Abstract: A shift controller for a vehicle includes a shift switching unit, a rotation restricting element, and an electronic control unit. The electronic control unit is configured to: acquire a count value corresponding to a degree of rotation of an actuator; set a rotational position of the actuator when the count value does not change by restricting rotation of the actuator using the rotation restricting element as a reference position of the actuator corresponding to the predetermined shift position; and interrupt setting the reference position of the actuator and restart setting the reference position of the actuator when the rotation of the actuator is restricted and a supply voltage to the actuator is equal to or lower than a predetermined first voltage determination value or a variation in the count value while the rotation of the actuator is restricted is equal to or greater than a predetermined value.

Abstract: A hydraulic control system includes a first oil passage, a first oil pump, a second oil passage, a second oil pump and a check valve. The first oil pump is disposed in the first oil passage. The second oil passage bypasses the first oil pump, includes an intake oil passage and a discharge oil passage, the intake oil passage and the first oil passage are connected to each other at a connection point, and the discharge oil passage includes an air vent hole. The second oil pump is disposed in the second oil passage, configured to take in oil from the intake passage, and configured to discharge the oil into the discharge oil passage. The check valve is provided between the connection point and the air vent hole, configured to restrict flow of the oil from the air vent hole toward the connection point via the second oil pump.

Abstract: A control device of a vehicle drive device including an electromagnetic valve oil pump sucking and discharging hydraulic oil through ON/OFF operations of an electromagnetic valve, a drive frequency controller for controlling a drive frequency at which the electromagnetic valve is to be turned on/off, a temperature sensor for detecting an oil temperature of the hydraulic oil, and a hydraulic circuit supplied with the hydraulic oil discharged from the electromagnetic valve oil pump, the control device of a vehicle drive device further including a surge absorption circuit absorbing a counter electromotive force generated in the electromagnetic valve oil pump, the drive frequency of operation of the electromagnetic valve oil pump being set lower when the oil temperature is low than when the oil temperature is high.

Abstract: A hydraulic control system includes a first oil passage, a first oil pump, a second oil passage, a second oil pump and a check valve. The first oil pump is disposed in the first oil passage. The second oil passage bypasses the first oil pump, includes an intake oil passage and a discharge oil passage, the intake oil passage and the first oil passage are connected to each other at a connection point, and the discharge oil passage includes an air vent hole. The second oil pump is disposed in the second oil passage, configured to take in oil from the intake passage, and configured to discharge the oil into the discharge oil passage. The check valve is provided between the connection point and the air vent hole, configured to restrict flow of the oil from the air vent hole toward the connection point via the second oil pump.

Abstract: A control apparatus for a shift-position changing mechanism that changes the shift positions of an automatic transmission mounted in a vehicle using a rotational force of an actuator based on a signal corresponding to the state of an operation member, including: a mechanism that generates a rotational force for moving the actuator toward a rotation stop positional-range corresponding to the shift position, based on a rotation stop position of the actuator; a detection unit that detects a rotation amount of the actuator; a control unit that controls the actuator based on the signal and the detected rotation amount; and a learning unit that learns the rotation stop positional-range corresponding to the shift position, based on an amount by which the actuator has been rotated since a control over the actuator executed by the control unit is stopped.

Abstract: An ECU executes a program that includes the steps of i) calculating a sporty running counting SC based on a state of a vehicle according to an operation of a driver; ii) changing a condition for executing sporty running in which an upshift is inhibited when an accelerator is suddenly released and in which a downshift is promoted during sudden braking such that the condition is easier to satisfy and changing a condition for returning from sporty running so that it is more difficult to satisfy when the sporty running count SC is equal to or greater than a threshold value; and iii) changing the condition for executing sporty running so that it is more difficult to satisfy and changing the condition for returning from sporty running so that it is easier to satisfy when the sporty running count SC is not equal to or greater than the threshold value.

Abstract: A control apparatus of an internal combustion engine includes an idle torque calculating portion, a target torque setting portion, and a target throttle opening amount calculating portion. The idle torque calculating portion and the target throttle opening amount calculating portion calculate the idle torque and the target throttle opening amount when the internal combustion engine is in a non-idling state, respectively, using a common physical quantity relating to an operating state of the internal combustion engine.

Abstract: A control apparatus of an internal combustion engine includes an idle torque calculating portion, a target torque setting portion, and a target throttle opening amount calculating portion. The idle torque calculating portion and the target throttle opening amount calculating portion calculate the idle torque and the target throttle opening amount when the internal combustion engine is in a non-idling state, respectively, using a common physical quantity relating to an operating state of the internal combustion engine.

Abstract: An ECU executes a program including the steps of: detecting engine speed NE based on a signal transmitted from an engine speed sensor; calculating engine speed NE with dead time of the engine with respect to a target output torque removed; calculating engine speed NE reflecting the dead time of the engine with respect to the target output torque; correcting the actual engine speed NE in accordance with a difference between the engine speed with dead time removed and the engine speed reflecting the dead time; and setting the target value of output torque in accordance with the corrected engine speed NE.

Abstract: An ECU executes a program including the steps of: detecting engine speed NE based on a signal transmitted from an engine speed sensor; calculating engine speed NE with dead time of the engine with respect to a target output torque removed; calculating engine speed NE reflecting the dead time of the engine with respect to the target output torque; correcting the actual engine speed NE in accordance with a difference between the engine speed with dead time removed and the engine speed reflecting the dead time; and setting the target value of output torque in accordance with the corrected engine speed NE.

Abstract: A control apparatus for a shift-position changing mechanism that changes the shift positions of an automatic transmission mounted in a vehicle using a rotational force of an actuator based on a signal corresponding to the state of an operation member, including: a mechanism that generates a rotational force for moving the actuator toward a rotation stop positional-range corresponding to the shift position, based on a rotation stop position of the actuator; a detection unit that detects a rotation amount of the actuator; a control unit that controls the actuator based on the signal and the detected rotation amount; and a learning unit that learns the rotation stop positional-range corresponding to the shift position, based on an amount by which the actuator has been rotated since a control over the actuator executed by the control unit is stopped.

Abstract: An ECU executes a program that includes the steps of i) calculating a sporty running counting SC based on a state of a vehicle according to an operation of a driver; ii) changing a condition for executing sporty running in which an upshift is inhibited when an accelerator is suddenly released and in which a downshift is promoted during sudden braking such that the condition is easier to satisfy and changing a condition for returning from sporty running so that it is more difficult to satisfy when the sporty running count SC is equal to or greater than a threshold value; and iii) changing the condition for executing sporty running so that it is more difficult to satisfy and changing the condition for returning from sporty running so that it is easier to satisfy when the sporty running count SC is not equal to or greater than the threshold value.

Abstract: When determining whether to perform one shift, from among a downshift and an upshift to an adjacent gear speed from a predetermined gear speed after the other shift from among a downshift and an upshift was performed, a shift line switching portion switches a shift line from a shift line that is based on the speed ratio of the predetermined gear speed to a shift line that is based on the speed ratio after the one shift. Accordingly, a shift determining portion determines whether to perform the one shift using the shift line that is based on the speed ratio after the one shift, and that shift is executed.

Abstract: A braking-force distribution control process controls the front and rear wheel braking-force distribution in a vehicle by regulating the braking liquid pressure ratio for front and rear wheel brakes, based on differences between front wheel speeds and rear wheel speeds. When an abrupt turning state is determined, the braking liquid pressure distribution ratio for the rear brakes is decreased as compared with when the abrupt turning state is not detected. Thus, when braking during a sudden turning of the vehicle, a sudden increase in yaw rate can be inhibited to enhance the steerage stability performance of the vehicle.

Abstract: The over-steering inhibiting control-continued state is clocked by a clocking device with a counting value per one run determined depending upon the control mode established by a control mode switching-over device. When the counting value reaches a preset time of the clocking device, even during continuation of the over-steering inhibiting control operation, the over-steering inhibiting control operation is forcibly discontinued by a control discontinuation determining device.

Abstract: A braking force control system in a vehicle includes rotational speed sensors for detecting rotational speeds of front wheels and rear wheels, respectively, and braking force regulating devices capable of individually regulating braking forces for the front and rear wheels. In the braking force control system, the following two controls (1) and (2) are carried out: a front/rear braking force distribution control (1) for controlling the distribution of braking forces to front and rear wheel sides, such that a difference between front and rear wheel speeds is equalized to a target value; and an antilock brake control (2) for determining wheel locking tendencies individually in the front wheel side and the rear wheel side and controlling the braking force for the wheel determined to be in the locking tendency.

Abstract: A road surface condition-detecting system for a vehicle detects a road surface condition from road noise generated by a vehicle wheel. The road surface condition is determined based on parameter data of frequency components of the road noise, by a neural network. The road noise may be corrected by eliminating therefrom a disturbance, such as audio output and exhaust noise. A present state of the road surface condition may be determined based on at least two consecutive determinations made based on the road noise detected at regular time intervals. Exclusive neural networks may be used for respective road surface condition types. One of a plurality of neural networks provided for respective vehicle speed ranges may be selected according to an actual vehicle speed.