A magnetic spring input device is disclosed. In various embodiments, an input device as disclosed includes a manual input structure movably coupled to a base assembly; and a non-stationary magnet fixedly coupled to the manual input structure; a stationary magnet coupled to the base assembly in a manner that is fixed with respect to at least a first input axis of the input device, the stationary magnet being coupled to the base assembly with a first magnetic pole having a first magnetic polarity is oriented opposite a corresponding magnetic pole of the non-stationary magnet having the first magnetic polarity, in a position that is adjacent to but offset from the non-stationary magnet when the manual input structure is in a neutral position. The non-stationary magnet is coupled to the manual input structure in a position such that movement of the manual input structure about or along the first input axis of the input device brings said poles have said first magnetic polarity within sufficient proximity to generate a repulsive magnetic force.

The present invention relates to a hand-held pan-tilt kit for realizing motion control with a joystick, comprising: a joystick for acquiring a user instruction; a controller connected to the joystick; wherein, the controller transmits a corresponding pan-tilt kit control signal according to the user instruction. The pan-tilt kit further comprises a first rotating means provided with a first motor, a second rotating means provided with a second motor, and a third rotating means provided with a third motor, the first electric motor, the second motor and the third motor are all electrically connected to the pan-tilt kit controller. The above hand-held pan-tilt kit for realizing motion control with a joystick is easy to operate and enables precise control of the hand-held pan-tilt kit by an external joystick.

A control device for an implement system of a machine is provided. The control device is mounted on a support. The control device includes a first gimbal rotatably coupled to the support. The control device also includes a second gimbal rotatably coupled to the first gimbal. The control device further includes a linear actuator having a first end and a second end. The linear actuator is fixed to the second gimbal from the first end. The control device further includes a handle attached to the linear actuator at the second end. The handle is configured to move in conjunction with rotational movements of the first gimbal and the second gimbal, and a linear movement of the linear actuator to control a movement of the implement system.

A rotary actuator with an operating knob which is rotatable about a rotational axis is included in an operating device of a motor vehicle. The rotary actuator generates an actuating signal during rotation of the operating knob, and the operating knob is translationally deflectable transversely with respect to the rotational axis to alternately operate two control modules using the same operating device. A coupling device couples the operating device to a first control module and to a second control module. The coupling device is configured to output the actuating signal exclusively to the first control module in a first switching position and to output the actuating signal exclusively to the second control module in a second switching position and to switch from the first switching position to the second switching position during translational deflection of the operating knob in a predetermined deflection direction.

A rotary actuator with an operating knob which is rotatable about a rotational axis is included in an operating device of a motor vehicle. The rotary actuator generates an actuating signal during rotation of the operating knob, and the operating knob is translationally deflectable transversely with respect to the rotational axis to alternately operate two control modules using the same operating device. A coupling device couples the operating device to a first control module and to a second control module. The coupling device is configured to output the actuating signal exclusively to the first control module in a first switching position and to output the actuating signal exclusively to the second control module in a second switching position and to switch from the first switching position to the second switching position during translational deflection of the operating knob in a predetermined deflection direction.

A control device for an implement system of a machine is mounted on a base. The control device includes a handle portion having a rotatable sleeve and a control rod encased in the handle portion. A seat is fixed to the control rod at a proximal end of the handle portion. Two linear actuators connected between the base and the seat form a kinematic chain including the linear actuators and the control rod.

Provided is an operation lever adapted to make a blade perform an action other than an up and down action by rotatably a grip around the shaft center of a lever shaft. The operation lever has a lever shaft operable back and forth, corresponding to an up and down action of a blade of a dozer unit, and a grip provided on an upper part of the lever shaft and capable of rotating in a clockwise direction and counterclockwise direction from a neutral position around a shaft center of the lever shaft by a predetermined rotation angle, corresponding to an angle action or a tilting action of the blade. The grip includes a return-to-neutral spring adapted to return the grip from a rotated position to a neutral position, and the rotation angle of the grip in the clockwise direction is set to be different from that in the counterclockwise direction.

Provided is a multi-operating switch unit for vehicles including: a housing part; a substrate; a switch shaft part; a rotary switch part; a directional switch part; and a push switch part. The directional switch part has: a directional slide part in which the position thereof can vary in the housing part due to a tilting directional operation of the switch shaft part; a directional switch that is arranged on the substrate and is operated due to the positional variation of the directional slide part; and a directional return part that returns the directional slide part and the switch shaft part. The directional return part has a return plunger; a return elastic part; and a return groove. The return plunger can be movable in the axial length direction of the switch shaft part with respect to the housing part, and the return groove is formed in the directional slide part.

The present application provides a rocker device. The rocker device includes a rocker, a bias component, an adjustable reset assembly, and a toggle component. The rocker is provided with a pressing part. The bias component includes a first end and a second end opposite to each other, the first end is in contact with the pressing part, and the second end is capable of offsetting. The adjustable reset assembly is disposed on the second end, and the adjustable reset assembly is configured to drive the second end of the bias component to reset. The rocker rotates in the toggle component, and the toggle component is configured to act on the adjustable reset assembly to adjust a reset force. The rocker device of the present application may adjust the operating force through the toggle component, which may meet the diverse experience needs of a user.

A stick controller for adjusting the position of an examination unit with respect to an eye to be examined in an ophthalmic eye-examining device includes an operation unit configured to be operated by a user so as to be positioned in a first driving area or a second driving area; a first magnetic coupling part coupled to the operation unit and configured to move along a first area together with the operation unit; a second magnetic coupling part detachably coupled to the first magnetic coupling part by magnetic force and configured to move along a second area; and a control signal generation unit configured to output a first drive control signal when the operation unit is positioned in the first driving area and output a second drive control signal when the operation unit is positioned in the second driving area.