A light source assembly includes a substrate, a fixing base, an adjusting frame, an adjusting plate and a lens plate. The substrate includes a plurality of light-emitting units. The fixing base is fixed onto the substrate and comprising a bottom and at least one wall, wherein a recess is formed at least by the bottom and the at least one wall. The adjusting frame is movably disposed in the recess and having an opening. The adjusting plate is movably disposed in the opening of the adjusting frame. The lens plate is fixed onto the adjusting plate and includes a plurality of lenses, wherein a plurality of first through-holes are formed in the bottom of the fixing base and a plurality of second through-holes are formed in the adjusting plate such that the plurality of light-emitting units are exposed from the adjusting plate.

A projector protection method includes: multiple temperature sensors detect temperatures of multiple areas in a projector to obtain multiple temperature parameters respectively; a processor lowers an output power of a laser source when any temperature parameter corresponding to one of areas falls into corresponding one of multiple first temperature intervals and multiple fans in the projector are set to a maximum speed; and the processor turns off the laser source when any temperature parameter corresponding to one of areas falls into corresponding one of multiple second temperature intervals. The second temperature interval and the first temperature interval corresponding to the same temperature parameter are different from each other.

An illumination system, a projection apparatus and an illumination control method are provided. The illumination system includes an excitation light source, an optical component, a light source driver, a temperature sensing module and a controller. The excitation light source emits an excitation light beam. The optical component is located on a transmission path of the excitation light beam. The light source driver is configured to drive the excitation light source. The temperature sensing module is located in a neighboring region of the optical component and configured to sense a temperature of the neighboring region of the optical component to output a sensing voltage. The controller is configured to receive the sensing voltage to determine whether the sensing voltage falls out of a predetermined voltage range and configured to output a control signal to the light source driver to adjust the excitation light beam.

A projection device, a light source system and a projection method thereof are provided. A portion of the light-emitting units are controlled to provide a light beam as the first light beam. It is detected whether characteristic parameters of the light-emitting units providing the light beam reach a preset value. When the preset value is not reached, the light-emitting units providing the light beam are disabled, and the remaining light-emitting units are controlled to provide the back-up light beam as the first light beam. A portion of the first light beam is converted into a second light beam. The first light beam of which the wavelength is not converted and the second light beam are combined to generate an illumination beam. The illumination beam is converted into an image beam. The image beam is converted into a projection beam.

A display of various types of information on a subdisplay provided to a main body of a projector can be maintained even after supply of power source is stopped. According to a representative embodiment, included are: a power source connection unit connecting a power supply line for supplying, from outside, power used in a projection type image display apparatus; a nonvolatile display device provided separately from an image projection unit and displaying at least character information; and a processing unit displaying information on one or more predetermined items on the nonvolatile display device, and a state of displaying information on the nonvolatile display device is maintained even in a state where the power supply line is not connected to the power source connection unit.

A filter module having at least one filter region is provided. The filter module is pervious to a first color light with a first waveband in a converted light, and filters a second color light with a second waveband in the converted light. The filter module includes an absorptive filter and a dichroic film. The absorptive filter is located at the at least one filter region, and configured to absorb the second color light with the second waveband. The dichroic film is located on the absorptive filter, and is pervious to the first color light and reflects the second color light. The absorptive filter is configured to absorb the second color light coming from the dichroic film, and is pervious to the first color light. The first waveband is greater than a first wavelength, and the second waveband is smaller than the first wavelength. A projection device is also provided.

A projection device includes multiple optical fiber mounting mechanisms. Each of the optical fiber mounting mechanisms includes an optical fiber extending along a first direction as an axis direction, a signal circuit extending along the first direction, and a mounting structure. The optical fiber includes an engaging section. The mounting structure surrounds the engaging section of the optical fiber and the signal circuit. The mounting structure includes an installation portion extending radially relative to the first direction. The installation portion includes a surface and multiple elements exposed from the surface. The surface includes a normal direction parallel with the first direction. A first length of the engaging section of the optical fiber protruding from the surface of the installation portion is longer than lengths of the elements protruding from the surface.

A HUD 100 includes a R light source 12r, a G light source 12g, and a B light source 12b; collimating lenses 13r, 13g, and 13b that are arranged forwardly of the light sources; fly-eye lenses 16 and 17 that are arranged side by side on an optical path of light that exits from the collimating lenses; a light modulation element 20 that, based on image information, performs spatial modulation on light that has passed through the fly-eye lenses; a projection optical system 50 that projects image light onto a projection surface 7, the image light acquired by the spatial modulation by the light modulation element; photodetection elements PD1 and PD2 that are fixed to a portion of the fly-eye lens 16; and an image light control unit 40B that controls a brightness distribution of the image light based on a brightness of light detected by each of the photodetection elements.

The present invention provides an electronic device, wherein the electronic device includes a projector and a controller. The projector includes a laser module and a lens module with a cover glass, wherein a laser beam generated from the laser module passes through the lens module to generate a projected image. The controller is coupled to the projector, and is arranged for determining if the cover glass is broken to generate a determination result, and controlling a power of the laser module according to the determination result.

Laser safety systems, devices, and methods for use in laser projectors are described. A laser projector includes any number of laser diodes that each emit laser light, a laser diode power source, a current sensor to detect a magnitude of the electric current output by the power source, a photodetector to detect a power/intensity of the laser light, a beam splitter to direct a first portion of the light towards the photodetector and a second portion of the light towards an output on the projector, and first and second laser safety circuits responsive to signals from the photodetector and the current sensor, respectively. The laser safety circuits selectively electrically couples/uncouples the laser diodes from the power source depending on signals from the photodetector and/or the current sensor. Particular applications of the laser safety systems, devices, and methods in a wearable heads-up display are described.