A device for a rotary haptic interface including: a rotary button and an interaction member interacting with a magnetorheological fluid, the rotary button and interaction member being secured to a shaft for rotation therewith, a chamber defined by walls and containing the fluid and the interaction element, and a mechanism generating a variable magnetic field. The element for interaction with the fluid includes a skirt surrounding the shaft, the skirt being secured to a longitudinal end of the shaft opposite the end to which the rotary button is secured, and extending from the first end towards the rotary button. The shaft passes through a single wall of the chamber and a sealing mechanism is arranged between the shaft and the wall. A mechanism for guiding the rotation of the shaft is arranged around the shaft between the sealing mechanism and the rotary button.

According to various embodiments, there is provided an input device including a handle configured to receive a force exerted by a user; a shaft coupled to the handle such that the force exerted on the handle is at least partially received on the shaft; wherein the handle is displaceable along a height of the shaft; wherein the handle includes a fastening member releasably biased to exert a force on a upper portion of the shaft in a direction at least substantially perpendicular to the height of the shaft.

According to various embodiments, a haptics device may be provided. The haptics device may include: an input circuit configured to receive audio input; a phase determination circuit configured to determine a phase of the audio input; a peak amplitude determination circuit configured to determine a peak amplitude of the audio input; and a haptics controller configured to control at least one actuator based on the phase of the audio input and based on the peak amplitude of the audio input.

A haptic interface with at least two degrees of freedom, comprising: at least one element (4) for interacting with a user, at least two passive brakes (6, 8) each extending along an axis (X, Y), each of the brakes (6, 8) being capable of exerting a resistive force about its axis (X, Y), the forces being controllable, measurement means (14, 16) for measuring a position of the element (4) for interacting with a user, detection means (11, 13) for detecting the force applied on the element (4) for interacting with the user, a control unit (UC) capable of sending commands to the brakes depending on information on the position of the element for interacting with the user and on the force applied on the element (4) for interacting with the user, such that said passive brakes (6, 8) generate resistive forces according to at least one given haptic pattern.

A haptic enabled device that is configured to render one or more haptic effects is provided. The haptic enabled device includes an actuator and a plurality of user input elements. Each of the plurality of user input elements is configured to be selectively coupled to the actuator. In addition, the actuator is configured to be positioned to render the one or more haptic effects at each of the plurality of user input elements.

A manipulation apparatus includes an image display device for displaying an image containing a command portion, an operation unit manually operable by a user, a pointer display unit for displaying a pointer at a position corresponding to an operation state of an operation unit on the image displayed on the image display unit, a vibration application unit for applying vibration to the operation unit, and a direction determination unit for, based on a positional relationship between the command portion and the pointer or based on contents of the command corresponding to the command portion, determining a direction of a force that is first applied to the operation unit as the vibration by the vibration application unit when the pointer is displayed on the command portion.

A method includes displaying information via a first display, displaying information via a second display, controlling the information displayed via the first display and the second display with a controller, and receiving a first input from a user through a user interface. The first input includes a command to change a setting of the first display or the second display and/or the information being displayed via the first display or the second display. The method also includes generating a first haptic effect to confirm receipt of the first input.

An operation device has a movable portion movable between a first position and a second position. The movable portion is operated by a user while the operation device is gripped by the user. The operation device receives information identifying a control mode and control information defined for each control mode as an instruction related to control of a tactile force sense, and controls the tactile force sense presented to the movable portion by using the received control information in the control mode identified by the received information.

Disclosed is an operation device including an interaction member, a microphone, a control circuit, and an audio signal processing circuit. The interaction member is used for interacting with a user. The control circuit periodically acquires scan data indicating the acting status of the interaction member. The audio signal processing circuit executes a noise removal process of removing noise from a collected audio signal collected by the microphone. The control circuit periodically transmits previously acquired scan data to the audio signal processing circuit. The audio signal processing circuit executes the noise removal process by using the scan data transmitted from the control circuit.

An operation device has a movable portion movable between a first position and a second position. The movable portion is operated by a user while the operation device is gripped by the user. The operation device receives information identifying a control mode and control information defined for each control mode as an instruction related to control of a tactile force sense, and controls the tactile force sense presented to the movable portion by using the received control information in the control mode identified by the received information.