An optical scanning device includes: an optical scanning unit configured to repeatedly scan an irradiation destination of irradiation light to a predetermined trajectory; a light emission control unit configured to control light emission of the irradiation light to irradiate irradiation points to the predetermined trajectory; and a driving signal generation unit configured to generate a driving signal for driving the optical scanning unit, wherein the light emission control unit irradiates the irradiation points to the predetermined trajectory so that the irradiation points are substantially uniformly dispersed in a region in which a density of the irradiation points is relatively low in a region in which the irradiation light is irradiated.

A wire handling tool includes a frame, a first actuator having a proximal end attached to the frame and a first distal end including a first grasping member for grasping a wire. The first distal end is configured to move along a first axis, wherein movement of the first distal end causes movement of the grasped wire along the first axis. The wire handling tool includes a controller for controlling the first actuator according to a wire feeding sequence to move the wire along the first axis.

An optical fiber scanner including: an optical fiber configured to emit, from a distal end thereof, illumination light guided from a light source; and at least three flat-plate-shaped piezoelectric elements that are disposed at positions spaced apart from the distal end that are closer to a proximal end of the optical fiber in the longitudinal axis direction and configured to vibrate the distal end of the optical fiber in a direction intersecting the longitudinal axis, wherein each of the piezoelectric elements has chamfered sections on both widthwise ends along at least a portion thereof in a longitudinal direction, and the piezoelectric elements adjacent in a circumferential direction are assembled into a tubular shape that surrounds the outer circumferential surface of the optical fiber in a close contact manner in a state where the chamfered sections are brought into close contact with one another.

Embodiments of the invention include a display formed on an organic substrate and methods of forming such a device. According to an embodiment, an array of pixel mirrors may be formed on the organic substrate. For example, each of the pixel mirrors is actuatable about one or more axes out of the plane of the organic substrate. Additionally, embodiments of the invention may include an array of routing mirrors formed on the organic substrate. According to an embodiment, each of the routing mirrors is actuatable about two axes out of the plane of the organic substrate. In embodiments of the invention, a light source may be used for emitting light towards the array of routing mirrors. For example, light emitted from the light source may be reflected to one or more of the pixel mirrors by one of the routing mirrors.

A fiber scanning system includes a fiber optic element having an actuation region and a motion actuator mechanically coupled to the fiber optic element. A continuous bond line is present between the actuation region and the motion actuator. The fiber scanning system also includes a retention collar mechanically coupled to the motion actuator.

The disclosure relates to the technical field of display, and provides a flexible display screen, a method for deformably driving the same, and a display device. The flexible display screen includes a flexible display panel and a deformable driver disposed on a back surface of the flexible display panel. The deformable driver drives the flexible display panel to deform based on the electrodeformation. The deformable driver includes a plurality of deformable units arranged in an array. The flexible display screen can achieve deformation with a variety of degrees of freedom, and can precisely control the deformation, thereby easy to achieve ultra-thin screen design.

Disclosed is a smart soft composite actuator which enables user-desiring deformation by changing the position of smart material functioning as an active component, wherein the smart soft composite actuator comprises a smart material whose shape is changeable based on an external signal; and a matrix for supporting the smart material and determining an external shape, wherein the smart material is positioned inside the matrix or in a surface of the matrix, and at least one of in-plane shear deformation and out-of-plane deformation is realized by controlling the position of smart material.

A method of fabricating a fiber scanning system includes forming a set of piezoelectric elements. The method also includes coating an interior surface and an exterior surface of each of the set of piezoelectric elements with a first conductive material. The method also includes providing a fiber optic element having an actuation region and coating the actuation region of the fiber optic element with a second conductive material. The method also includes joining the interior surfaces of the set of piezoelectric elements to the actuation region of the fiber optic element and poling the set of piezoelectric elements. The method also includes forming electrical connections to the exterior surface of each of the set of piezoelectric elements and the fiber optic element.

An wobble motor with an actuator extending in a Z direction between opposite mount and tool ends and comprising two sections offset in that Z direction. Each section comprises a structure of electrodes interleaved in a piezoelectric material in such a way that a Y-region can cause deflection in a Y-direction perpendicular to the Z-direction upon energizing of associated electrodes and such that a X-region can cause deflection in an X-direction perpendicular to the Y and Z directions upon energizing of associated electrodes.

This invention pertains to piezoelectric actuators made of single crystal active elements which not only exhibit uniform and superior displacement in the axial direction but also of lower cost to produce than full single crystal ring or tube actuators. Said multi-stake actuator is made up of multiple longitudinal (d33) or transverse (d3i or d32) mode piezoelectric single crystal active elements, bonded together by epoxy with the aid of shaped edge- and top and bottom washer-stiffeners which are configured to suit various application needs.