A projection lens includes a DMD chip, an equivalent prism, a vibrating mirror, a first refractive lens group, a diaphragm, and a second refractive lens group that are successively arranged. The first refractive lens group includes a first lens, a triple-cemented lens, and a fifth lens that are successively arranged. The triple-cemented lens includes a second lens, a third lens, and a fourth lens, and the fourth lens is an aspherical lens.

In an electro-optic device, a chip provided with a mirror and a drive element adapted to drive the mirror, a cover having a light-transmitting property and adapted to cover the mirror in a planar view, and a spacer located between the cover and the chip are disposed on an interconnection board. Further, a boundary between the cover and the spacer, a boundary between the chip and the spacer, and a part of the interconnection board are covered with an inorganic film such as an aluminum oxide film. The inorganic film also covers a part of a chip-side terminal and an internal terminal, and a conductive member.

An electro-optic device includes an interconnection board provided with an internal terminal, and a chip mounted on the interconnection board, and the chip is provided with a mirror, a drive element, and a chip-side terminal electrically connected to the drive element. The interconnection board includes a first surface on which an internal terminal is disposed, a second surface located on an opposite side to the first surface, a third surface connecting the first surface and the second surface to each other, and a fourth surface located on an opposite side to the third surface. The interconnection board is provided with a metal member exposed on the first surface and the second surface, and through holes (a first through hole and a second through hole) extending from the third surface to the fourth surface and having contact with the metal member.

An optical reflecting device includes a mirror part, a pair of joints, a pair of vibration parts, a plurality of driving parts, and a fixed part. Each of the joints has a first end connected to respective one the facing positions to each other on the mirror part and a second end opposite to the first end, and extends along a first axis. Each of the vibration parts has a central portion connected to the second end of respective one of the joints. A plurality of driving parts is disposed in each of the pair of vibration parts, and rotates the mirror part. Both ends of each of the pair of vibration parts are connected to the fixed part. The beam width defined as the length of each of the joints in a direction orthogonal to the first axis is greater than the beam width of each of the pair of vibration parts.

An illumination optical system is provided that is configured to guide light emitted from a light source to an image generation unit that is arranged to be movable in a direction perpendicular to incoming light and is configured to generate an image by reflecting the incoming light. The illumination optical system includes a first lens that is arranged to be movable in a direction perpendicular to an optical axis of the first lens, a second lens that is arranged to be movable in a direction that changes a face-to-face distance between the first lens and the second lens, and a lens position control unit configured to displace the first lens and the second lens.

Light-emitting systems (e.g., projection systems) that comprise multiple light-emitting diodes (LEDs) are described herein. For example, the systems may include dual (i.e., two) primary red LEDs.

The present application provides a projection device. The projection device of the present application includes a lens barrel and a thermal transfer assembly disposed on an outer wall of the lens barrel; the thermal transfer assembly includes a first thermal transfer structure and a second thermal transfer structure, the first thermal transfer structure is disposed on the outer wall of the lens barrel and extends along an axial direction of the lens barrel, one end of the second thermal transfer structure is disposed at one end of the first thermal transfer structure, and the other end of the second thermal transfer structure extends away from the axial direction of the lens barrel. The application can effectively dissipate thermal when the lens assembly is working.

There is provided a lens array and an lens array capable of suitably preventing irregular brightness without reducing resolution. A micro lens array of a screen includes upper-level microlenses and lower-level microlenses which are formed on the incidence surface of the screen, which have the same effective diameter, and which have a structure that generates an optical path length difference Δ in transmission light. By disposing the upper-level microlenses and the lower-level microlenses at an interval based on the effective diameter, the basic periodic structure of a lens period is formed. Further, the upper-level microlenses and the lower-level microlenses form a basic block comprising a combination of the lenses having a structure that generates the optical path length difference. A concave-and-convex period PC based on the basic block is an integer multiple of the lens period.

An optical module includes: a light emitting unit configured to generate light; a mirror mechanism configured to reflect the light generated by the light emitting unit; and a scanning unit configured to scan the light reflected from the mirror mechanism. The light emitting unit includes: a light forming unit including a plurality of semiconductor light emitting elements and a filter that multiplexes light beams from the plurality of semiconductor light emitting elements; and a protective member disposed so as to surround the light forming unit. The mirror mechanism is disposed outside the protective member and integrated with the protective member, and the scanning unit is disposed in a region surrounded by the protective member.

A suspension system including a set of optics which adjust the size and focus of the projection image originating at a Digital Micro-Mirror Device mirror set. The suspension and adjustment system for these optics may be mounted between the Digital Micro-Mirror Device housing and the optics carrier. This system has the capability to both adjust the resulting size and focus of the image at the same distance to a wall, as well as adjust for out-of-plane issues which often result in skewed images. This results in an adjustable focal and image size differing from the manufacturer's intended throw pattern and allowing broader use of the projector to make smaller images at the same throw distance.