A vehicle braking control system includes a vehicle brake controller configured to receive a driver assistance vehicle stopped signal from a driver assistance system feature on the vehicle. The driver assistance vehicle stopped signal indicates the vehicle has been stopped by the driver assistance system feature. The vehicle brake controller is also configured to receive a driver override signal, if a driver of the vehicle engages an interactive system of the vehicle. The vehicle brake controller is also configured to, if the driver override signal is not received within a predetermined time after receiving the driver assistance vehicle stopped signal, transmit a park brake engagement signal to engage a parking brake on the vehicle.

A hitching assistance system for a vehicle includes a steering system including a vehicle steering wheel and a controller executing an automated hitching maneuver including controlling the steering system to back the vehicle toward a trailer, monitoring the hitching assistance system for an interruption event affecting execution of the automated hitching maneuver, detecting the interruption event and identifying the interruption event as one of a standard interruption event or an exception interruption event, upon identifying the standard interruption event, causing the steering wheel to move to a centered position and ceasing control of the steering system, and upon identifying the exception interruption event, ceasing control of the steering system without causing the steering wheel to move to the centered position.

In a special operating mode, a controller is programmed to disengage a hydraulically actuated park mechanism without use of engine power. The starter motor is used to rotate the engine-driven pump at sufficient speed to command disengagement of Park. Once park is disengaged, a holding pin is used to maintain the out of park condition without hydraulic pressure or flow.

A vehicle drive device includes a control portion that is allowed to execute a control mode that controls multiple hydraulic elements to cause a vehicle in a stop state of an engine to start moving. The control mode starts controlling part of the multiple hydraulic elements before the engine is started, by using oil pressure accumulated in an accumulator (S8). The control mode starts controlling the rest of the multiple hydraulic elements by using oil pressure that is provided after the engine is started (S16).

A transmission park mechanism is hydraulically actuated. Specifically. a controller releases the parking pawl by commanding engagement of particular shift elements at an elevated line pressure. The process of transitioning from Park to a Drive or Reverse condition may involve several sequential steps. To reduce the delay between driver selection of Drive or Reverse and completion of the engagement, it is advantageous to raise the line pressure in response to depression of a brake pedal, prior to movement of the shift lever. To limit the adverse fuel economy impact of increased line pressure, the line pressure is lowered again if the driver does not move the shift lever soon after depressing the brake pedal.

A control device that controls a vehicle drive device provided with a transmission mechanism and a rotating member in a power transmission path in this order from a drive power source side, and provided with a parking lock mechanism that restricts rotation of the rotating member by allowing an engaging member to engage with the rotating member, the power transmission path connecting a drive power source to wheels.

Controls for improved performance of a vehicle equipped with start-stop control logic are disclosed. Deviation from nominal engine start-stop control logic for the internal combustion engine occurs when a predetermined mission related type of stop event will occur or is occurring that is different from other stop event types that are controlled by the nominal engine start-stop control logic. At least one of a location and a payload associated with the mission related stop event type is provided as an input to the controller before the vehicle arrives at the stop event so that operating parameters of the vehicle are controlled accordingly.

A limp-home driving method at the time of a breakdown of a parking switch for a vehicle includes a first step of diagnosing a breakdown of a plurality of air parking switches provided in a hybrid vehicle by connecting the air parking switches to a hybrid control unit (HCU) and a transmission control unit (TCU), respectively, through parking wires, and connecting the HCU and the TCU with each other by controller area network (CAN) communication, a second step of informing a driver of a breakdown state at the time of confirming the breakdown of the air parking switches in the first step, and a third step of limiting an output of the vehicle and performing a limp-home function in a state in which an ISG (Idle Stop and Go) control is stopped, after the second step.

Provided is a hydraulic pressure control device. A hydraulic pressure control device includes a solenoid valve configured to supply hydraulic pressure to switch between an engaged state and a released state of a lock-up clutch, and a transmission control device configured to control the solenoid valve. The solenoid valve supplies hydraulic pressure to switch between a parking locked state and a parking released state of a parking lock mechanism, in addition to switching of the lock-up clutch.

An ADS performs processing including setting an immobilization command to Applied when an autonomous state has been set to an autonomous mode, when an acceleration command has a value indicating deceleration, when an actual moving direction indicates a standstill state, and when a wheel lock request is issued, setting the acceleration command to V1, and setting the acceleration command to zero when an immobilization status has been set to 11.