A seat adjustment switch includes a multidirectional force sensor, a carrier plate, and a button cap. The multidirectional force sensor is arranged on the carrier plate and includes a sensor pin. The sensor pin is pivotable via which the multidirectional force sensor is actuatable. The button cap is connected to the sensor pin. The button cap serves as an actuating element operable by an operator for pivoting the sensor pin in order to actuate the multidirectional force sensor. The carrier plate includes a receiving sleeve that is integrally formed with the carrier plate and is connected to other portions of the carrier plate via flexible regions, the sensor pin is guided through the receiving sleeve for the multidirectional force sensor to be arranged on the carrier plate. The button cap forms a form-fit connection with the receiving sleeve.

A joystick sensor includes a housing, a reset assembly, a rocker assembly, a circuit assembly, the reset assembly, the rocker assembly and the circuit assembly are mounted on the housing; the rocker assembly includes two magnets, an upper rocker arm, a lower rocker arm, and a rocker body, one end of the upper rocker connected with one of the two magnets; one end of the rocker arm is connected with the other one of the two magnets, the other end of the lower rocker arm is secured a pressing block; the circuit assembly includes a flexible circuit board, two Hall IC elements, and a switch spring, the two Hall IC elements and the switch spring are arranged on the flexible circuit board, positions of the Hall IC elements respective correspond to positions of the magnets; a position of the switch spring corresponds to a position of the pressing block.

An adaptive joystick preferably includes a rotatable cylinder bar, an outer base ring, an inner ring and an industrial joystick base. An adaptive controller receives an output from the adaptive joystick and outputs a control signal to a valve solenoid to control a hydraulic cylinder. Angle, depth and pressure sensors are preferably used to monitor a position of the hydraulic cylinder. The sensor outputs are fed into the adaptive controller. An inward wrist curl of the rotatable cylinder bar combined with a forearm pull rearward of the outer base ring are used to cause a digging motion. An outward wrist curl of the rotatable cylinder bar combined with a forearm push forward of the outer base ring are used to cause a dumping motion. A hand movement to the left is associated with swinging the excavator left. A hand movement to the right is associated to swinging the excavator right.

A joystick device is provided. The joystick device includes a housing, a joystick assembly, a reset assembly, a translation assembly, and a circuit board. A magnetic component is located on the translation assembly, and a magnetic induction element is located on the circuit board. The joystick assembly pushes the translation assembly to translate, and the magnetic induction element generate an output that changes with the movement of the translation assembly. A handle using the joystick device also provided.

A seat adjustment switch includes a multidirectional force sensor, a carrier plate, and a button cap. The multidirectional force sensor is arranged on the carrier plate and includes a sensor pin. The sensor pin is pivotable via which the multidirectional force sensor is actuatable. The button cap is connected to the sensor pin. The button cap serves as an actuating element operable by an operator for pivoting the sensor pin in order to actuate the multidirectional force sensor. The carrier plate includes a receiving sleeve that is integrally formed with the carrier plate and is connected to other portions of the carrier plate via flexible regions, the sensor pin is guided through the receiving sleeve for the multidirectional force sensor to be arranged on the carrier plate. The button cap forms a form-fit connection with the receiving sleeve.

A joystick includes: a base; a joystick shaft, four micro-switches, and a retaining ring. The joystick shaft is in operable connection with the base, and is surrounded by a trigger member and a limit member. The four micro-switches are fixed on the base, and are located in four cardinal directions of the trigger member, and four ordinal directions are formed between every two adjacent micro-switches. Each of the micro-switches is a mechanical-shaft-key switch. The retaining ring is configured to limit rotation angles of the joystick shaft. According to the joystick of the present application, the noise caused by the joystick can be effectively reduced, and the service life of the joystick can be prolonged, the directional output control in eight directions can be realized, and it is ensured that the micro-switches in the cardinal directions will not be damaged when the joystick performs the control operation in the ordinal directions.

The present invention discloses a care robot controller, which includes: a controller body that includes slide rails, finger slot sliders and a joystick, wherein the finger slot sliders are movably arranged on the slide rails and configured to receive pressing, and the joystick is configured to control the care robot; a gesture parsing unit configured to parse three-dimensional gestures of the controller body, and control the care robot to perform corresponding actions when the three-dimensional gestures of the controller body are in line with preset gestures; and a tactile sensing unit configured to sense the pressing received by the finger slot sliders and initiate a user mode corresponding to the pressing information, so that the controller body provides corresponding vibration feedback. Thus the user can control the controller efficiently and conveniently, the control accuracy is improved, and effective man-machine interaction is realized.

The present disclosure relates generally to control systems, and in particular apparatus, methods, and systems for controlling flights remotely or onboard the vehicle. More specifically, the present disclosure describes embodiments of a control system that allows a user to control the motion of a target in or along one or more degrees of freedom using a single controller. The control system described herein also include mechanisms that permit the conversion of user intent into discrete 3-D motions with tactile feedback relative to the null command.

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.

The present invention discloses a care robot controller, which includes: a controller body that includes slide rails, finger slot sliders and a joystick, wherein the finger slot sliders are movably arranged on the slide rails and configured to receive pressing, and the joystick is configured to control the care robot; a gesture parsing unit configured to parse three-dimensional gestures of the controller body, and control the care robot to perform corresponding actions when the three-dimensional gestures of the controller body are in line with preset gestures; and a tactile sensing unit configured to sense the pressing received by the finger slot sliders and initiate a user mode corresponding to the pressing information, so that the controller body provides corresponding vibration feedback. Thus the user can control the controller efficiently and conveniently, the control accuracy is improved, and effective man-machine interaction is realized.