Laser light source, wavelength conversion light source, light combining light source, and projection system
Abstract
A laser light source (300), a wavelength conversion light source, a light combining light source, and a projection system. The laser light source comprises a laser element array, a focusing optical element (33), a collimation optical element (34), an integrator rod (36) for receiving and homogenizing a secondary laser beam array (382), an angular distribution control element (35) disposed on the light path between the laser element array and the integrator rod (36) for enlarging the divergence angle of the laser beam array (382) in the direction of the short axis of the light distribution, such that the rate between the divergence angle of each of the secondary laser beam that enters the integrator rod (36) in the direction of the short axis of the light distribution and the divergence angle in the direction of the long axis is greater than or equal to 0.7.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . A laser light source, comprising:
a laser light source array including a laser element array, for generating a collimated laser beam array; a focusing optical element disposed after the laser light source array, for focusing the laser beam array; an integrator rod disposed after the focusing optical element, for receiving and homogenizing the focused laser beam array; and an angular distribution control element disposed on an optical path between the laser element array and the integrator rod, for increasing, for each laser beam of the laser beam array that enters the integrator rod, a ratio of a divergence angle in a direction of a short axis of its light distribution to a divergence angle in a direction of a long axis.
2 . The laser light source of claim 1 , wherein the angular distribution control element is a collimating lens array, each collimating lens corresponding to a laser element for collimating a light emitted by the laser element; and
wherein the laser element is located on an optical axis of the corresponding collimating lens and away from its focal point, and wherein for the laser beam output by the collimating lens, the ratio of the divergence angle in the direction of the short axis of the light distribution to the divergence angle in the direction of the long axis is increased.
3 . The laser light source of claim 2 , wherein a distance between a location of the collimating lens and its ideal position is less than or equal to 0.05 mm, wherein the ideal position of the collimating lens is located at its focal point.
4 . The laser light source of claim 1 , wherein the angular distribution control element is at least one cylindrical lens, disposed between the focusing optical element and the integrator rod, wherein each cylindrical lens corresponds to at least one column of the laser beams of the laser beam array, wherein a column direction of each column of the at least one column of laser beams is parallel to a generating line of the cylindrical lens, and wherein for each laser beam of each column of laser beams, its long axis of the light distribution is parallel to the generating line of the cylindrical lens; and
wherein for each laser beam of each column of laser beams after its corresponding cylindrical lens, the ratio of the divergence angle in the direction of the short axis of the light distribution to the divergence angle in the direction of the long axis is increased.
5 . The laser light source of claim 1 , wherein the angular distribution control element is a scattering plate, disposed between the focusing optical element and the integrator rod, wherein for each laser beam in the laser beam array after scattering by the scattering plate, the ratio of the divergence angle in the direction of the short axis of the light distribution to the divergence angle in the direction of the long axis is increased.
6 . The laser light source of claim 1 , wherein the angular distribution control element is a micro-lens array, disposed between the focusing optical element and the integrator rod, wherein each micro-lens in the micro-lens array is a rectangle;
wherein a direction of a short axis of a light distribution of the laser beam array incident on the micro-lens array is parallel to a long side of each micro-lens; and wherein for each laser beam in the laser beam array outputted from the micro-lens array, the ratio of the divergence angle in the direction of the short axis of the light distribution to the divergence angle in the direction of the long axis is increased.
7 . The laser light source of claim 1 , wherein the angular distribution control element is a diffraction optical element, disposed between the focusing optical element and the integrator rod, wherein for each laser beam in the laser beam array, after passing through the diffraction optical element, the ratio of the divergence angle in the direction of the short axis of the light distribution to the divergence angle in the direction of the long axis is increased.
8 . The laser light source of claim 1 , wherein a light entrance port of the integrator rod is larger in size than a light exit port;
wherein the light entrance port of the integrator rod has a first side and a second side perpendicular to each other, the light exit port has a first side and a second side perpendicular to each other, wherein the first side of the light entrance port and the first side of the light exit port are parallel to each other, and wherein a length ratio of the first side of the light entrance port to the first side of the light exit port is smaller than a length ratio of the second side of the light entrance port to the second side of the light exit port; and wherein when the laser beam array enters the integrator rod, the direction of the long axis of the light distribution of each laser beam is parallel to the first side of the light entrance port of the integrator rod.
9 . The laser light source of claim 8 , wherein the first side of the light entrance port of the integrator rod is equal in length to the first side of the light exit port.
10 . The laser light source of claim 8 , wherein the light entrance port of the integrator rod is a square shape.
11 . The laser light source of claim 9 , wherein the laser light source array includes a laser element array and a collimating lens array, wherein each collimating lens corresponds to a laser element, for collimating the laser emitted by the laser element, and wherein each laser element is located on an optical axis of the corresponding collimating lens and away from its focal point, and wherein the angular distribution control element is located between the focusing optical element and the integrator rod.
12 . A wavelength conversion light source, comprising:
the laser light source of claim 1 ; and a wavelength conversion device, for receiving a light generated by the laser light source and emitting a converted light.
13 . A light combining light source, comprising:
the laser light source of claim 1 ; a wavelength conversion light source, which includes an excitation light source and a wavelength conversion device, the wavelength conversion device receiving an excitation light generated by the excitation light source and emitting a converted light; and a light combining device, where a light emitted by the laser light source and the converted light emitted by the wavelength conversion light source are incident onto the light combining device from different directions and are combined by the light combining device into one output light beam.
14 . A projection system, comprising:
the light combining light source of claim 13 ; and a spatial light modulator device, for receiving the output light beam generated by the light combining light source and modulating it.Cited by (0)
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