This transmission device includes a mode changeover switch (59) on which a mode changeover operation between a manual mode (M2) and an automated mode (M1) is externally performed, other operation unit (80) on which a predetermined shift operation is externally performed separately from the mode changeover switch (59), and a control unit (60) configured to control a mode changeover between the manual mode (M2) and the automated mode (M1). The control unit (60) executes the mode changeover between the manual mode (M2) and the automated mode (M1) on the basis of the mode changeover operation on the mode changeover switch (59). When the shift operation on the other operation unit (80) has been performed, the control unit (60) executes the mode changeover between the manual mode (M2) and the automated mode (M1).

A clutch arrangement having a first coupler mounted for rotation with a first input gear, a second coupler mounted for rotation with a second input gear, and an input-gear selector mounted for rotation with an input shaft and positioned between the first and second couplers. The input-gear selector is movable on the input shaft relative to the first and second couplers. Engagement of the input-gear selector with the first coupler drives rotation of the first input gear with rotation of the input shaft, and engagement of the input-gear selector with the second coupler drives rotation of the second input gear with rotation of the input shaft.

A clutch arrangement having a first coupler mounted for rotation with a first input gear, a second coupler mounted for rotation with a second input gear, and an input-gear selector mounted for rotation with an input shaft and positioned between the first and second couplers. The input-gear selector is movable on the input shaft relative to the first and second couplers. Engagement of the input-gear selector with the first coupler drives rotation of the first input gear with rotation of the input shaft, and engagement of the input-gear selector with the second coupler drives rotation of the second input gear with rotation of the input shaft.

A shift gate assembly that can include a shift plate, a gate seal and a shift lever. The shift plate can include a lever opening having an opening centerline. The gate seal can be made of an elastic material and connected to the shift plate and extend along the lever opening. The gate seal can include a slit extending along the lever opening and offset with respect to the opening centerline. The shift lever can extend through the lever opening and the slit, be selectively movable along the lever opening and the slit, and elastically deform the gate seal as the shift lever moves along the slit.

A transmission includes an input shaft and an output shaft, the input shaft selectively accepting a torque input from a prime mover, and the output shaft selectively providing torque output to a driveline. A controller determines a shaft displacement angle representing an angle value of rotational displacement difference between at least two shafts of the transmission, and performs a transmission operation responsive to the shaft displacement angle.

A shift lever assembly includes a shift lever, a folding device, and a fold interlock device. The shift lever is adapted to move between park and gear positions. The shift lever includes a base structure and an arm pivotally engaged to the base structure about a first axis. The folding device is adapted to pivotally move the arm with respect to the base structure about the first axis and between deployed and stowed states. The fold interlock device is adapted to move between locked and released positions, and includes a locking member adapted to abut the arm in a circumferential direction with respect to the first axis when in the locked position to prevent movement from the deployed state to the stowed state, and to circumferentially clear the arm when in the released position to enable actuation of the folding device from the deployed state to the stowed state.

A shift lever assembly includes a shift lever, a folding device, and a fold interlock device. The shift lever is adapted to move between park and gear positions. The shift lever includes a base structure and an arm pivotally engaged to the base structure about a first axis. The folding device is adapted to pivotally move the arm with respect to the base structure about the first axis and between deployed and stowed states. The fold interlock device is adapted to move between locked and released positions, and includes a locking member adapted to abut the arm in a circumferential direction with respect to the first axis when in the locked position to prevent movement from the deployed state to the stowed state, and to circumferentially clear the arm when in the released position to enable actuation of the folding device from the deployed state to the stowed state.

In a shift device, as a result of a rotor cam being rotated in a positive direction, and transmitting surfaces of the rotor cam pressing rotation surfaces of an urging cylinder, the urging cylinder is rotated in the positive direction, and a lever is moved rotationally towards a front side. Here, in a case in which a load towards the rear side is applied to the lever, the rotation surfaces are rotated in an opposite direction relative to the transmitting surfaces. As a result, the load towards the rear side being applied to the lever can be released.

Some embodiments relate to a method for setting a cruising mode of a vehicle, wherein a human/machine interface is arranged on a steering wheel of the vehicle for shifting a transmission of the vehicle, this human/machine interface comprising at least one first and at least one second switch segment and at least one switch, wherein the switch segments are arranged on the at least one switch, and in the event that the at least one first and the at least one second switch segment of the at least one switch are activated at the same time the cruising mode is set for the vehicle.

A monitoring method and device for determination of a gear-stick position, a vehicle control unit, and a vehicle. The monitoring method for determination of a gear-stick position includes: acquiring a first actual gear-stick position and a first acceptable gear-stick position calculated by a functional layer; calculating a second actual gear-stick position according to a gear-stick position signal; determining whether the first actual gear-stick position and the second actual gear-stick position are consistent; in case that the first actual gear-stick position and the second actual gear-stick position are consistent, determining whether the first acceptable gear-stick position is valid; and in case that the first actual gear-stick position and the second actual gear-stick position are inconsistent or the first acceptable gear-stick position is invalid, controlling the vehicle to enter a safe state. The present application can ensure safe driving of a vehicle.