A controller is capable of controlling an asset or target in physical and/or virtual three-dimensional space using a single hand by generating control inputs in four or more degrees of freedom while also limiting cross-coupling (unintended motions). The controller includes a first control member is configured to be gripped in a user's single, second control member is disposed on or near a top end of the first member movable with at least one degree of freedom independently of the movement of the first control member, and a third control member positioned on the first member for displacement by one or more digits of the user's single hand and coupled with the second member to move in opposition to movement of the second control member.

An operating device includes: an operating lever extending in a first direction and including a first end-side part in the first direction, the first end-side part being operable; a casing supporting a first-direction intermediate part of the operating lever; first and second sensors arranged in the casing so as to be spaced apart from each other in a second direction perpendicular to the first direction and be adjacent to a second end-side part in the first direction of the operating lever; and third and fourth sensors arranged in the casing so as to be spaced apart from each other in a third direction perpendicular to the first and second directions and be adjacent to the second end-side part of the operating lever, wherein each of the first to fourth sensors outputs a signal in accordance with a load applied from the operating lever.

A controller is capable of controlling an asset or target in physical and/or virtual three-dimensional space using a single hand by generating control inputs in four or more degrees of freedom while also limiting cross-coupling (unintended motions). The controller includes a first control member is configured to be gripped in a user's single, second control member is disposed on or near a top end of the first member movable with at least one degree of freedom independently of the movement of the first control member, and a third control member positioned on the first member for displacement by one or more digits of the user's single hand and coupled with the second member to move in opposition to movement of the second control member.

A hand controller that includes a control member mounted on a hand held base for commanding a remote vehicle or movement of a virtual object within a virtual environment includes an input device mounted for generating tilt commands for a sensor mounted on the remote vehicle or the virtual object, the input device being located on a front of the base and oriented to be displaced up and down to tilt the sensor or the virtual point of view when the base is held during operation.

A control stick includes a control portion, a first electrical contact portion and a second electrical contact portion. The control portion has plural first moving contact points, the first electrical contact portion has a control board and plural first static contact points corresponding to the first moving contact points respectively, and a gap exists between the first moving contact point and the respective first static contact point. The first static contact points are electrically connected with the control board. When the control portion swings towards one of the first moving contact points, the first moving contact point is contacted and conducted with the first static contact point. This control stick is capable of achieving the control of a multiple of variables to meet the requirements of controlling a multiple variable in some occasions.

A variable track joystick device includes a support housing, a joystick movable with respect to the support housing, and a joystick guidance mechanism controllable to selectively confine joystick movement to a predetermined track pattern. During operation of the variable joystick device, a controller determines when the variable track joystick device is placed in a selected one of (i) a first mode in which joystick movement controls the first work vehicle function and (ii) a second mode in which joystick movement controls the second work vehicle function. The controller further commands the joystick guidance mechanism to restrict joystick movement to the predetermined track pattern when the joystick device is placed in the first mode, while permitting joystick movement outside of the predetermined track pattern when the joystick device is placed in the second mode.

Embodiments are directed to a flight control stick support comprising a spherical bearing coupled to a flight control stick, a first plate having a first hole configured to receive a top portion of the spherical bearing, a second plate having a second hole configured to receive a bottom portion of the spherical bearing, and a clamping device configured to move the first plate relative to and the second plate to apply a variable force against the spherical bearing.

A control device for a human-machine interface includes a base and a moveable member in the form of a lever or a push element, which can be moved relative to the base. The control device further includes at least one electroactive element positioned between the moveable member and a fixed element of the base.

A thumbstick assembly is configured to receive user input. The thumbstick assembly receives input through depression of a thumbstick, lateral rotation of the thumbstick, or some combination thereof. The thumbstick comprises a first surface, a rod, a spherical magnet. The first surface receives contact with a user's skin. The rod comprises a first end coupled to the first surface and a second end coupled to the spherical magnet. The thumbstick assembly further comprises a cup and a ring magnet. The cup is configured to receive the spherical magnet, wherein the spherical magnet is configured to move about a pivot point within the cup. The ring magnet is positioned about an outer surface of the cup and is configured to provide a restoring torque to the movement of the spherical magnet. The thumbstick assembly comprises one or more sensors that detect movement of the thumbstick relative to the cup.

A thumbstick assembly is configured to receive user input. The thumbstick assembly receives input through depression of a thumbstick, lateral rotation of the thumbstick, or some combination thereof. The thumbstick comprises a first surface, a rod, a spherical magnet. The first surface receives contact with a user's skin. The rod comprises a first end coupled to the first surface and a second end coupled to the spherical magnet. The thumbstick assembly further comprises a cup and a ring magnet. The cup is configured to receive the spherical magnet, wherein the spherical magnet is configured to move about a pivot point within the cup. The ring magnet is positioned about an outer surface of the cup and is configured to provide a restoring torque to the movement of the spherical magnet. The thumbstick assembly comprises one or more sensors that detect movement of the thumbstick relative to the cup.