The present disclosure relates to an operating member including: a support; an actuating part, which defines an actuating surface is mounted on the support by a mount to be movable relative to the support, by manual actuation against a resetting force, while carrying out an actuating movement from a rest position into a depressed position; a detector having at least one force sensor, wherein the detector is adapted to detect at least one position of the actuating part; wherein the mount includes a guidance mechanism having at least one pair of coupled levers, wherein the levers are each pivotably mounted on the support by a first pivot joint and on the actuating part—by a second pivot joint to cause a pivoting movement of the at least one pair of coupled levers by the actuating movement, wherein the guidance mechanism further includes at least one coupling rod.

In an operating device, a brake setting unit sets a target braking torque based on a braking torque pattern, and a rotational torque setting unit sets a target rotational torque based on a rotational torque pattern in accordance with information detected by a rotation detecting portion at reference time intervals. A control unit includes a time change adjustment unit. For at least one of the braking torque and the rotational torque, the time change adjustment unit changes the braking torque so that a current braking torque reaches the target braking torque and/or changes the rotational torque so that a current rotational torque reaches the target rotational torque in a predetermined time period greater than the reference time interval.

A controller controls an operating device. The operating device includes an operating member capable of being pushed by an operator, a biasing unit biasing the operating member in a return direction, a detecting unit configured to detect a distance of movement of the operating member and output a detection signal indicating the distance of movement, and a braking unit configured to brake movement of the operating member. In response to determining, based on the detection signal, that the operating member is pushed into a predetermined retracted position, the controller causes the braking unit to hold the operating member pushed. In response to determining, based on the detection signal, that the operating member is moved in the return direction because of a clearance in a drive transmission system between the operating member and the braking unit, the controller causes the braking unit to stop holding the operating member.

An input device includes an input structure, a magnet attached to the input structure, and an electromagnet. The magnet rotates when the electromagnet is activated, thereby rotating the input structure. The magnet and input structure rotate about a pivot in order to provide haptic and/or visual feedback to a user. The pivot may attach the magnet and input structure to a body, which in turn may be affixed to, or part of, an electronic device. The electromagnet can encircle the body and/or magnet.

The present disclosure relates to an imaging device, an imaging operation device, and a control method that enable better imaging.

A reaction force generating unit generates a reaction force with respect to the operation direction of the operation unit, and a control unit sets the reaction force on the basis of imaging-related information during operation on the operation unit. Further, the operation unit gives an instruction on a start of image capture by the imaging device, a position detection unit detects an amount of operation with respect to the operation direction of the operation unit, and the control unit sets the reaction force according to the amount of operation. The present technology can be applied, for example, to imaging devices such as single-lens reflex cameras and compact cameras.

Systems, devices and methods for the management of glucose levels in the body of patient featuring user interface input mechanisms configured to provide haptic feedback to the user are provided.

A knob device for vehicle includes a knob unit and a locking unit. The knob unit includes a rotating cover with an open end, a rotary shaft mounted to the open end, and a motor fixed to the rotating cover for driving the rotating cover to vibrate. The locking unit includes a rotary wheel which includes a main body fixed to the rotary shaft and latching teeth formed at a periphery of the main body and distributed in a ring around a central axis of the rotary wheel, a gap being defined between two neighboring teeth, an iron core configured to be inserted into the gap to limit rotation of the rotary wheel, and a solenoid connected to the iron core for driving the iron core to move. The knob device can realize locking of the rotary wheel clockwise and counter-clockwise, meeting requirement of diverse use.

A coversheet layer of an information handling system, comprising a coversheet having a key location of a haptic keyboard and a haptic touchpad area on a C-cover for the information handling system including a magnet or ferromagnetic insert in the coversheet for alignment to a top replaceable overlay layer magnetically attachable to the coversheet, a support layer, a contact foil placed between the coversheet and support layer, a piezoelectric element placed between the contact foil and support layer to receive an applied mechanical stress at the key location or touchpad actuation location of the coversheet and generate an electric actuation signal and a controller of the information handling system operatively coupled to the contact foil to receive the electric actuation signal and send an electrical haptic response signal to the piezoelectric element to cause the piezoelectric element to generate haptic feedback.

An electromagnetic feedback actuator for an operating element includes an electromagnet, a magnet armature, and a metal body. The electromagnet includes a magnetic coil and a magnetic core. The magnet armature is moveable relative to the electromagnet. The operating element includes an actuating element (e.g., touch surface, sensor surface). The magnet armature is mechanically coupled to the operating element to provide a force pulse to the operating element in response to contact with, or pressure actuation on, an actuating element of the operating element. The electromagnet is arranged in the metal body. The metal body, in integral fashion, forms the magnet armature, a magnet yoke for the magnetic core of the electromagnet, and a holder for the electromagnet. An arrangement includes at least one such electromagnetic feedback actuator coupled to an operating element.

A touchpad module includes a bracket, a touch member and a supporting assembly. The touch member is located over the bracket. The touch member includes a membrane wiring board and a circuit board. The circuit board is located over the membrane wiring board. The supporting assembly is arranged between a second end of the touch member and the bracket. While a first end of the touch member is pressed down, the first end of the touch member is swung relative to the bracket. Consequently, a membrane switch of the membrane wiring board is triggered. The present invention further provides a computing device with the touchpad module.