Laser light from a light source part is guided to an irradiation plane by an irradiation optical system. In the irradiation optical system, element lenses are arrayed, and light fluxes that have passed through the element lenses respectively enter transparent elements. Irradiation regions of the light from the element lenses are superimposed on the irradiation plane. When each pair of adjacent target element lenses out of three target element lenses arrayed sequentially is regarded as a target element lens pair, the optical path lengths of three transparent elements corresponding to the three target element lenses are determined such that a peak position of light intensity on the irradiation plane resulting from the interference between the light fluxes through one target element lens pair is different from that corresponding to the other pair. This suppresses variations in light intensity caused by interference between the light fluxes on the irradiation plane.

The present invention relates to a head-up display device that allows a viewer to view an actual scene overlapped with a virtual image, and that is capable of creating a display image with suppressed luminance variation. A MEMS scanner scans synthesized laser light two-dimensionally in the main scanning direction H and the sub-scanning direction V substantially orthogonal to the main scanning direction H. A controller unit causes a first scan for generating a display image M on a transmissive screen by scanning in the main scanning direction H at high speed while scanning in the sub-scanning direction V, and a second scan for scanning a position displaced more toward the sub-scanning direction V than the first scan on the transmissive screen.

Apparatus and method for the amplification of a laser beam by pumping a homogenous composite source beam through an amplification medium. A slab crystalline active medium is side-pumped via a pump module having a laser diode bar and an optical assembly. The optical assembly has a fast axis collimator and a lens in the fast axis and an array of slow axis collimators and the lens in the slow axis. The lenses are spaced so that the individual source beams from the emitters are: imaged upon a first facet of the amplification medium; have a beam waist at or near the first facet; are sized to fill the first facet; substantially overlap on the first facet; and are directed so that peripheral source beams undergo total internal reflection on entering the amplification medium. Embodiments of multiple laser diode bars and optical assemblies are described together with double side pumping arrangements.

A flexible display device includes a flexible display panel, a correction panel, and a flexible printed circuit board. The correction panel includes a shape memory polymer layer and a driver. The shape memory polymer layer includes microlenses and the driver control the microlenses. The flexible printed circuit board connects the driver to a driving circuit board.

Device for shaping laser radiation (10a, 10c), comprising a component (1) having an entrance face (2) and an exit face (3), a first lens array (4) on the entrance face (2) with a plurality of lenses (5a, 5c, 5e) juxtaposed in the X-direction, and a second lens array (6) on the exit face (3) with a plurality of lenses (7a, 7c, 7e) juxtaposed in the Y-direction, wherein the laser radiation (10a, 10c) is deflected by a first one of the lenses (5a, 5c, 5e) of the first lens array (4) with respect to the X- and Y-direction by a different angle than from a second one of the lenses (5a, 5c, 5e) of the first lens array (4), and/or wherein the laser radiation (10a, 10c) is deflected by a first of the lenses (7a, 7c, 7e) of the second lens array (6) with respect to the X- and Y-direction by a different angle than by a second one of the lenses (7a, 7c, 7e) of the second lens array (6).

A method and apparatus for illuminating at least one object appearing in a field of view (FOV). An illumination system includes an illumination source configured to provide illumination to illuminate a target of the object. A collimating lens is configured to collimate the illumination and to provide the illumination to a fixed multiple lens array (MLA). The fixed multiple lens array provides the illumination to a movable MLA. The movable MLA is configured to provide the illumination to the target to illuminate the target. The position of the movable MLA may be adjusted to alter the illumination full field angle.

A device (1) for applying light (4) to an inner surface (2) of a cylinder (3), comprising a homogenizer (14), into which light (4) can enter and from which the light (4) can exit, wherein the homogenizer (14) has a cylindrical internal surface (15), on which the light (4) can be reflected after entering and before exiting, and also comprising ways for introducing light (4) into the homogenizing means (14), and focusing arrangements, which can focus light (4) exiting from the homogenizer (14) onto the inner surface (2) of the cylinder (3) to which light (4) is to be applied.

An optical element includes a first multi-lens surface and a second multi-lens surface. The first multi-lens surface has m areas arranged in an array, the m areas including a plurality of first cells. The second multi-lens surface has m second cells arranged in an array, the m second cells corresponding to the m areas. Light enters the first multi-lens surface. The light is emitted from the second multi-lens surface. The m areas of the first multi-lens surface each have n first cells. A focal plane of the m second cells is located at an emission side of the n first cells. The number m is a natural number no smaller than 2, and the number n is a natural number no smaller than 2.

The laser system may include first and second laser apparatuses and a beam delivery device. The first laser apparatus may be provided so as to emit a first laser beam to the beam delivery device in a first direction. The second laser apparatus may be provided so as to emit a second laser beam to the beam delivery device in a direction substantially parallel to the first direction. The beam delivery device may be configured to bundle the first and second laser beams and to emit the first and second laser beams from the beam delivery device to a beam delivery direction different from the first direction.

A display device includes: a display module including elemental pixel groups, each of the elemental pixel groups being configured to display an elemental image for displaying a reproduced image; an elemental lens array including elemental lenses, the elemental lenses being provided in front of the elemental pixel groups in one-to-one correspondence; a diopter adjustment element array including diopter adjustment elements, the diopter adjustment elements being provided in front of the plurality of elemental lenses in one-to-one correspondence; and a controller. The controller is configured to: control a part of the diopter adjustment elements in accordance with visual acuity of one eye of a user; and control the other part of the diopter adjustment elements in accordance with visual acuity of the other eye of the user.