A hybrid electric powertrain system includes a transmission, engine, e-accessory, primary and secondary electric machines, and controller. The e-accessory is powered by the secondary electric machine in response to an accessory torque demand. The engine and primary electric machine are connected to the transmission and configured, alone or in combination, to provide input drive torque to the transmission. The secondary electric machine is connected to the e-accessory and satisfies the accessory torque demand. A first clutch between the secondary electric machine and a transmission input member connects the secondary electric machine to the input member. The controller, in response to an output torque request, executes a power-sharing strategy using an objective cost function that allocates engine torque, primary motor torque, and secondary motor torque to the input member to satisfy the output torque request, while satisfying the accessory torque demand via the secondary electric machine.

A hybrid electric powertrain system includes a transmission, engine, e-accessory, primary and secondary electric machines, and controller. The e-accessory is powered by the secondary electric machine in response to an accessory torque demand. The engine and primary electric machine are connected to the transmission and configured, alone or in combination, to provide input drive torque to the transmission. The secondary electric machine is connected to the e-accessory and satisfies the accessory torque demand. A first clutch between the secondary electric machine and a transmission input member connects the secondary electric machine to the input member. The controller, in response to an output torque request, executes a power-sharing strategy using an objective cost function that allocates engine torque, primary motor torque, and secondary motor torque to the input member to satisfy the output torque request, while satisfying the accessory torque demand via the secondary electric machine.

Method disclosed to start a combustion engine in a hybrid powertrain comprising a gearbox with input and output shafts; a first planetary gear connected to the input shaft and a first main shaft; second planetary gear connected to the first planetary gear and a second main shaft; first and second electrical machines respectively connected to the first and second planetary gears; a first gear pair connected with the first main shaft, first planetary gear, and output shaft of the gear box; and a second gear pair connected with the second main shaft, second planetary gear and output shaft of the gear box. The method comprises: determining a desired torque in the output shaft of the gear box and a start torque in an output shaft of the combustion engine required to start the combustion engine, and controlling the first and second electrical machines to achieve both the desired and start torques.

A vehicle control device including a first driving force controller and a second driving force controller. The first driving force controller executes the first driving force control or the second driving force controller executes the second driving force control, on the basis of the speed of the vehicle, the first vehicle speed limit, and the second vehicle speed limit. The first vehicle speed limit and the second vehicle speed limit change independently of each other.

A control apparatus of a power transmission system for a vehicle includes an electronic control unit. When an input rotational speed of an input-side rotary member is lower than an output rotational speed of an output-side rotary member in a two-way clutch, and a shift request to form a shift stage in which the two-way clutch is switched to a lock mode is generated, the electronic control unit switches the two-way clutch to the lock mode, after the input rotational speed of the input-side rotary member is made substantially equal to the output rotational speed of the output-side rotary member.

A control apparatus for a vehicle drive-force transmitting apparatus which defines a first drive-force transmitting path provided with a first clutch and a two-way clutch and a second drive-force transmitting path provided with a continuously variable transmission and a second clutch. The two-way clutch transmits a drive force during a driving state of the vehicle, and cuts off transmission of the drive force during a driven state of the vehicle when the two-way clutch is in its one-way mode. The two-way clutch transmits the drive force during the driving state and during the driven state when the two-way clutch is in its lock mode. An engine torque is increased in a case in which a request for switching the two-way clutch to the one-way mode is made during the driven state in forward running of the vehicle with the two-way clutch being in the lock mode.

Disclosed is a method for control a vehicle with a drive system comprising an output shaft of a combustion engine and a planetary gear with a first and a second electrical machine, connected via their rotors to the components of the planetary gear, the vehicle is started by controlling the first electrical machine to achieve a torque thereof, so that the requested torque is transmitted to the planetary gear's output shaft, and controlling the second electrical machine to achieve a torque, so that the desired power to electrical auxiliary aggregates and/or loads in the vehicle, and/or electric energy storage means, if present in the vehicle, for exchange of electric energy with the first and second electrical machine is achieved.

A method is provided for controlling a shifting process in a powertrain of a vehicle, the powertrain having a first and a second drive machine, a transmission connecting the drive machines to a transmission output and at least one coupling which can be shifted, wherein during a shifting process an offgoing coupling is disengaged and/or an oncoming coupling is engaged.

A vehicle propulsion system includes a prime mover having a prime mover output shaft, a continuously variable transmission having a variator input shaft coupled to the prime mover output shaft and having a variator output shaft, a driver torque request module in communication with a driver input and for outputting a driver torque request, an engine backbone in communication with the prime mover, and a transmission backbone in communication with the continuously variable transmission and the engine backbone in the vehicle propulsion system. The transmission backbone includes a positive torque request module that generates a positive torque request, and a positive torque request monitor that limits a torque request from the transmission backbone to the engine backbone to a maximum of a predetermined threshold.

A controller for a motor vehicle includes means for receiving information indicative of a current vehicle speed; means for receiving information indicative of an amount of brake force a braking system is developing or is capable of developing; means for receiving information indicative of a gradient of a driving surface on which the vehicle is driving; and torque transmission reduction means for causing a powertrain torque reduction operation to be performed in which the controller causes one or more components in a torque transmission path from a torque delivery device to driven wheels to assume a torque reduction condition in which torque transmission is reduced or substantially terminated. The controller is configured automatically to cause the torque reduction operation to be performed in dependence at least in part on the information indicative of current vehicle speed, information indicative of brake force amount and information indicative of driving surface gradient.