The present invention relates to a laser projection apparatus, and more particularly to a laser projection apparatus which uses a dichroic mirror capable of reflecting a first polarization light and allowing a second polarization light, having a polarization different with the first polarization light, to pass therethrough, and the first and second polarization lights are then mixed with each other thereby forming a laser beam.
Basically, general laser projection apparatus uses a light mixing module and a light splitting module to corporately form a plurality of color lights for image projection. Please refer to
As shown in
Then, the light splitting module 16 splits the laser beam into a plurality of color lights (such as red, blue and green lights) for the following image projection. To get a better understanding of the conventional laser projection apparatus 10 of
However, according to the aforementioned description, it is to be noted that the reflective mirrors 18 are required to be spaced with regular intervals, the first laser light sources 20 aims at the reflective mirrors 18, respectively, and the second laser light sources 22 and the reflective mirrors 18 are disposed to have an interlacing arrangement. Thus, the light mixing module 12 may not have a compact size and consequentially the conventional laser projection apparatus 10 may not have a miniaturization design due to the presence or existence of the intervals between the adjacent two reflective mirrors 18, the adjacent two first laser light sources 20 and the adjacent two second laser light sources 22.
Therefore, one object of the present invention is to provide a laser projection apparatus adopting a dichroic mirror capable of reflecting a first polarization light and allowing a second polarization light different from the first polarization light to pass therethrough. The first and second polarization lights are then mixed with each other thereby forming a laser beam. Thus, the laser projection apparatus of the present invention has compact size.
The present invention provides a laser projection apparatus, which includes a first light mixing module and a light splitting module. The first light mixing module includes a plurality of first laser light sources, a plurality of second laser light sources and a first dichroic mirror. The first laser light sources emit a first polarization light, respectively. The second laser light sources emit a second polarization light, respectively, wherein the first polarization light is different from the second polarization light. The first dichroic mirror is disposed between the first and second laser light sources. The first dichroic mirror includes a first surface toward each one of the first laser light sources and a second surface toward each one of the second laser light sources. The first surface reflects the first polarization light. The second polarization light sequentially passes through the second surface and the first surface to mix with the first polarization light and thereby forming a first laser beam. The light splitting module receives the first laser beam and splits the first laser beam into a plurality of color lights.
In summary, the laser projection apparatus of the present invention adopts a dichroic mirror capable of reflecting the first polarization light and allowing the second polarization light (having a polarization different with the first polarization light) to pass therethrough. The first and second polarization lights are then mixed with each other thereby forming a laser beam, and the laser bean is then emitted into the light splitting module for light splitting. As a result, compared with the conventional laser projection apparatus using reflective mirrors having specific intervals therebetween, the dimensions of the dichroic mirror and light mixing module are reduced; and consequentially, the laser projection apparatus of the present invention has compact size and miniaturization design.
For making the above and other purposes, features and benefits become more readily apparent to those ordinarily skilled in the art, the preferred embodiments and the detailed descriptions with accompanying drawings will be put forward in the following descriptions.
The present invention will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:
The present invention will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for purpose of illustration and description only. It is not intended to be exhaustive or to be limited to the precise form disclosed.
Please refer to
The first laser light sources 106 are spaced with intervals, and each first laser light sources 106 emits a first polarization light P1. The second laser light sources 108, disposed next to the first laser light sources 106, are spaced with intervals, and each of the second laser light sources 108 emits a second polarization light P2. In one embodiment, preferably, both of the first laser light sources 106 and the second laser light sources 108 are Blu-ray laser diodes; however, it is understood that the first laser light sources 106 and the second laser light sources 108 may have other types of implementations according to the practical application of the laser projection apparatus 100. The first polarization light P1 and the second polarization light P2 may be any general polarization light and the two polarization lights have different polarizations. In one embodiment, for example, the first polarization light P1 is S-polarization light, and the second polarization light P2 is P-polarization light; however, the present invention is not limited thereto. It should be noted that the quantity and the arrangement of the first and second laser light sources 106 and 108 illustrated in
The dichroic mirror 110 is disposed between the first and second light sources 106 and 108 and is tilted relative to the first and second light sources 106 and 108. The dichroic mirror 110 is an optical element capable of reflecting the first polarization light P1 and allowing the second polarization light P2 having a polarization different with that of the first polarization light P1 to pass therethrough. The dichroic mirror 110 has a first surface 112 toward each one of the first laser light sources 106 and a second surface 114 toward each one of the second laser light sources 108. Moreover, the first surface 112 reflects the first polarization light P1 emitted from the first laser light sources 106. The second polarization light P2 emitted from the second laser light sources 108 sequentially passes through the second surface 114 and the first surface 112 of the dichroic mirror 110, and consequentially is mixed with the first polarization light P1 thereby forming a laser beam L. In one embodiment, preferably, the angle θ formed between the normal line N of the dichroic mirror 110 and the laser beam L is about 40 degrees to 50 degrees; however, the present invention is not limited thereto.
The process of the laser projection apparatus 100 producing the laser beam L will be described as follow. In the following exemplary process, a configuration of the first polarization light P1 being S-polarization light, the second polarization light P2 being P-polarization light and the dichroic mirror 110 being for reflecting S-polarization light and allowing P-polarization light to pass therethrough is taken as an example; however, the present invention is not limited thereto. In other words, the first polarization light P1 may be P-polarization light, the second polarization light P2 may be S-polarization light in an another embodiment, and accordingly the dichroic mirror 110 is for reflecting P-polarization light and allowing S-polarization light to pass therethrough in the another embodiment.
As shown in
It is to be noted that the brightness of the laser beam produced by the light mixing module in the laser projection apparatus can be further enhanced by employing more than one light mixing module. Please refer to
The second light mixing module 202 is disposed adjacent to the first light mixing module 201, and includes a plurality of third laser light sources 206, a plurality of fourth laser light sources 208 and a dichroic mirror 210. The third laser light sources 206 are spaced with intervals, and each of the third laser light sources 206 emits a third polarization light P3. The fourth laser light sources 208, disposed adjacent to the third laser light sources 206, are spaced with intervals, and each of the fourth laser light sources 208 emits a fourth polarization light P4. In one embodiment, preferably, both of the third laser light sources 206 and the fourth laser light sources 208 are Blu-ray laser diodes; however, it is understood that the third laser light sources 206 and the fourth laser light sources 208 may have other types of implementations according to the practical application of the laser projection apparatus 200. The third polarization light P3 and the fourth polarization light P4 may be any commonly-known polarization light with different polarizations. In one embodiment, for example, the third polarization light P3 is S-polarization light and correspondingly the fourth polarization light P4 is P-polarization light; however, the present inv limited thereto. It should be noted that the quantity and the arrangement of the third and fourth laser light sources 206 and 208 illustrated in
The dichroic mirror 210 is disposed between the third and fourth laser light sources 206 and 208 and is tilted relative to the third and fourth laser light sources 206 and 208. The dichroic mirror 210 is an optical element capable of reflecting the third polarization light P3 and allowing the light having a polarization different with that of the third polarization light P3 (that is, the fourth polarization light P4) to pass therethrough. The dichroic mirror 210 has a third surface 212 toward each one of the third laser light sources 206 and a fourth surface 214 toward each one of the forth laser light sources 208. Moreover, the third surface 212 reflects the third polarization light P3 emitted from the third laser light sources 206. The fourth polarization light P4 emits from the fourth laser light sources 208 sequentially passes through the fourth surface 214 and the third surface 212 of the dichroic mirror 210 consequentially, and is mixed with the third polarization light P3 thereby forming a laser beam L1. In one embodiment, preferably, the angle θ1 formed between the normal line N1 of the dichroic mirror 210 and the laser beam L1 is about 40 degrees to 50 degrees, and the reflective mirrors 204 are disposed parallel to the dichroic mirror 210; however, the present invention is not limited thereto.
As shown in
The process of the laser projection apparatus 200 producing the laser beam will be described as follow. In the following exemplary process, a configuration of the first and third polarization lights P1 and P3 being S-polarization light, the second and fourth polarization lights P2 and P4 being P-polarization light and the dichroic mirrors 110, 210 being for reflecting S-polarization light and allowing P-polarization light to pass therethrough is taken as an example; however, the present invention is not limited thereto. In other words, the first and third polarization lights P1 and P3 may be P-polarization light, the second and fourth polarization lights P2 and P4 may be S-polarization light in an another embodiment, and accordingly the dichroic mirrors 110, 210 are for reflecting P-polarization light and allowing S-polarization light to pass therethrough in the another embodiment. Or, in still another embodiment, the first and fourth polarization lights P1 and P4 may be P-polarization light, the second and third polarization lights P2 and P3 may be S-polarization light, the dichroic mirror 110 is for reflecting P-polarization light and allowing S-polarization light to pass therethrough, and the dichroic mirror 210 is for reflecting S-polarization light and allowing P-polarization light to pass therethrough.
As shown in
Then, as shown in
In summary, the laser projection apparatus of the present invention adopts a dichroic mirror capable of reflecting the first polarization light and allowing the second polarization light (having a polarization different with the first polarization light) to pass therethrough. The first and second polarization lights are then mixed with each other thereby forming a laser beam, and the laser bean is then emitted into the light splitting module for light splitting. As a result, compared with the conventional laser projection apparatus using reflective mirrors having specific intervals therebetween, the dimensions of the dichroic mirror and light mixing module are reduced; and consequentially, the laser projection apparatus of the present invention has a more compact size and improved miniaturization design.
While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
Number | Date | Country | Kind |
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102148481 | Dec 2013 | TW | national |