A joystick control device including a base and a teeter board supported on the base by at least first and second pivoting mounts, with each pivoting mount guiding relative rotary motion between the base and the teeter board about a respective axis of rotation, and the respective axes of rotation of the first and second pivoting mounts are spaced apart and extend parallel to each other. A handle effects movement of the teeter board, which movement is detected by a sensor arranged to generate an output signal indicative of the position and orientation of the teeter board relative to the base. Third and fourth pivoting mounts having respective axes of rotation perpendicular to those of the first and second pivoting mounts are suitably also provided to enable the device to provide two-axis control.

Provided is a control stick capable of measuring rotation angles thereof and automatically returning to an original point after the rotational movements. The control stick includes a rotating rod rotated in a yawing direction and a pitching direction, a first spring which returns the rotating rod to an original point when the rotating rod rotates in the yawing direction, a first rotation angle measurement portion which measures a rotation angle of the rotating rod in the yawing direction and transmits the measured rotation angle to a controller of the motion simulator, a second spring which returns the rotating rod to an original point when the rotating rod rotates in the pitching direction, and a second rotation angle measurement portion which measures a rotation angle of the rotating rod in the pitching direction and transmits the measured rotation angle to the controller of the motion simulator.

An input/output operation device includes an actuator detection circuit part, a drive circuit part, a drive control calculation processing part that controls the drive circuit part, and a rotation body on which the actuator is installed. The actuator includes a movable unit freely rotatable independently about two axes orthogonal to each other, a fixed unit supporting the movable unit for free rotation, and a drive part driving the movable unit with respect to the fixed unit. The detection circuit part outputs a position signal corresponding to a position of an operation part. The drive circuit part controls the drive part. The rotation body rotates about a rotation axis, in which the control calculation processing part controls the drive of the operation part through use of a coordinate system stationary with respect to a reference rotation angle of the rotation body at different rotation angles of the rotation body.

A one-handed joystick for cranes allows an operator to make all necessary motions with a single hand and arm for manipulating various components of a crane. The one-handed joystick includes a rotatable cylinder bar, a rotatable ring, an industrial joystick base, a rocker switch and at least two push button switches. Motions of the rotatable cylinder bar, the rotatable ring, the industrial base and the rocker switch are used to raise and lower the auxiliary hoist; raise and lower the telescopic boom for luffing a hoist; raise and lower the main hoist; slew the boom base in a clockwise or counterclockwise direction; and extend or retract the telescoping boom. The speed of main and auxiliary hosts may be changed with the two push button switches. A Deadman's switch may be installed on a back side of the rotatable cylinder bar.

Provided is an electromagnetic induction potentiometer adaptive for full-stroke detection, including a movable element configured to obtain an input for position change, a permanent magnet attached to the movable element, a magnetic induction sensor configured to sense positions of the permanent magnet and generate an initial potential signal, and an full-stroke adaptive output adjusting unit configured to collect the initial potential signal and adaptively adjust the initial potential signal to an actual potential signal corresponding to a full stroke of position changing of the movable element.

An active inceptor apparatus and method for operating a machine. The apparatus comprises a stick member having a grip portion, the stick member being pivotably mounted relative to a housing. It further comprises a position sensor responsive to, and for generating signals indicative of, stick member position. A force sensor is provided on the stick member responsive to, and for generating signals indicative of, force applied to the stick by a user. The apparatus also includes a control unit operable to receive the position and force signals from the position and force sensors respectively. The control unit is operable to process the signals according to a predetermined relationship to determine a value FD indicative of force applied to the stick member relative to displacement of the stick member. The control unit is also operable to generate machine control signals as a function of position signals and force signals in dependence upon the value FD, for communication to the machine.

The present disclosure relates to an input device, including: a base part, a support, a handle mounted to the support in a pivotably movable manner, a detector for detecting the position of the handle and at least one magnet pair of one first magnet associated with the handle means and a second magnet associated with the base part, wherein the first magnet and the second magnet, at least in one position of the handle, are disposed spaced apart over an air gap (d) and opposite to each other, in order to cause a haptic feedback and/or a returning action during the operation of the handle, wherein adapting means are provided for adapting the clear distance between the first magnet and the second magnet of the magnet pair by adapting the adapting means.

A remote controller comprising a shifter lever structure, a controller, and a signal emission device electrically coupled to the controller. The shifter lever structure includes a base, a press key movably connected to the base, a shifter lever arranged surrounding the press key and movably connected to the base, and a sensor coupled to the press key and the shifter lever. The sensor is configured to obtain moving state information about the press key and the shifter lever. The sensor includes at least one of an angle sensor, an angular displacement sensor, an angular velocity sensor, an angular acceleration sensor, a torque sensor, a distance sensor, a linear displacement sensor, a linear velocity sensor, a linear acceleration sensor, or a pressure sensor. The controller is configured to receive the moving state information from the sensor and emit a control signal corresponding to the information via the signal emission device.

A four-axis joystick provides the ability to control four parameters in a single input device. In one embodiment, the Z-direction of control is implemented by a telescoping joystick handle, with the X- and Y-directions of control being implemented by pivoting motions of the handle in directions radial to an axis of the joystick handle, and the theta-direction of control implemented by rotation of a portion of the handle about the handle axis. The four-axis joystick may be used as an input device for audio mixing applications with the X-, Y-, and Z-dimensions of control mapped to panning of an audio source in the left-right, forward-backward, and up-down directions respectively, and the theta-dimension mapped to volume control of low frequency effects.

A work vehicle includes a vehicle main body, a work implement attached to the vehicle main body, an operating lever configured to operate the work implement, an imparting section configured to impart force to the operating lever, an acceleration detection section configured to detect acceleration of the vehicle main body, and a control section configured to control the imparting section to automatically adjust a magnitude of the force imparted to the operating lever based on the acceleration detected by the acceleration detection section.