A shifter assembly selects a first mode and a second mode of a transmission for a vehicle. The shifter assembly includes a housing and a shift lever movably coupled to the housing and pivotable relative to the housing. The shift lever includes a body and a cap defining an aperture and being coupled to the body. The cap is rotatable relative to the body between a first and a second orientations. The shift lever further includes a toggle device partially received by the cap in the aperture with at least a portion of the toggle device being moveably coupled to the body between a rest and a depressed positions. The shift lever further includes an element mounted to the toggle device and rotatable with the cap between the first and the second orientations. The shift lever further includes a sensor system configured to interact with the element to detect rotation of the cap between the first and the second orientations.

Provided is a control apparatus for vehicle that enables a driver to activate and deactivate a freewheeling mode at his/her discretion. A control apparatus 1 for vehicle switches the vehicle to a freewheeling mode in which power generated by an engine 2 of the vehicle is not transmitted to drive shafts 7 of the vehicle. The control apparatus 1 for vehicle includes: a decelerator having a plurality of deceleration gear stages for changing deceleration of the vehicle; and a manipulator 10 provided on steering 11 of the vehicle and configured to allow selection of the freewheeling mode in accordance with an operation performed by a driver. The vehicle transitions to the freewheeling mode upon the freewheeling mode being selected through an operation of the manipulator 10.

An electric drive train for a military vehicle includes an electric motor, and a gearbox. The gearbox is driven by the electric motor and drives a tractive element. The gearbox includes input and output shafts, a pair of clutches, and a pair of planetary gearsets. The input shaft receives torque from the electric motor. The output shaft outputs torque to the tractive element. The first clutch is operable to engage an element of the first planetary gearset and the second clutch is operable to engage an element of the second planetary gearset. The first clutch and the second clutch are operable to engage the element of the first planetary gearset and the second planetary gearset to transition the electric drive train between a park mode, a neutral mode, a first driving mode, and a second driving mode, and to provide braking for the electric drive train.

A military vehicle includes an electric motor, a gearbox, a hydraulic system, and a control system. The gearbox is driven by the electric motor and drives a tractive element. The gearbox includes a first planetary gearset, a second planetary gearset, a first brake, and a second brake. Processing circuitry is configured to obtain one or more control inputs including a brake request or a mode selection. The processing circuitry operates the hydraulic system of the military vehicle to transition the gearbox between a park mode, a neutral mode, a first driving mode, and a second driving mode according to the mode selection. The processing circuitry operates the hydraulic system to provide variable pressurization to a chamber corresponding to one of the first brake or the second brake in order to perform the brake request while operating according to the first driving mode or the second driving mode.

Improved rotary switch systems and methods are disclosed. Such systems and methods may be used in vehicles that implement shift-by-wire transmission systems. The switch systems and methods may include programmable end-stops and/or variable tactile feedback.

A control method and system for preventing misoperation of a shift lever of a vehicle are provided. In particular, when a driver manipulates the shift lever to select an automatic transmission mode or a manual transmission mode, shifting into an unintended mode attributable to misoperation is prevented. Therefore, the control method and system improve reliability in manipulating the shift lever and provide a safe driving environment to a driver.

Improved rotary switch systems and methods are disclosed. Such systems and methods may be used in vehicles that implement shift-by-wire transmission systems. The switch systems and methods may include programmable end-stops and/or variable tactile feedback.

Provided is a control apparatus for vehicle that enables a driver to activate and deactivate a freewheeling mode at his/her discretion. A control apparatus 1 for vehicle switches the vehicle to a freewheeling mode in which power generated by an engine 2 of the vehicle is not transmitted to drive shafts 7 of the vehicle. The control apparatus 1 for vehicle includes: a decelerator having a plurality of deceleration gear stages for changing deceleration of the vehicle; and a manipulator 10 provided on steering 11 of the vehicle and configured to allow selection of the freewheeling mode in accordance with an operation performed by a driver. The vehicle transitions to the freewheeling mode upon the freewheeling mode being selected through an operation of the manipulator 10.

A mechanical creeper mode selection system for a transmission of a work vehicle is provided, in which the transmission includes one or more range modes having one or more range mode shift mechanisms each driven by an electrohydraulic circuit. The system includes a creeper mode selection lever movable by an operator to select a creeper gear range. The system also includes a sensor that observes a position of the creeper mode selection lever and generates sensor signals based thereon. The system includes a controller that processes the sensor data to determine a movement of the creeper mode selection lever and outputs one or more control signals to the electrohydraulic circuit to position the one or more range mode shift mechanisms in a range neutral mode based on the movement of the creeper mode selection lever.

A control method and system for preventing misoperation of a shift lever of a vehicle are provided. In particular, when a driver manipulates the shift lever to select an automatic transmission mode or a manual transmission mode, shifting into an unintended mode attributable to misoperation is prevented. Therefore, the control method and system improve reliability in manipulating the shift lever and provide a safe driving environment to a driver.