocharger power generation using rotation of a turbine provided in an exhaust passage of the internal combustion engine; and a control unit including at least one electronic control unit. The control unit is configured to calculate a first power generation instruction value required for the turbocharger, and determine whether or not a magnitude relationship in which generated power of the turbocharger power generation is larger than an increase amount of a pumping loss of the internal combustion engine resulting from the turbocharger power generation is satisfied based on an operational state of the internal combustion engine, and calculate the first power generation instruction value larger when the magnitude relationship is satisfied than when the magnitude relationship is not satisfied.

Methods and systems are provided for integrating a bi-fuel engine with a CVT transmission. Responsive to a driver demand, a controller may determine whether to maintain usage of a current fuel or transition to an alternate fuel based on the cost efficiency of the transition and further based on any engine limitations that may be incurred at the engine speed-load following the transition. To improve the net fuel economy benefit while addressing the engine limitation, a fuel transition may be combined with a CVT adjusted engine speed-load regime, while maintaining engine power output.