Provided herein is a vehicle including: an electric axle powertrain including: a continuously variable electric drivetrain comprising a motor/generator and a ball-type continuously variable planetary (CVP), a drive wheel axle operably coupled to the continuously variable electric drivetrain, and a first wheel and a second wheel coupled to the drive wheel axle; and a controller configured to control a CVP speed ratio and determine a request for torque vectoring, wherein the controller commands a change in the CVP speed ratio based on the request for torque vectoring,

Provided herein is a vehicle including: an electric axle powertrain including: a continuously variable electric drivetrain comprising a motor/generator and a ball-type continuously variable planetary (CVP), a drive wheel axle operably coupled to the continuously variable electric drivetrain, and a first wheel and a second wheel coupled to the drive wheel axle; and a controller configured to control a CVP speed ratio and determine a request for torque vectoring, wherein the controller commands a change in the CVP speed ratio based on the request for torque vectoring,

A shifting control apparatus includes an overall-speed-position shifting control portion including: a synchronous shifting control portion to implement a synchronous control of shifting actions of the vehicular automatic transmission and the step-variable transmission portion to respective target ones of the overall speed positions and the gear positions, such that a moment of generation of a command to establish the target overall speed position is delayed with respect to a moment of generation of a command to establish the target gear position, so that the shifting actions take place in synchronization with each other, irrespective of different control response times of the shifting actions; and a multiple-step shifting control portion to command the synchronous shifting control portion such that the vehicular automatic transmission performs a shift-up action from a present one of the overall speed position to the target overall speed position through at least one intermediate overall speed position intermediate.

A method is provided to control a hybrid powertrain comprising an internal combustion engine, a gearbox, a range gearbox, and two electrical machines to achieve a shift operation from a low range position to a high range position with minimal to no torque interruption and optimal brake regeneration, on the one hand, and a large torque and a lame number of gear steps are achieved on the other hand.

A method is provided to control a hybrid powertrain comprising an internal combustion engine, a gearbox, a range gearbox, and two electrical machines to achieve a shift operation from a low range position to a high range position with minimal to no torque interruption and optimal brake regeneration, on the one hand, and a large torque and a lame number of gear steps are achieved on the other hand.

A hybrid electric power-split vehicle, equipped with a continuously variable transmission coupling an electric motor/generator (EM) with a combustion engine (CE), includes systems and methods that reduce possible resonant noise and vibration during CE startup, by improved EM control, to generate compensating EM torque to counter act such possible resonant noise and vibration. The systems and methods include predetermined baseline CE operating condition (OC) cranking torque profiles stored as OC grids (SOCGs). A start profile is generated from selected cranking torque SOCGs, and also from selected historical start OCGs (HOCGs) of prior engine and/or CE starts, which include prior start noise and vibration metrics along with prior start OCs and related parameters. The start profile is calibrated using a blend factor that is generated from comparisons of SOCGs, and utilized to generate a feed-forward torque signal that adjusts EM torque to reduce the startup noise and vibration resonances.

A hybrid electric power-split vehicle, equipped with a continuously variable transmission coupling an electric motor/generator (EM) with a combustion engine (CE), includes systems and methods that reduce possible resonant noise and vibration during CE startup, by improved EM control, to generate compensating EM torque to counter act such possible resonant noise and vibration. The systems and methods include predetermined baseline CE operating condition (OC) cranking torque profiles stored as OC grids (SOCGs). A start profile is generated from selected cranking torque SOCGs, and also from selected historical start OCGs (HOCGs) of prior engine and/or CE starts, which include prior start noise and vibration metrics along with prior start OCs and related parameters. The start profile is calibrated using a blend factor that is generated from comparisons of SOCGs, and utilized to generate a feed-forward torque signal that adjusts EM torque to reduce the startup noise and vibration resonances.

A control method for a vehicle may include shifting request check step of checking whether there is request for shifting in vehicle on the basis of acceleration pedal depression extent and vehicle speed by shifting control device; target engine speed determination step of determining engine target speed on basis of the vehicle speed and gear ratio of pseudo target gear stage by target engine speed determiner when request for shifting is found to have been received as the result of the shifting request check step; and engine speed control step of controlling the engine speed to follow the target engine speed by determining the engine speed control torque on the basis of the difference between the target engine speed and the current engine speed and by applying the determined engine speed control torque to the first motor generator, after the engine target speed determination step.

A control method for a vehicle may include shifting request check step of checking whether there is request for shifting in vehicle on the basis of acceleration pedal depression extent and vehicle speed by shifting control device; target engine speed determination step of determining engine target speed on basis of the vehicle speed and gear ratio of pseudo target gear stage by target engine speed determiner when request for shifting is found to have been received as the result of the shifting request check step; and engine speed control step of controlling the engine speed to follow the target engine speed by determining the engine speed control torque on the basis of the difference between the target engine speed and the current engine speed and by applying the determined engine speed control torque to the first motor generator, after the engine target speed determination step.

A vehicle includes a drive axle, a multi-mode transmission, and a controller coupled to the multi-mode transmission. The multi-mode transmission includes a first gear set having a first planetary gear carrier and a second gear set having a second planetary gear carrier, a first motor/generator coupled to the first gear set, a second motor/generator coupled to the second gear set and selectively coupled to a connecting shaft, a brake positioned to selectively limit a rotational movement of a ring gear of the second gear set when engaged, a first clutch selectively rotationally coupling the first gear set and the second gear set to the drive axle when engaged, and a second clutch selectively rotationally coupling the second motor/generator to the connecting shaft when engaged. The controller is configured to engage the brake and the clutches to selectively reconfigure the multi-mode transmission to an intermediate shift mode of operation.