A projector device includes an illumination module and an imaging module. The imaging module is connected to the illumination module and includes a housing, a relay optical system, and a projection optical system. The housing has a first annular receiving groove and a second annular receiving groove. The first annular receiving groove is closer to the illumination module than the second annular receiving groove. A center axis line of the first annular receiving groove and a center axis line of the second annular receiving groove are on the same axis line. The relay optical system includes a lens received in the first annular receiving groove. The projection optical system includes a lens and a reflecting mirror received in the second annular receiving groove. Mirror centers of the lenses and a mirror center the reflecting mirror are located on the same axis line.

A projector device includes an illumination module and an imaging module. The imaging module is connected to the illumination module and includes a housing, a relay optical system, and a projection optical system. The housing has a first annular receiving groove and a second annular receiving groove. The first annular receiving groove is closer to the illumination module than the second annular receiving groove. A center axis line of the first annular receiving groove and a center axis line of the second annular receiving groove are on the same axis line. The relay optical system includes a lens received in the first annular receiving groove. The projection optical system includes a lens and a reflecting mirror received in the second annular receiving groove. Mirror centers of the lenses and a mirror center the reflecting mirror are located on the same axis line.

A high dynamic range projector (HDRP) is configured with at least one spatial light modulator having red, green and blue digital light projector (DPL) chips, a light laser source including red, green and blue (RGB) light laser systems which are operative to illuminate respective DLP chips; and a central processing unit (CPU) coupled to the DLP engines and respective RGB light laser systems, wherein the CPU is operative to determine an optimal average power of each of the RGB light laser systems at a frame rate based on a desired contrast ratio.

A high dynamic range projector (HDRP) is configured with at least one spatial light modulator having red, green and blue digital light projector (DPL) chips, a light laser source including red, green and blue (RGB) light laser systems which are operative to illuminate respective DLP chips; and a central processing unit (CPU) coupled to the DLP engines and respective RGB light laser systems, wherein the CPU is operative to determine an optimal average power of each of the RGB light laser systems at a frame rate based on a desired contrast ratio.

A projection display device includes a plurality of semiconductor lasers, a collimating lens, an integrator illumination system, a deflection element, a transfer optical system, and a projection lens. The collimating lens is configured to collimate a plurality of laser beams output from the plurality of semiconductor lasers. The integrator illumination system is configured to overlap the plurality of laser beams collimated by the collimating lens to form a rectangular illumination region. The deflection element is disposed at a position closer to the collimating lens than a position where the rectangular illumination region is formed by the integrator illumination system. The transfer optical system is configured to enlarge and transfer the rectangular illumination region deflection-scanned by the deflection element to a reflective optical modulation element. The projection lens is configured to project video light output from the reflective optical modulation element.

A wavelength-converting wheel has a light incident side. The wavelength-converting wheel includes a motor, a turntable, a wavelength-converting layer and a reflective element. The motor has a rotating shaft. The turntable has an inner ring portion and an annular irradiation portion. The inner ring portion is sleeved on the rotating shaft, the annular irradiation portion is connected to an outer edge of the inner ring portion, and the annular irradiation portion includes a light-reflecting region and a wavelength-converting region. The wavelength-converting layer is disposed in the wavelength-converting region and has a light receiving surface facing the light incident side. The reflective element is disposed in the light-reflecting region and has a reflective surface facing the light incident side. The light receiving surface is coplanar with the reflective surface or the light receiving surface is farther from the light incident side with respect to the reflective surface.

The instant disclosure provides an optical wheel including a rotary light-transmittable substrate, an optical microstructure layer and an optical coating layer. The rotary light-transmittable substrate has a first surface and a second surface opposite to the first surface, and rotates around a central axis. The optical microstructure is disposed on the first surface or the second surface. The optical coating layer is disposed on the optical microstructure. At least a laser incident light beam is projected onto the first surface or the second surface of the rotary light-transmittable substrate for forming a laser emission light beam emitted from the second surface.

The instant disclosure provides an optical wheel including a rotary light-transmittable substrate, an optical microstructure layer and an optical coating layer. The rotary light-transmittable substrate has a first surface and a second surface opposite to the first surface, and rotates around a central axis. The optical microstructure is disposed on the first surface or the second surface. The optical coating layer is disposed on the optical microstructure. At least a laser incident light beam is projected onto the first surface or the second surface of the rotary light-transmittable substrate for forming a laser emission light beam emitted from the second surface.

The present disclosure provides a display system that may comprise a retro-reflective screen configured to reflect incident light along a direction that is opposite to the direction of propagation of the incident light, and a projector that may project light characterizing an image or video to the retro-reflective screen. An array of optical elements or an individual optical element may be positioned between the retro-reflective screen and the projector. The array of optical elements or individual optical element may direct the light from the projector to the retro-reflective screen in a manner such that the image or video is viewable by a user at an observation angle of at least about 2 degrees.

Embodiments of the disclosure provide a projection display apparatus comprising: a light source for emitting a light beam; a first light path configured to project the light beam emitted from the light source to a first display position; a second light path configured to project the light beam emitted from the light source to a second display position; a light patch switching device configured to switch the light beam emitted from the light source between the first light path and the second light path; and a light modulation device through which both the first light path and the second light path pass, wherein the light modulation device is configured to modulate the light beam passing therethrough to generate a display image.