Aspects of the present invention relate to a method of using a transmission with multiple clutches in order to provide improved methods of traction control on a hill ascent. Embodiments provide for the use of power-shift, automatic or dual clutch gearboxes.

A vehicle launch control technique includes providing a driver interface configured to display information to and input from a driver of the vehicle and a controller in communication with the driver interface, determining a maximum available torque curve for the powertrain based on current conditions, displaying, at the driver interface, the maximum available torque curve, receiving, from the driver via the driver interface, a desired launch speed for the powertrain, receiving, from the driver via the driver interface, a desired torque curve for the powertrain, wherein the desired torque curve changes in response to changes to the desired launch speed, generating, in response to a command via the driver interface, a final desired torque curve for the powertrain, and performing launch control of the vehicle by controlling the powertrain of the vehicle according to the final desired torque curve.

An automatic transmission control device implements a downshift by disengagement of a clutch that is engaged in a gear position before the downshift. It is determined whether an engine state is in a predetermined region in which a change of an engine torque per a change of an accelerator pedal opening is smaller than that in another region, and the engine torque is within a predetermined range, and an engine rotational speed is within a predetermined range. It is determined whether an operating state is in a predetermined state of accelerator operation in which the accelerator pedal opening is larger than a predetermined value, and an accelerator pedal opening change rate has an absolute value smaller than a predetermined value. The downshift is inhibited in response to determination that the engine state is in the predetermined region and the operating state is in the predetermined state of accelerator operation.

The present disclosure relates to a method for a torque control of a hybrid vehicle, a storage medium and an electronic device. The method includes: determining a target-total-torque-change-gradient when a limitation requirement for a gradient of torque change of a DCT is received; determining a torque request of an electric motor and an actual-torque-response-change-gradient of an engine; and determining a gradient of torque change of the electric motor according to the target-total-torque-change-gradient and the actual-torque-response-change-gradient of the engine; and filtering the torque request of the electric motor according to the gradient of torque change of the electric motor. The limitation of the gradient of torque change of the DCT is considered, A problem that the actual total torque responses of the electric motor and the engine exceeds the limitation requirement of the gradient of torque change of the DCT is effectively solved, and a drivability of the whole vehicle is improved.

A vehicle automatic driving control apparatus executes an automatic traveling control by performing setting on preset automatic-driving-required drive torque as target torque, and includes a traction-control-required drive torque setting unit that sets, when a preset operating condition of a traction control is satisfied, traction-control-required drive torque as the target torque to decrease drive torque and thereby suppress a drive wheel slip, an automatic-driving-required drive torque decreasing unit that gradually decreases, based on a preset amount, the automatic-driving-required drive torque when the traction control is operated, a torque comparing unit that compares the traction-control-required drive torque with the decreased automatic-driving-required drive torque, and an automatic-driving-required drive torque setting unit that completes the traction control and performs the setting again on the decreased automatic-driving-required drive torque as the automatic-driving-required drive torque for the automatic driving control, when the traction-control-required drive torque is determined as exceeding the decreased automatic-driving-required drive torque.

A method for controlling torque intervention of a hybrid vehicle includes: during a torque phase time interval, reducing torque of an engine which is connected to a motor and generates a power transferred to a transmission by reducing an amount of air supplied to the engine in a state in which control for generating optimal combustion efficiency of the engine is maintained; increasing torque of the motor as much as the reduced torque of the engine during the torque phase time interval; and during an inertia phase time interval, reducing the increased torque of the motor by subtracting the reduced torque of the engine from an amount of torque intervention request for the transmission. The control for generating optimal combustion efficiency is obtained by controlling an ignition angle of the engine according to the amount of air supplied to the engine to maximize efficiency of the engine.

An apparatus for controlling an engine clutch of a hybrid vehicle includes an engine for providing driving power of the vehicle through combustion of a fuel, a motor for providing driving power of the vehicle by electric energy, a battery connected to the motor, and providing electric energy to the motor, an engine clutch for selectively connecting the engine and a driving shaft, and a control unit for measuring a real-time engine torque, revising a predetermined release delay time of the engine clutch according to a change rate of the real-time engine torque, and maintaining a lock-up of the engine clutch for the revised release delay time of the engine clutch when a hybrid travelling mode is switched to an electric travelling mode.

A construction machine including an internal combustion engine controlled based on a torque command, an electric motor mechanically connected to the internal combustion engine, and an electric energy storage device that supplies electric power to the electric motor, the construction machine performing work by driving a hydraulic pressure generator using the internal combustion engine and the electric motor, the construction machine including: a speed control device that controls a speed of the electric motor based on a speed command; and a torque limiter that limits the torque command relative to a torque target, wherein the torque command is limited by the torque limiter in such a manner that a rate of change with time of the torque command is limited to be equal to or less than a predetermined value.

A vehicle automatic driving control apparatus executes an automatic traveling control by performing setting on preset automatic-driving-required drive torque as target torque, and includes a traction-control-required drive torque setting unit that sets, when a preset operating condition of a traction control is satisfied, traction-control-required drive torque as the target torque to decrease drive torque and thereby suppress a drive wheel slip, an automatic-driving-required drive torque decreasing unit that gradually decreases, based on a preset amount, the automatic-driving-required drive torque when the traction control is operated, a torque comparing unit that compares the traction-control-required drive torque with the decreased automatic-driving-required drive torque, and an automatic-driving-required drive torque setting unit that completes the traction control and performs the setting again on the decreased automatic-driving-required drive torque as the automatic-driving-required drive torque for the automatic driving control, when the traction-control-required drive torque is determined as exceeding the decreased automatic-driving-required drive torque.

A vehicle and an acceleration limit control method thereof, includes obtaining a driving score of a driver, determining a driving score change amount of the driver based on traveling information measured or generated when the vehicle is driving, determining a current driving score based on the determined change amount of the driving score and the obtained driving score, and setting an acceleration limit level or changing a preset acceleration limit level based on the determined current driving score.