A multidirectional input device includes a frame, a plate-shaped base below the frame, a load detector provided on the frame or the base, and circuitry. The frame stores part of a tiltable operation stick and a tilt detector. The circuitry is configured to output an output signal representing the direction and the magnitude of an operation on the operation stick, based on the angle detection value of the tilt of the operation stick detected by the tilt detector and the load detection value of a load applied to the frame detected by the load detector. The circuitry is configured not to output the output signal or to output the output signal that sets the magnitude of the operation to zero, when the load detection value detected by the load detector is less than a predetermined threshold.

A video augmentation system is disclosed. The system includes a sensor configured to detect haptics signals associated with user manipulation; a camera configured to record images associated with the user manipulation; and a processor configured to combine the haptics signals and the images into a combined haptics/images file.

A piloting device for piloting an aircraft includes a piloting member suitable for being actuated by a pilot, a mechanism for mounting and guiding in rotation the piloting member about at least one rotation axis with respect to a frame, at least one force sensor connected between the piloting member. The mechanism includes at least one sensing element configured to produce a signal upon deformation indicative of a force applied to the piloting member. The force sensor comprises at least one pair of bearing surfaces. The device also includes at least one pair of stops configured to limit the angular amplitude of rotation of the piloting member with respect to the frame on abutment of the at least one pair of bearing surfaces with at least one pair of stops. The stops or at least one of the bearing surfaces comprises a compliant material.

In embodiments, a work vehicle magnetorheological fluid (MRF) joystick system includes a joystick device, an MRF joystick resistance mechanism, and a controller architecture. The joystick device includes, in turn, a base housing, a joystick movably mounted to the base housing, and a joystick bias mechanism coupled to the joystick and exerting a centering force urging the joystick to return to the centered position when moved therefrom. The controller architecture is operable in a modified centering mode in which the controller architecture: (i) determines when the joystick begins return toward the centered position due to the centering force applied by the joystick bias mechanism; and (ii) when so determining, commands the MRF joystick resistance mechanism to modify a rate at which the joystick returns to the centered position by varying the MRF resistance force applied to the joystick.

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 method to detect a hands off status of a user input device is disclosed. The method comprising filtering a sensed force, acting on the user input device, using a first lag filter to provide a first output, the lag filter comprising a first lag time constant. Filtering the sensed force using a second lag filter, substantially in parallel with the first filter, to provide a second output, the second lag filter comprising a second lag time constant greater than the first lag time constant. Comparing with a first threshold value, in a first comparison, a magnitude of a difference between the first output and the second output. Comparing with a second threshold value, in a second comparison, a magnitude of the second output. Designating the user device to have a hands off status based on the first comparison and the second comparison.

The invention relates to a steering device sensor comprising an electrically insulating support, which can be integrated in a steering device for a vehicle, and an electric conductor, which is connected to the support, characterised in that the conductor forms multiple measurement zones of different measuring sensitivity on the support. The invention also relates to a measurement system comprising two steering device sensors. The invention also relates to an operator control system using a measurement system comprising two steering device sensors. The measurement system and the operator control system can be used in a steering device such as a steering wheel.

An input device provides an improved feeling of operation to a user and allows the user to recognize an operation of a handle by providing haptic feedback by limiting a direction of movement of the handle of the input device provided in a vehicle according to a control item, applying a reaction force to the handle, or generating a vibration. The input device includes the handle that is movable in a first direction and a second direction and a motor that is configured to generate force related to a movement of the handle. A driver is configured to operate the motor. A controller operates the driver to limit a moving direction of the handle to the first direction or the second direction according to a control item controlled by the movement of the handle.

A multidirectional input device includes an operation input part, a base, and a load detector. The operation input part includes an operation stick, two coupled parts configured to convert a tilt of the operation stick into two rotation angles orthogonal to each other, at least one return spring configured to return the operation stick to an upright position, and a frame accommodating the two coupled parts, the at least one return spring, and a part of the operation stick. The base has a plate shape and is provided below the frame. The load detector is provided on the frame or the base and is configured to detect a load applied to the frame.

A controller for operative connection to a power assisted transport vehicle that is at least partially directed by a human operator in physical contact with the vehicle, the controller including: a contact surface with a deadman switch, a first sensor and a second sensor each responsive to manual actuation of the contact surface, each sensor having a respective first sensor output signal and a second sensor output signal, and a signal processing means adapted to process the first and second output signals, and control the mode of operation of the controller in accordance with the state of the deadman switch.