Abstract: A driving force control unit for a vehicle, which allows transmission of driving force from a driving motor to driving wheels irrespective of releasing an accelerator pedal at a certain or lower vehicle speed when a transmission is set in a driving range, and which switches the magnitude of the driving force while the accelerator pedal is released at vehicle speed no more than the certain vehicle speed between a greater condition and a smaller condition in accordance with depression of the brake pedal so that the driving force is made lower at a depression of the brake pedal than at a release of the brake pedal. In the driving force control unit, the driving force value in said greater condition upon switching from said smaller condition to said greater condition, at a release of the brake pedal during the time the vehicle stops, is increased or decreased according to an inclination angle of the vehicle at the time of stopping.

Abstract: A method for controlling an internal combustion engine provided on a vehicle and cooperating with the throttle hand lever and an accelerator pedal, whereby the amount of fuel is predetermined. The amount of fuel is predetermined by respective positions of the accelerator pedal and throttle hand lever and is corrected on the basis of a position of the vehicle brake pedal.

Abstract: An automatic engine stop control system for a vehicle in which: an engine is activated when fed with a fuel; and an action mechanism has an action content influenced by a rotating state of the engine; and the fuel feed to the engine is stopped when predetermined conditions are satisfied during the running of the vehicle comprises: a rotating state decider for deciding that the engine is forced to rotate by a running inertia force owned by the vehicle while the vehicle is coasting; an action state decider for deciding the action content of the action mechanism in the state where the engine is forced to rotate by the running inertia force of the vehicle; and an automatic stop inhibitor for inhibiting the stop of the fuel feed to the engine when it is decided by the action state decider means that the action content of the action mechanism is insufficient.

Abstract: In method and apparatus for automatically stopping an engine idling for an automotive vehicle, a vehicular velocity it detected, a brake manipulated variable of a brake manipulator is detected, the brake manipulated variable is compared with a predetermined criterion to determine whether a brake manipulator is operated, the engine is stopped when the vehicular velocity is detected to be zero and the brake manipulator is determined to be operated, the engine is re-stated when an operation of the brake manipulator is released the brake manipulated variable is determined after the vehicular velocity is zero and the brake manipulator is operated, and the predetermined criterion is updated on the basis of the learning value.

Abstract: A method/system for controlling downshifting in an automated mechanical transmission system (10) utilized on a vehicle having a manually controlled engine brake (46) and foot brake (44) system. The engine speed at which downshifts are commanded (ESD/S) is modified as a function of sensed operation of the engine brake (EB?) and foot brake (FB) systems.

Abstract: An engine automatic speed control apparatus which exhibits a smooth transition from brake release to an engine drive state. An ECU determines braking force such that a vehicle does not move in correspondence with the slope of a road surface according to a road surface slope sensor while monitoring an operated quantity of a brake pedal according to a brake pedal operated-quantity sensor. The ECU stops an engine when braking force is applied via the brake pedal such that the vehicle does not move. After stopping the engine, the ECU determines braking force such that the vehicle does not move in correspondence with slope of the road surface according to the road surface slope sensor, and restarts the engine when braking force becomes less than braking force required to maintain the vehicle in a stopped state. The ECU then restarts the engine in the interval from relaxing of braking force via the brake pedal until the brake pedal is released.

Abstract: The invention relates to a method for controlling an internal combustion engine of a motor vehicle having an auxiliary force brake device wherein the auxiliary force is generated by coupling the brake actuation to the manifold pressure of the engine. In the method, the engine is operated with increased manifold pressure during the warm-up phase after a cold start. In the method, an actuation of the brake effects limiting the manifold pressure to a maximum value by intervening in the engine control. This maximum value is less than the value which would otherwise adjust under the same conditions without brake actuation.

Abstract: A circuit interfaces the brake, the drivetrain, and an accessory driven from the engine through a power take-off with the engine control so as to disallow application of the brake from discontinuing running of the engine at running speed set by the throttle control input whenever there is concurrence of a first input selecting placement of the accessory device in driven relationship to the power shaft, of a second input distinguishing that the transmission is in non-neutral position, and of a third input indicating vehicle speed is below a certain limit. The circuit allows a driver of the vehicle to apply the brake and operate the accessory without interrupting the set running speed of the engine so long the vehicle speed is below the certain limit.

Abstract: An apparatus for controlling brake force of a vehicle is disclosed. Each cylinders of a vehicle engine has a combustion chamber that receives fuel from a fuel injector and air from an air intake passage. The engine selectively performs a stratified charge combustion and a uniform charge combustion. The stratified charge combustion mode is selected to increase the amount of the air and the fuel supplied to the engine and improve a combusting state of the engine. The apparatus further includes a brake booster for increasing the brake force according to the negative pressure applied thereto. The brake booster is actuated by the negative pressure an amount of which is greater than a predetermined amount. Airflow in the air intake passage is restricted to generate the negative pressure. A fuel injector directly injects the fuel into the cylinder to set the engine to perform the stratified charge combustion.

Abstract: An engine control apparatus for a hybrid vehicle reduces a shock and improves the fuel consumption rate when an engine is under a fuel cut control at the time of reducing a speed through an operation of a brake pedal. In case that all conditions are fulfilled, that is, the fuel cut control, the speed reduction of not less than a predetermined level, and the non-full charge state of a battery, the program locks an intake valve and an exhaust valve in full open position and carries out a regenerative control with a generator 14. This procedure enables a cylinder to be connected with an intake air conduit and an exhaust conduit via the passages of the intake valve and the exhaust valve, thereby preventing compression of a gas in the cylinder and effectively reducing friction.

Abstract: A method of controlling the idle speed of an internal combustion engine of a vehicle from a first idle speed to a second idle speed that is higher than the first idle speed in response to a driver originating indication that is independent of the acceleration control of the vehicle. The higher second idle speed is set to achieve a desired level of vehicle creep. When the driver originating indication indicates that vehicle motion is no longer desired, the engine idle speed is returned to the first lower idle speed. The change between the first lower idle speed and the second higher idle speed can be accomplished in a stepping or ramping fashion. In addition, the first and second idle speeds are adjusted in response to changes in engine operating parameters such as engine coolant temperature, changes in engine load, and vehicle speed.

Abstract: A system and method for increasing engine idle during operation of an anti-lock brake system includes car-speed sensing means, in which the state of an electronic signal, outputted according to a driving speed of an automobile, is changed; engine revolution sensing section means, which varies the state of an electronic signal outputted according to the engine's revolutions; operation control means, which, when the ABS operation is realized, outputs a control signal for increasing the revolutions of the engine so that it matches the speed the automobile is travelling; a solenoid valve, which controls the state of pressure applied to change the operational degree of the acceleration pedal; switching means, which, according the state of the signal applied from the operation control means, controls the operational state of the solenoid valve; a vacuum pump, which is linked with the operation of the alternator and creates pressure, and, according to an opening state of the solenoid valve, supplies pressure; and an

Abstract: A simple operator presence override circuit is connected between available terminals on a PTO switch and a brake switch, and to the seat relay of the operator presence system. The override circuit permits continued operation of the engine under certain restricted conditions when the operator leaves the vehicle seat. A blocking diode connects one side of the seat relay to ground via the brake switch and one set of terminals on the PTO switch. With the PTO switch in the off condition and the vehicle braking system activated so the brake switch is closed, the seat relay remains activated to prevent operation of the ignition grounding circuit that otherwise would shut the engine down when the operator leaves his seat. Switching the PTO switch on or deactivating the braking system without an operator on the seat will automatically open the seat relay so that the engine is killed.

Abstract: A preferred embodiment of the present invention includes a power take off ("PTO") controller used on a vehicle. The controller includes a PTO on/off switch, a brake/clutch ignore switch, and a PTO set/resume switch connected to an electronic controller. The controller sets the engine speed command to a PTO default speed in response to the PTO on/off switch being in an on position. By placing the brake/clutch ignore switch in an ignore position, the vehicle operator can use the brake or clutch without affecting the PTO engine speed.

Abstract: In a utility vehicle operable in either a runabout or continuous mode, a foot operated accelerator pedal switch activates a main relay to start the engine and to maintain the engine running as long as the pedal is depressed with a key switch in the run position. When the pedal is released with the vehicle operating in the runabout mode, the main relay is deactivated and the engine is killed. Depressing the pedal activates the main relay to start the engine and maintain the engine running. The key switch is connected to latching relay structure and has a neutral run latch position. The latching relay structure is operably connected to the key switch and to a parking brake switch. The neutral run switch position and the latching structure permit continuous running of the engine as long as the parking brake is engaged.

Abstract: The switchover is mode from a regenerative braking-preference mode in which the braking force for follower and driving wheels are more than a theoretical braking force distribution characteristic for follower and driving wheels, to a usual mode in which a braking force distribution characteristic thereof corresponds to the theoretical braking force distribution characteristic, is carried along an equal braking force line which is the sum of the braking forces for the follower and driving wheels. Thus, the sum total of the braking forces over the entire vehicle is kept constant even if the distribution of the braking forces for the follower and driving wheels is varied and therefore, a smooth braking is possible without a degradation of the steering stability. In addition, the switchover in mode from the regenerative-preference mode to the usual mode is carried out when the time-differentiation value of a wheel speed of the follower wheel or the driving wheel exceeds a predetermined value.