Apparatus and method that includes providing a variable-parameter electrical component in a high-field environment and based on an electrical signal, automatically moving a movable portion of the electrical component in relation to another portion of the electrical component to vary at least one of its parameters. In some embodiments, the moving uses a mechanical movement device (e.g., a linear positioner, rotary motor, or pump). In some embodiments of the method, the electrical component has a variable inductance, capacitance, and/or resistance. Some embodiments include using a computer that controls the moving of the movable portion of the electrical component in order to vary an electrical parameter of the electrical component. Some embodiments include using a feedback signal to provide feedback control in order to adjust and/or maintain the electrical parameter. Some embodiments include a non-magnetic positioner connected to an electrical component configured to have its RLC parameters varied by the positioner.

A rotary drive mechanism comprises: a camshaft having a plurality of cams; and a plurality of transducer units each including a plurality of transducers that each have a dielectric elastomer layer and a pair of electrode layers sandwiching the dielectric elastomer layer. The plurality of transducer units each provide a drive force to a corresponding one of the plurality of cams. The plurality of transducers in one of the transducer units are arranged radially around the corresponding cam. Such a configuration can exert a drive force more efficiently.

Provided are a source driver for receiving a digital signal and providing a grayscale signal corresponding to the digital signal and a display device for displaying content. The source driver includes an amplifier configured to provide a grayscale signal, a second driving switch configured to provide the grayscale signal provided by the amplifier to an output node or block the grayscale signal, and a first driving unit including a first switch whose one end is connected to a first voltage and whose other end is connected to the output node and a second switch whose one end is connected to a second voltage and whose other end is connected to the output node, and configured to first drive the output node. The output node is first driven by the first driving unit and then second driven by the amplifier with the grayscale signal.

Provided are a source driver for receiving a digital signal and providing a grayscale signal corresponding to the digital signal and a display device for displaying content. The source driver includes an amplifier configured to provide a grayscale signal, a second driving switch configured to provide the grayscale signal provided by the amplifier to an output node or block the grayscale signal, and a first driving unit including a first switch whose one end is connected to a first voltage and whose other end is connected to the output node and a second switch whose one end is connected to a second voltage and whose other end is connected to the output node, and configured to first drive the output node. The output node is first driven by the first driving unit and then second driven by the amplifier with the grayscale signal.

An optical element driving mechanism is provided, including a fixed portion, a movable portion, a driving assembly, and a stopping assembly. The movable portion is movably connected to the fixed portion, wherein the movable portion is used for connecting to an optical element having a main axis. The driving assembly is disposed on the fixed portion or the movable portion, and the driving assembly is used for driving the movable portion to move relative to the fixed portion. The stopping assembly is connected to the movable portion and the fixed portion.

A camera includes a camera focus adjustment device, a lens, and an image sensor coupled to the camera focus adjustment device. The camera focus adjustment device includes a flexure structure. The flexure structure includes an outer framework of structural members continuously interconnected by flexure notch hinges. The flexure structure also includes two inner structural members oriented in parallel and extending from the outer framework of structural members. A gap is between the two inner structural members. The camera focus adjustment device also includes a piezoelectric material within the gap and a pair of wedges within the gap. The pair of wedges is affixed to the piezoelectric material and to one inner structural member of the two inner structural members. Based on temperature-based piezoelectric activity associated with the piezoelectric material, the camera focus adjustment device is operable to move the image sensor relative to the lens.

Provided is an optical scanning device including: a mirror portion that reflects incident light; a first actuator that allows the mirror portion to swing around a first axis; a second actuator that allows the mirror portion to swing around a second axis which is orthogonal to the first axis; a pair of first angle detection sensors that output a signal corresponding to an angle of the mirror portion around the first axis, the pair of first angle detection sensors being disposed at positions facing each other across the first axis or the second axis; and at least one processor, in which the processor generates a first angle detection signal representing the angle of the mirror portion around the first axis by adding or subtracting a pair of first output signals output from the pair of first angle detection sensors.

A piezoelectric adjustment apparatus has a piezo element whose movement is transmitted via a lever to a plunger. The plunger can be set against an abutment that is arranged at one side of the lever and a second abutment is provided at the other side of the lever.

Servomotor (1) comprising: —a base body (10), —an actuator body (20) which is arranged on the base body (10)—a drive arrangement (40) which is coupled to a drive section of the actuator body (20) and, when the drive arrangement (40) is activated, brings about a movement of the drive section of the actuator body (20) in one of two opposing circumferential directions on the basis of this coupling, —a rotational guide (50) with which the actuator body (20) is rotatably guided on the base body (10) and by which the movement of the drive section of the actuator body (20) is converted into a rotational movement of the actuator body (20), —a resetting arrangement (80) which couples the actuator body (20) and the base body (10) to one another and applies a resetting force between them, which resetting force opposes the actuating movement of the actuator body (20), —a magnet-compensation device (90) which reduces or cancels out the resetting force applied by the resetting device (80).

Servomotor (1) comprising: —a base body (10), —an actuator body (20) which is arranged on the base body (10)—a drive arrangement (40) which is coupled to a drive section of the actuator body (20) and, when the drive arrangement (40) is activated, brings about a movement of the drive section of the actuator body (20) in one of two opposing circumferential directions on the basis of this coupling, —a rotational guide (50) with which the actuator body (20) is rotatably guided on the base body (10) and by which the movement of the drive section of the actuator body (20) is converted into a rotational movement of the actuator body (20), —a resetting arrangement (80) which couples the actuator body (20) and the base body (10) to one another and applies a resetting force between them, which resetting force opposes the actuating movement of the actuator body (20), —a magnet-compensation device (90) which reduces or cancels out the resetting force applied by the resetting device (80).