A traction drive system for a work machine, including at least one electric motor, a transmission, and a controller. The controller is configured to select a gear ratio of the transmission depending on a change to be expected in a motor output of the at least one electric motor. The change to be expected in the motor output is conditional on a change in the gear ratio of the transmission. The change to be expected in the motor output is determined on the basis of at least one operating parameter of the work machine.

A traction drive system for a work machine, including at least one electric motor, a transmission, and a controller. The controller is configured to select a gear ratio of the transmission depending on a change to be expected in a motor output of the at least one electric motor. The change to be expected in the motor output is conditional on a change in the gear ratio of the transmission. The change to be expected in the motor output is determined on the basis of at least one operating parameter of the work machine.

A method for controlling a transmission provided in a vehicle may include providing a reference data for automatic shift of the transmission according to a speed reference of the vehicle, collecting a detected data delivered from at least one detector or operation state information related to an in-vehicle device, wherein the at least one detector and the in-vehicle device is attached or mounted on the vehicle configured for recognizing a driving condition, determining a mode for the automatic shift based at least on the detected data or the operating state information, and performing the automatic shift according to the mode.

A rotary shifter with 360 rotation in each of clockwise and counter clockwise rotating directions. The shifter includes a package housing with a bezel cover. A cylindrical shaped plunger housing is secured to a rotary knob supported atop the housing and which is selectively rotatable in the clockwise direction from a Park gear position, in succession, to each of a Reverse gear position, a Neutral gear position and at least one Drive gear position, with further clockwise rotation preventing movement beyond a final one of the Drive gear positions. The knob is further selectively rotatable in a counter clockwise direction to return to the Park gear position, with additional permitted counter-clockwise rotation retaining the shifter in the Park gear position.

A vehicle control device is for a vehicle having a drive source, and an automatic transmission connected to the drive source, the automatic transmission having an engagement element for disconnecting/connecting transmission of a driving force and a variator placed further upstream than the engagement element. The vehicle control device includes first and second control units. The first control unit is configured to execute sailing stop control to stop the drive source and to put the automatic transmission into a neutral state when a sailing stop condition is established. The second control unit is configured to start the drive source and to implement downshifting of the variator when a size of a deceleration level is a prescribed value or greater when the sailing stop control is cancelled due to a prescribed sailing stop cancellation condition among sailing stop cancellation conditions being established, and to engage the engagement element after the downshifting.

During changing of a shift range (for example, from P-range to NotP-range), an SBW-ECU determines whether it is in a range-change delay condition (a switching completion time of the shift range is delayed than a normal switching completion time). When it is determined that it is in the range-change delay condition, it is determined whether a target range should be changed to a safer range (for example, P-range). As a result, when it is determined that the target range should be changed to the safer range, the target range is changed to the safer range. Thereby, even if a driver determines that the shift range cannot be changed before the switching completion of the shift range and the driver gets off the vehicle, the shift range can be changed to the safer range (P-range).

A vehicle includes an engine and a vehicle park mechanism. The vehicle further includes a controller configured initiate an auto-stop of the engine in response to an auto-stop condition. The controller is further configured to actuate the vehicle park mechanism in response to a driver exit condition and the engine being auto-stopped.

A vehicle drive-train with a drive engine, a drive output and a transmission device connected in the power flow between the drive engine and the drive output. The transmission device has at least two transmission units whose transmission ratios can be varied continuously, at least in some ranges, and which are arranged in power-trains running parallel with one another between the drive engine and the drive output. The power-trains can each be functionally connected with a respective axle of the drive output. At least one shifting element is provided by which the power-trains can be functionally connected in the area between the transmission units and the drivable axles. In addition, a method for operating the vehicle drive-train is described, in which the shifting element is actuated as a function of torque to be transmitted via the transmission device between the drive engine and the drive output.

A method of estimating road slope using a gravitational acceleration sensor, includes determining whether a driving mode of a vehicle is a towing or freight carrying mode, calculating a difference value between road slope measured using the gravitational acceleration sensor and road slope measured using a driving torque when the driving mode of the vehicle is the towing or freight carrying mode, estimating road slope by correcting the road slope measured using the gravitational acceleration sensor based on the difference value, and controlling a shift of the vehicle according to the estimated road slope.

A method of estimating road slope using a gravitational acceleration sensor, includes determining whether a driving mode of a vehicle is a towing or freight carrying mode, calculating a difference value between road slope measured using the gravitational acceleration sensor and road slope measured using a driving torque when the driving mode of the vehicle is the towing or freight carrying mode, estimating road slope by correcting the road slope measured using the gravitational acceleration sensor based on the difference value, and controlling a shift of the vehicle according to the estimated road slope.