A vehicular awakening detection device 10 includes pressure sensors 48 provided in a + side paddle shift 46R and/or a − side paddle shift 46L which is able to be operated by a driver in a vehicle. The pressure sensor 48 is used for determining the degrees of awakening of a driver by making the driver to operate the + side paddle shift 46R and/or the − side paddle shift 46L.

In a rough terrain vehicle, at a time of preparing to start movement, in a case that a left paddle switch and a right paddle switch are operated together with an accelerator pedal, an ECU disengages a clutch of an automatic transmission, and causes an output of an engine to increase. On the other hand, at a time of starting movement, in a case that the left paddle switch and the right paddle switch are returned to their initial positions, the ECU engages the clutch and transmits the output of the engine from the engine to vehicle wheels via the automatic transmission, to thereby rapidly start movement of the rough terrain vehicle.

A method to control a road vehicle for the execution of a multiple downshift in a drivetrain provided with a servo-assisted transmission; the control method comprises the steps of: detecting a condition of slowing down of the road vehicle and, simultaneously, detecting a driver's request for a multiple downshift; carrying out, in succession, a plurality of downshifts while the road vehicle is slowing down and in an autonomous manner regardless of further interventions of the driver; determining a duration of a shift time interval; and carrying out each downshift following a first downshift when said shift time interval has exactly elapsed since the previous downshift.

A steering column assembly includes a jacket assembly, a modular shift assembly, and a mounting bracket. The jacket assembly extends along a first axis. The modular shift assembly includes a shift bracket and a shift gate. The shift bracket is connected to the jacket assembly and defines a shift bracket opening. The shift gate is disposed on the shift bracket. The bracket defines a shift gate opening as well as first and second detents that extend from the shift gate opening. The mounting bracket is disposed on the shift bracket and has a tab that overlaps a portion of the shift gate.

A method to control the execution of a shift to a lower gear with a released accelerator pedal in a drivetrain provided with a dual-clutch, servo-assisted transmission; the following steps are provided: opening, in a first instant, an outgoing clutch; closing, in the first instant, an incoming clutch; completing the opening of the outgoing clutch with a first linear ramp in a second instant; synchronizing, between the second instant and a third instant, a rotation speed of the internal combustion engine with a rotation speed of the incoming clutch; closing of the incoming clutch with a second linear ramp starting from a fourth instant, which is prior to or coincides with the second instant; completing the closing of the incoming clutch in a fifth instant, which coincides with or is subsequent to the second instant; and activating the internal combustion engine so as to generate a torque between the fourth instant and the third instant.

The invention relates to a gearbox system for a vehicle having: an automated manual gearbox; a gearbox control device designed to control the automated manual gearbox; a monostable toggle switch which can be operated by a user, in particular a driver, and is movable in at least, in particular exactly, two deflection directions and by means of which a plurality of driving ranges of the gearbox control device can be selected by the user; and a visual device which displays or can display graphically a gearshift diagram with driving ranges selectable by the toggle switch. The gearbox control device has a further driving range which cannot be selected by means of the toggle switch but can be exited by moving the toggle switch in at least one of the two deflection directions. The visual device has at least one display designed to display a symbol which indicates the at least one deflection direction of the toggle switch by means of which the further driving range can be exited. The gearbox control device is also designed to control the at least one display such that the symbol is only displayed when the further driving range is selected.

A gearbox system for a vehicle includes an automated manual gearbox; a gearbox control device which controls the gearbox; a monostable toggle switch which is movable by a user in two deflection directions to select a plurality of driving ranges of the gearbox control device, and a visual device which displays graphically a gearshift diagram with driving ranges selectable by the monostable toggle switch. The gearbox control device has a further driving range which cannot be selected by the monostable toggle switch but can be exited by moving the monostable toggle switch. The visual device has at least one display to display a symbol indicating at least one deflection direction by which the further driving range can be exited. The gearbox control device may control the at least one display such that the symbol is only displayed when the further driving range is selected.

A paddle switch system comprises a housing, a paddle having a pivot member pivotally disposed in the housing for operating an electrical switch within the housing in response to a force on the paddle, a cover coupled to the housing wherein the housing and the cover partially enclose the paddle, and a vibration reduction mechanism disposed in the housing proximate the pivot member of the paddle. The electrical switch comprises a dome switch and the paddle is disposed in the housing to partially preload the dome switch.

A motor vehicle has a control element for selecting a vehicle operating mode from a plurality of defined vehicle operating modes. Furthermore, the motor vehicle has at least one drive motor and an electronically controllable, automated transmission, which is operable in at least one automatic program and in at least one manual program. The motor vehicle also has an electric control arrangement and at least one button for triggering a changeover from an automatic program to a manual program. The electronic control arrangement is configured such that, upon activation of the button for triggering a manual program for a predefined minimum duration by the driver, an operating mode, which is not selectable via the control element based on dynamics, independent of the activation of the control element, is automatically activatable and displayable on the display instead of a selectable operating mode.

A manual mode training system for a vehicle having a manual transmission or a “manual mode” transmission controlled by a paddle shifter. The system includes a sensor to obtain force and position information from a foot pedal of the vehicle, and a processor to receive the information. Based on the information, the processor may predict an intended vehicle response, determine an appropriate gear to achieve the intended vehicle response, and notify a driver, through a haptic feedback mechanism, how to shift the transmission of the vehicle to reach the appropriate gear. A corresponding method is also disclosed and claimed herein.