Method for controlling a car, in particular a sports car, provided with a relative power train, relative braking devices and relative steering means, the method being based on a joystick comprising a lever, arranged in the car to identify a forward tilt and a backward tilt parallel to a longitudinal development of the car for interacting with said power train and with said braking devices, and two side tilts to the left and to the right for interacting with said steering means so as to determine a trajectory of the car, wherein the method, according to a first operating condition, comprises a first step of respectively associating said forward tilt and said backward tilt with a proportional forward and backward acceleration of the car.

A driving joystick arrangement for a construction machine comprises an operating lever and a basic housing, wherein the operating lever is pivoted in the basic housing, and the basic housing comprises a shift gate through which the operating lever extends. The operating lever comprises, at least in sections, a material which is suited and arranged in the operating lever such that a position of the operating lever relative to the basic housing can be detected by means of the Hall sensor.

A handle-type integrated control device includes: a steering lever disposed to be movable in a width direction of a vehicle by a driver's operation; a handle housing disposed at an upper end of the steering lever and configured to rotate, in a front-to-rear direction of the vehicle, about one end of the steering lever by the driver's operation; a speed value receiver disposed at one end of the handle housing to receive an acceleration or deceleration change value; and a speed controller connected to the speed value receiver to receive the acceleration or deceleration change value from the speed value receiver.

A control pod bracket assembly for an operator seat of a work machine adjusts a spacing distance between a right control pod and a left control pod. A right side bracket and a left side bracket having the control pods mounted thereon may be slidably coupled to a center bracket to move between inward and outward positions. Right side bracket and left side bracket locking mechanisms are selectively engageable to lock the side brackets at the inward or outward positions, and to unlock and allow the side brackets to move between the inward and outward positions. Adjustment of the side brackets allows the control pod spacing to be varied between a minimum control pod spacing distance and a maximum control pod spacing distance.

A construction machine that frequently changes between a forward and reverse direction of movement includes a system and method for operating the machine such that rotation of the operator seat can change the direction and speed of the machine's movement to minimize disorientation by the operator. The machine can be changed from moving in the forward direction to moving in the reverse direction, without changing the position of a propel lever or joystick that is used to control the direction and speed of the machine's movement. Rotation of the seat can be used to proportionally reduce the speed of the machine as the machine nears a threshold for changing direction. The joystick can be a dual axis lever that can move along a longitudinal axis and a lateral axis. The direction of movement and speed of the machine can depend on a combination of the joystick position and seat position.

A method for reconfiguring operator controls of a work vehicle is disclosed. The method comprises providing a user interface operatively coupled to a control device. Displaying one or more displays of an apparatus configuration on a display screen of the user interface, each of the one or more displays including graphics associated with a function of the apparatus. Associating a control output of a control unit of the control device with the function of the apparatus; and dynamically adjusting, by a controller, the control output of the control unit to reconfigure operator controls of the work vehicle in response to a change in the graphics or a change in the relative arrangement of the one or more displays on the display screen.

A memory stores a plurality of steering angle characteristics including a first steering angle characteristic and a second steering angle characteristic. A steering angle characteristic selecting unit selects a selected steering angle characteristic from the steering angle characteristics stored in the memory. A driving control unit controls the steering angle of an autonomous-driving vehicle in accordance with the selected steering angle characteristic and a rightward or leftward operation amount of a mechanical operation unit of an autonomous-driving vehicle.

A working vehicle includes an operator seat, an armrest arranged on a side of the operator seat, and a speed shifter to change a traveling speed. The armrest includes an operation lever to be swung back and forth to cause the speed shifter to perform acceleration and deceleration, and an operation switch to be pressed to cause the speed shifter to perform acceleration and deceleration.

A control system includes a joystick and a computer. The joystick includes a joystick body, a cover hingedly coupled to the joystick body and movable between an open position and a closed position, and an input located on the joystick body. The input is exposed by the cover when the cover is in the open position and concealed by the cover when the cover is in the closed position. The computer is programmed to enter a first mode in response to the cover moving from the open position to the closed position, to enter a second mode in response to both the cover moving from the closed position to the open position and the input being activated, and to remain in a same of the first and second modes in response to the cover moving from the closed position to the open position without the input being activated.

The present invention relates to flying scooter comprising a base made of fibreglass, 20 fans with 20 motors connected to a power system with components comprising capacitors, batteries, photovoltaic solar cells, an oxygen generator, a regulator, electronic sensors, and electronic chips. The scooter has a circular front part that includes a display that gives operational levels of the components, and the base has a cavity for the passenger's legs, and a rubber strap for securing the passenger. Manual controls are provided as well as a grip for the controls. The controls are connected to the sensors and electronic chips wirelessly.