A hybrid system includes a transmission control module, a power source, a transmission, and a drive train. The transmission control module partially operates the hybrid system and receives operating information from various components of the system, calculates power losses in the drive train, and calculates the driving torque needed to reach a target power profile determined from a driver's input.

A method and system are provided for shifting a vehicle transmission having several members. Each member is a first, second, or third node of a planetary gear set (of multiple planetary gear sets), or an input, output, or stationary member. A first torque transmitting mechanism is applied to transfer torque between first and second members in a low gear state. In some versions, a second torque transmitting mechanism is applied in the low gear state without substantially transferring torque between third and fourth members, and then the second torque transmitting mechanism is disengaged. A third torque transmitting mechanism is then applied without substantially transferring torque between the third and fourth members in the low gear state. The transmission is upshifted by disengaging the first torque transmitting mechanism, keeping the third torque transmitting mechanism applied, and applying the second torque transmitting mechanism to transfer torque between the third and fourth members.

A control device for a continuously variable transmission includes first, second, and third controllers. The first controller controls, in response to a first speed control request for controlling a traveling speed of a vehicle for a predetermined state, a gear ratio of the continuously variable transmission such that a rotational speed of a drive power source approaches a set rotational speed. The second controller controls, in response to a second speed control request issued while the first controller is controlling the gear ratio, the gear ratio based on the rotational speed and the gear ratio. The third controller changes, when the rotational speed changes as a result of the second controller controlling the gear ratio, torque of the drive power source based on torque and the rotational speed of the drive power source before the gear ratio is changed and a target rotational speed of the drive power source.

A vehicle powertrain includes an engine and a transmission, each controlled by controllers that communicate with one another. When the vehicle is coasting in certain gears, a one-way clutch over-runs. When the driver depresses the accelerator pedal (tips in), the transmission controller adjusts a transmission torque demand limit which is communicated to the engine controller. In response, the engine controller adjusts the engine torque, resulting in a smooth re-engagement of the one-way clutch.

A machine may include an engine, a traction device, a continuously variable transmission (CVT) connecting the engine to the traction device, an operator input device outputting engine output command signals input by an operator, an engine speed sensor monitoring an engine output speed, and an electronic control module (ECM). The ECM controls a machine output of the machine by executing a transmission output control routine using transmission output parameters as feedback when transmission output parameter sensor signals are reliable. The ECM controls the machine output by executing a target engine speed control routine using an engine output speed sensor signals as feedback when the transmission output parameter sensor signals are nor reliable. In the target engine speed control routine, the ECM determines a CVT transmission ratio that will cause the CVT to apply a load to the engine that will cause the engine to run at the target engine speed.

A drive unit for a hybrid vehicle capable of improvement of fuel efficiency during HV running is provided. The drive unit includes an engine, a first motor, a second motor, a first planetary gear unit, a second planetary gear unit, a first engagement unit, and a second engagement unit. In a case where an operation state of the vehicle is high vehicle speed and a low driving force in which a requested driving force is small, by bringing the first engagement unit to an engaged state and the second engagement unit to the disengaged state, a first state where a gear ratio which is a rotation number ratio between an input element and an output element of a complex planetary gear unit becomes a first gear ratio ?2 smaller than 1 is set. In the case of a low vehicle speed and a high driving force in which the requested driving force is large, by bringing the second engagement unit to the engaged state and the first engagement unit to the disengaged state, a second state where the gear ratio becomes a second gear ratio ?1 larger than 1 is set.

A method for controlling an internal combustion engine system so as to avoid turbo surge and/or shorten power cut off during gearshift is provided. The internal combustion engine system includes: an internal combustion engine and a gearbox operatively connected to the internal combustion engine; a turbocharging arrangement configured to provide a boost pressure of air fed to the internal combustion engine; and a control system configured to control operation of the internal combustion engine system, the method comprising: providing information about a point of time for initiating an upcoming gearshift, a target engine speed after the upcoming gearshift, iii) a target engine torque after the upcoming gearshift, and current operation conditions of the internal combustion engine system; determining, based on said information and before the upcoming gearshift is initiated, whether there is a risk of having turbo surge during the upcoming gearshift; and, if such a risk is determined, lowering the boost pressure before initiating the upcoming gearshift.

A technique is directed to methods and systems for detecting the presence of a machine operator. In some implementations, an operator presence system monitors a machine to determine whether an operator is present in an operating machine. The operator presence system collects input data from sensors or devices on the machine and determines whether the operator is in the operator seat. During operation, if an operator is determined to not be in the operator seat, the operator presence system can generate and send notifications (e.g., visual or audible warnings) to alert the operator to sit in the operator seat.

Rolling launch control techniques for a vehicle involve a set of devices configured to obtain rolling launch control information including at least a start speed for a rolling drag race including the vehicle and a controller configured to control a powertrain of the vehicle such that the vehicle maintains the start speed until the start of the rolling drag race, receive a first driver input in preparation for the rolling drag race, the first driver input including at least a fully-depressed accelerator pedal, optimally adjust settings of at least one of the powertrain and a driveline of the vehicle based on the rolling launch control information, and in response to a start signal or indication for the rolling drag race, stop maintaining the vehicle start speed and launch the vehicle with the fully-depressed accelerator pedal and the optimized powertrain/driveline settings.

A method for operating a drive train of a motor vehicle, where the drive train includes a drive aggregate, a group transmission connected between the drive aggregate and a drive output, and a separating cutch connected between the drive aggregate and the group transmission. If a speed is lower than a limit value, the separating clutch is opened and for transmission preselection one or all the other sub-transmission(s) is/are changed to a friction-force-locking condition. The separating clutch is then at least partially closed and the drive aggregate is brought to a defined rotation speed. When a friction-force-locking group transmission is required, it is checked whether a starting gearshift or a driver-desired shift for the group transmission is called for and the target rotation speed of the drive aggregate is checked. Depending on the results, the sub-transmission can be synchronized by a transmission brake or by the drive aggregate.