JP4193369B2 - Color separation device, color composition device, color separation composition device, and projector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides a color separation device that separates light from a light source into light for a plurality of wavelength regions, a color composition device that combines light for a plurality of wavelength regions, and converts light from the light source into light for a plurality of wavelength regions. A color separation and synthesis device that separates and combines the separated light, and separates the light from the light source into light for each of a plurality of wavelength ranges, modulates each separated light to generate an image, and the image is displayed on a screen or the like. The present invention relates to a projector that projects onto a projection surface.
[0002]
[Prior art]
As a conventional projector, for example, a projector that performs color separation using a dichroic mirror is known. FIG. 18 is a plan view showing a configuration of a conventional projector. The projector includes a light source 81, a first lens array 82, a second lens array 83, a superimposing lens 84, reflection mirrors 85, 89, 91a and 91b, color separation dichroic mirrors 86 and 87, and an incident light. Side polarizing plates 94a, 94b and 94c, transmissive liquid crystal panels 95a, 95b and 95c, exit side polarizing plates 96a, 96b and 96c, a cross dichroic prism 98, and a projection lens 99 are provided.
[0003]
The light source 81 is disposed on the incident surface side of the first lens array 82. The projection lens 99 is disposed on the exit surface side of the cross dichroic prism 98. The lens arrays 82 and 83 and the superimposing lens 84 constitute a uniform illumination optical system that uniformly illuminates the three transmissive liquid crystal panels 95a, 95b, and 95c.
[0004]
Non-polarized light emitted from the light source 81 is divided into a plurality of partial light beams by a plurality of small lenses of the first lens array 82 and is condensed in the vicinity of the plurality of small lenses of the second lens array 83. Is done. The plurality of partial light beams emitted from the second lens array 83 are superimposed on the transmissive liquid crystal panel 95 (transmissive liquid crystal panels 95a, 95b, and 95c) by the superimposing lens 84. Thereby, this uniform illumination optical system can illuminate the transmissive liquid crystal panel 95 uniformly.
[0005]
The reflection mirror 85 guides the light beam emitted from the superimposing lens 84 toward the dichroic mirror 86. The dichroic mirror 86 transmits the red light component of the light emitted from the superimposing lens and reflects the blue light component and the green light component. The red light transmitted through the dichroic mirror 86 is reflected by the reflection mirror 91b, passes through the incident-side polarizing plate 94b, and reaches the transmissive liquid crystal panel 95b for red light.
[0006]
Of the blue light and green light reflected by the dichroic mirror 86, the green light is reflected by the dichroic mirror 87, passes through the collimating lens 92c, passes through the incident side polarizing plate 94c, and is transmissive for green light. The liquid crystal panel 95c is reached. On the other hand, the blue light passes through the dichroic mirror 87, passes through the reflection mirrors 89 and 91a, passes through the incident-side polarizing plate 94a, and reaches the transmissive liquid crystal panel 95a for blue light.
[0007]
Each color light incident on the three transmissive liquid crystal panels 95a, 95b and 95c is modulated in accordance with image information to form an image of each color light. The modulated lights emitted from the transmissive liquid crystal panels 95a, 95b, and 95c are incident on the cross dichroic prism 98 through the exit-side polarizing plates 96a, 96b, and 96c, respectively.
[0008]
The cross dichroic prism 98 has a function as a color light combining optical system for combining three colors of modulated light to form a color image. The three colors of modulated light are combined by the cross dichroic prism 98 to form combined light for projecting a color image. The combined light generated by the cross dichroic prism 98 is emitted in the direction of the projection lens 99. The projection lens 99 has a function of projecting the combined light onto a projection surface such as a screen (not shown), and displays a color image on a projection surface such as a screen (not shown).
[0009]
[Problems to be solved by the invention]
By the way, the dichroic mirrors 86 and 87 used in the color separation optical system of the conventional projector are arranged so as to be inclined at 45 degrees with respect to the main optical axis. Therefore, the dichroic mirrors 86 and 87 are designed so as to obtain desired color separation characteristics for light having an incident angle of 45 degrees. Therefore, if all the light incident on the dichroic mirrors 86 and 87 is 45 degrees, that is, if all light parallel to the main optical axis is incident on the dichroic mirrors 86 and 87, desired color separation can be performed. . However, when light having an incident angle other than 45 degrees is incident, the spectral characteristics of the dichroic mirrors 86 and 87 have an incident angle dependency, and thus desired color separation cannot be performed.
[0010]
However, in this projector, each partial light beam condensed on the condenser lens of the lens array 83 is diverged and guided to the liquid crystal panels 95a, 95b, and 95c. Accordingly, as shown in FIG. 19, divergent light having an incident angle in the range of 45 ° ± α is incident on the color separation surfaces of the dichroic mirrors 86 and 87. As shown in FIG. 20, in the spectral characteristic with respect to light having an incident angle of 45 degrees, the spectral characteristic with respect to light having an incident angle of 45 degrees + α, and the spectral characteristic with respect to light having an incident angle of 45 degrees−α, The separation boundary wavelength (cutoff wavelength) that divides the wavelength range is different.
[0011]
Therefore, when divergent light from the uniform illumination optical system is incident, the cutoff wavelength differs depending on the incident angle, and thus the apparent reflectance and transmittance curves of the dichroic mirrors 86 and 87 with respect to the divergent light become gentle. As shown in FIG. 21, the light having the wavelength to be reflected by the dichroic mirrors 86 and 87 is transmitted, and the light having the wavelength to be transmitted is reflected to cause color mixing. For example, in the dichroic mirror 86 that transmits red light and reflects cyan light, a large amount of light in the wavelength region on the short wavelength side is mixed with red light, yellowish red light is transmitted, and long time is applied to cyan light. A lot of light in the wavelength region on the wavelength side is mixed and cyan light close to white is reflected. When such color mixture occurs, the color purity of each separated light decreases, the color reproducibility of the projected image decreases, and color unevenness occurs.
[0012]
On the other hand, as another conventional projector that reduces this color mixture and increases the color purity of each color light, a projector in which a color filter is arranged immediately before color composition is known. In this projector, it is possible to cut light in an extra wavelength region by a color filter and to increase the color purity of each color light. However, since light in an extra wavelength region is cut, loss of light energy corresponding to the cut occurs. Further, the incident angle dependency of the spectral characteristics of the dichroic mirror as described above also becomes a problem in the cross dichroic prism 98. That is, when the light incident on the cross dichroic prism 98 is affected by the incident angle dependency, the light that should be reflected (or transmitted) to the projection lens 99 side may not be reflected (or transmitted). When such a phenomenon occurs, the light use efficiency decreases, and the brightness of the projected image decreases.
[0013]
The present invention has been made in view of the above, and reduces color mixing of separated light while suppressing loss of light energy, improves color purity of each separated light, and thereby reproduces color of a projected image. The purpose is to improve the property and reduce the color unevenness. Another object of the present invention is to improve the light use efficiency in color synthesis, thereby improving the brightness of the projected image.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, the color separation device of the present invention includes a color separation unit that transmits light in a predetermined wavelength range, reflects light in other wavelength ranges, and separates the light into a plurality of wavelength ranges. By rotating the polarization plane of the predetermined wavelength range or the other wavelength range, among the light incident on the color separation means, the light of the predetermined wavelength range is changed to P-polarized light with respect to the color separation plane of the color separation means. And color selective polarization converting means for converting the light in the other wavelength range into S-polarized light with respect to the color separation surface.
[0015]
According to the first color separation device, it is possible to reduce the influence of the incident angle dependency by utilizing the polarization dependence of the spectral characteristics of the color separation means, and the light to be reflected and the light to be transmitted, Both characteristics can be improved. Therefore, it is possible to prevent color separation of separated light while suppressing loss of both light to be reflected and light to be transmitted, and to improve the color purity of each separated light.
[0016]
In the first color separation device, in particular, the polarization boundary wavelength of the color selective polarization conversion unit is included in a wavelength region between the cutoff wavelength of the P polarization and the cutoff wavelength of the S polarization of the color separation unit. It is preferable to do.
[0017]
This is because the above-described effects can be obtained more reliably by doing so.
[0018]
In addition, the color composition device of the present invention transmits color light in the first wavelength range, reflects light in the second wavelength range different from the first wavelength range, and combines these lights. And S-polarized light with respect to the color synthesis surface of the color synthesis unit of the light in the first wavelength range or the second wavelength range incident on the color synthesis unit is converted into P-polarized light. And color selective polarization conversion means.
[0019]
According to the first color synthesizing apparatus, it is possible to reduce the influence of the incident angle dependence by utilizing the polarization dependence of the spectral characteristics of the color synthesizing means, and the light to be reflected or transmitted Loss can be prevented. Therefore, the light use efficiency in color composition can be improved.
[0020]
In the first color synthesizing apparatus, in particular, the polarization boundary wavelength of the color selective polarization converting unit is included in a wavelength region between the cutoff wavelength of P-polarized light and the cutoff wavelength of S-polarized light of the color synthesizing unit. It is preferable to do.
[0021]
This is because the above-described effects can be obtained more reliably by doing so.
[0022]
A first color separation / synthesis apparatus according to the present invention has the above-described color separation apparatus, a color synthesis means for synthesizing light separated by the color separation means, and having spectral characteristics substantially matching the color separation means, It comprises.
[0023]
According to the first color separation / synthesis apparatus, it is possible to obtain the same effect as the color separation apparatus. Further, the effect can be reproduced even in color synthesis. Therefore, if the first color separation / synthesis apparatus is employed in an optical apparatus such as a projector, it is possible to improve color reproducibility and reduce color unevenness.
[0024]
A second color separation / synthesis apparatus according to the present invention comprises the above-described color separation apparatus and a color synthesis apparatus, and the color synthesis means synthesizes the light separated by the color separation apparatus.
[0025]
According to the second color separation / synthesis apparatus, it is possible to obtain the same effects as those of the color separation apparatus and the color synthesis apparatus. Therefore, if the second color separation / synthesis apparatus is employed in an optical apparatus such as a projector, it is possible to improve color reproducibility, reduce color unevenness, and improve light utilization efficiency.
[0026]
According to the second color separation / synthesis apparatus, it is possible to obtain the same effects as those of the color separation apparatus and the color synthesis apparatus. Therefore, if the second color separation / synthesis apparatus is employed in an optical apparatus such as a projector, it is possible to improve color reproducibility, reduce color unevenness, and improve light utilization efficiency.
[0027]
In the third color separation / synthesis device of the present invention, the light separated by the first color separation device is synthesized by the color separation means provided in the color separation device. In the third color separation / synthesis device, the first color separation device separates the light into a plurality of wavelength ranges, and the light is synthesized by the color separation means provided in the color separation device. According to the third color separation / synthesis apparatus, it is possible to obtain the same effect as that of the color separation apparatus. Further, the effect can be reproduced even in color synthesis. Therefore, if the third color separation / synthesis apparatus is employed in an optical apparatus such as a projector, it is possible to improve color reproducibility and reduce color unevenness.
[0028]
The first projector of the present invention separates the light from the light source, modulates the separated light to generate an image, and projects the image. And a light modulation means for modulating the light separated by the color separation device.
[0029]
According to the first projector, it is possible to obtain the same effect as the color separation device. Further, the effect can be reproduced even in color synthesis. Therefore, it is possible to improve the color reproducibility of the projected image and reduce color unevenness.
[0030]
According to another aspect of the invention, there is provided a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image. The light modulation unit modulates the separated light. And the above color synthesizing device for synthesizing the light modulated by the light modulation means.
[0031]
According to the second projector, it is possible to obtain the same effects as the color separation device and the color synthesis device. Therefore, it is possible to improve the color reproducibility of the projected image and reduce color unevenness, and it is possible to obtain a bright projected image by improving the light utilization efficiency.
[0032]
A third projector according to the present invention is a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image. And a light modulation means that is provided in the subsequent stage of the color separation apparatus and in the previous stage of the color synthesis means or the color synthesis apparatus, and modulates the light separated by the color separation apparatus.
[0033]
According to the third projector, it is possible to obtain the same effect as that of the first or second color separation / synthesis apparatus. Therefore, it is possible to improve the color reproducibility of the projected image and reduce color unevenness, and it is possible to obtain a bright projected image by improving the light utilization efficiency.
[0034]
According to another aspect of the invention, there is provided a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image. And a light modulation means for modulating the light separated by the separation device, and the light modulated by the light modulation means is synthesized by the color separation means provided in the color separation device. According to the fourth projector, it is possible to obtain the same effect as the third color separation / synthesis apparatus. Therefore, it is possible to improve the color reproducibility of the projected image and reduce color unevenness.
[0035]
Further, a fifth projector of the present invention separates light from a light source, modulates the separated light to generate an image, and projects the image to transmit light in the first wavelength range, Reflects light in the second wavelength range, which is shorter than the first wavelength range, and in the third wavelength range, which is longer than the first wavelength range, and converts the light into three wavelength ranges. Color separation means for separating; polarization conversion means for converting light from the light source into linearly polarized light; and the first wavelength region or the second wavelength region of the linearly polarized light converted by the polarization conversion device, and the first wavelength region. By rotating the polarization plane in the third wavelength region, the light in the first wavelength region among the light incident on the color separation device is changed to P-polarized light with respect to the color separation surface of the color separation device, and the second S-polarized light with respect to the color separation surface is converted into light in the wavelength region and the third wavelength region A color selective polarization conversion means that is for anda three modulation means for modulating the separated light by the color separation means.
[0036]
According to the fifth projector, in the case of separating light into three substantially continuous wavelength ranges, the influence of the incident angle dependency can be reduced by using the polarization dependency of the spectral characteristics of the color separation means. Therefore, it is possible to efficiently improve the characteristics of both light to be reflected and light to be transmitted. Therefore, it is possible to prevent color separation of separated light while suppressing loss of both light to be reflected and light to be transmitted, and to improve the color purity of each separated light. As a result, it is possible to improve the color reproducibility of the projected image and reduce color unevenness.
[0037]
In the fifth projector, in particular, the polarization boundary wavelength of the color selective polarization conversion means is included in the wavelength range between the cutoff wavelength of the P polarization and the cutoff wavelength of the S polarization of the color separation means. Is preferred.
[0038]
This is because the above-described effects can be obtained more reliably by doing so.
[0039]
The color separation means is preferably constituted by a cross dichroic prism or a cross dichroic mirror.
[0040]
If comprised in this way, size reduction of a projector and simplification of the optical system can be achieved.
[0041]
In addition, it is preferable that the fifth projector further includes a color synthesizing unit that has a spectral characteristic substantially coincident with the color separation unit and synthesizes the light modulated by the light modulation unit.
[0042]
With such a configuration, it is possible to reduce the influence of the incident angle dependency on the color synthesizing means, and it is possible to prevent loss of light to be reflected and light to be transmitted. Therefore, the light use efficiency in color synthesis can be improved, and a bright projected image can be obtained.
[0043]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. The present invention is not limited to the embodiments.
[0044]
(Embodiment 1)
FIG. 1 is a plan view showing a schematic configuration of the projector according to the first embodiment of the invention. This projector includes a light source 1, a uniform illumination optical system 19, a color selective polarization converter 5, a cross dichroic prism 6 as a color separation means, and lenses 7a, 7b, 9a, 9b, constituting a relay optical system. 11a, 11b, field lens 11c, reflecting mirrors 8a, 8b, 10a and 10b, λ / 2 phase difference plates 12a, 12b and 16, incident side polarizing plates 13a, 13b and 13c, and transmissive liquid crystal panel 14a , 14b and 14c, exit side polarizing plates 15a, 15b and 15c, a cross dichroic prism 17 as a color synthesizing means, and a projection lens 18.
[0045]
FIG. 2 is a plan view showing a schematic configuration of the light source 1 and the uniform illumination optical system 19 shown in FIG. The uniform illumination optical system 19 includes a first lens array 2, a second lens array 21, a light shielding plate 22, a polarization conversion element array 23, and a superimposing lens 4.
[0046]
FIG. 2 shows only main components for ease of explanation. The light source 1 includes a light source lamp 1a and a concave mirror 1b. Radial light rays (radiated light) emitted from the light source lamp 1a are reflected by the concave mirror 1b and emitted in the direction of the lens array 2 as a substantially parallel light bundle. As the light source lamp 1a, for example, a halogen lamp, a metal halide lamp, a high-pressure mercury lamp, or the like can be used. The concave mirror 1b is a parabolic mirror, but may be replaced with a combination of an elliptical mirror and a parallelizing lens. The light source lamp 1a and the concave mirror 1b are not limited to those described here.
[0047]
The light emitted from the light source 1 is divided into a plurality of partial light beams 20 by the plurality of lenses 2 a of the lens array 2. 3A and 3B are a front view and a side view showing a schematic configuration of the lens array 2 shown in FIG. In the lens array 2, minute lenslets 2a having a rectangular outline are arranged in a matrix of M rows in the vertical direction and 2N columns in the horizontal direction. From the center in the lateral direction of the lens, there are N rows of small lenses 2a in the left direction and N rows in the right direction. In this example, M = 10 and N = 4. The external shape of each small lens 2a viewed from the light traveling direction is set to be substantially similar to the shape of the transmissive liquid crystal panel 14 (transmissive liquid crystal panels 14a, 14b and 14c). For example, if the aspect ratio (ratio of horizontal and vertical dimensions) of the image forming area of the transmissive liquid crystal panel 14 is 4: 3, the aspect ratio of each small lens 2a is also set to 4: 3.
[0048]
The partial light flux divided by the first lens array 2 is guided by the plurality of lenses 21a of the second lens array 21 so as to be condensed on a polarization separation film 27 of a polarization beam splitter array 24 described later. The lens array 21 has the same configuration as the lens array 2. In addition, the direction of the lenses of the lens arrays 2 and 21 may be either the light traveling direction or the opposite direction. Moreover, as shown in FIG. 2, you may face the mutually different direction. The lens array 21 does not necessarily have the same configuration as the lens array 2, and can be omitted when the light emitted from the light source 1 is excellent in parallelism.
[0049]
Each partial light beam 20 emitted from the second lens array 21 is converted into one type of linearly polarized light by the polarization conversion element array 23. In the polarization conversion element array 23, as shown in FIG. 2, the two polarization conversion element arrays 23a and 23b are arranged in symmetrical directions with the optical axis LA in between. FIG. 4 is a perspective view showing a schematic configuration of the polarization conversion element array 23a shown in FIG. The polarization conversion element array 23a includes a polarization beam splitter array 24, a λ / 2 phase difference plate 25 (shown by diagonal lines in FIG. 4) selectively disposed on a part of the light exit surface of the polarization beam splitter array 24, It has. The polarization beam splitter array 24 has a shape in which a plurality of columnar translucent members 26 each having a parallelogram cross section are sequentially bonded. Polarization separation films 27 and reflection films 28 are alternately formed on the interface of the translucent member 26. The λ / 2 phase difference plate 25 is selectively attached to the outgoing surface of the transmitted light from the polarization separation film 27 or the reflected light from the reflective film 28. In this example, a λ / 2 phase difference plate 25 is attached to the outgoing surface of transmitted light by the polarization separation film 27.
[0050]
FIG. 5 is an explanatory diagram for explaining the principle of polarization conversion of the polarization conversion element array 23a according to the first embodiment. First, light having a random polarization direction is incident on the incident surface of the polarization conversion element array 23a.
[0051]
The incident light is separated into S-polarized light and P-polarized light by the polarization separation film 27. The S-polarized light is reflected almost perpendicularly by the polarization separation film 27 and further reflected by the reflection film 28 and emitted. On the other hand, the P-polarized light passes through the polarization separation film 27 as it is. A λ / 2 phase difference plate 25 is disposed on the exit surface from which the P-polarized light transmitted through the polarization separation film is emitted. The P-polarized light transmitted through the polarization separation film is s-polarized by the λ / 2 phase difference plate 25. It is converted into and injected. Therefore, most of the light that has passed through the polarization conversion element array 23a is emitted as S-polarized light. If the light emitted from the polarization conversion element array 23a is to be P-polarized light, the λ / 2 phase difference plate 25 may be disposed on the emission surface from which S-polarized light reflected by the reflective film 28 is emitted.
[0052]
The polarization conversion element array 23b has the same configuration and function as the polarization conversion element array 23a.
[0053]
FIG. 6 is an explanatory diagram showing a schematic configuration of the light shielding plate 22 shown in FIG. The light shielding plate 22 has an opening 22a in a substantially rectangular plate-like body so that light is incident only on the incident surface corresponding to the polarization separation film 27 among the incident surfaces of the two polarization conversion element arrays 23a and 23b. It has the structure which provided.
[0054]
The plurality of partial light beams 20 emitted from the polarization conversion element array 23 are superimposed on the transmissive liquid crystal panel 14 by the superimposing lens 4. The uniform illumination optical system 19 can illuminate the transmissive liquid crystal panel 14 uniformly and with one kind of polarized light by the above configuration. In this example, the condensing lens 21 and the superimposing lens 4 are configured separately. However, by concentrating some or all of the plurality of small lenses 21a constituting the condensing lens 21 as an eccentric lens, The lens 21 may have the function of the superimposing lens 4 together. In this case, the position where the condenser lens 21 is arranged may be either the position of the condenser lens 21 in FIG.
[0055]
The light emitted from the superimposing lens 4 enters the color selective polarization converter 5. The color selective polarization converter 5 is a plate-like optical element that rotates only the polarization plane of incident light in a predetermined wavelength range by 90 degrees. This predetermined wavelength range can be freely set. Here, the green wavelength region is set as the predetermined wavelength region. As such a color selective polarization converter 5, for example, Color Switch (registered trademark of Color link) in which a retardation film is laminated is known. The color-selective polarization converter 5 has a small incident angle dependency, and the slope of the conversion characteristic curve between the polarization plane rotation wavelength range that rotates the polarization plane and the polarization plane non-rotation wavelength range that does not rotate the polarization plane is steep. It is. Further, in this example, since the color selective polarization converter 5 is arranged perpendicular to the main optical axis which is the substantially central axis of the incident light beam, the incident angle dependency of the color selective polarization converter 5 is further increased. Get smaller.
[0056]
Here, the polarization plane rotation wavelength region is a wavelength region in which the conversion rate is 50% or more, that is, a wavelength region in which the light amount of the converted light is greater than or equal to the light amount of the non-converted light. The polarization plane non-rotating wavelength region is a wavelength region where the conversion rate is less than 50%, that is, a wavelength region where the light amount of the converted light is less than the light amount of the non-converted light. In this case, the polarization boundary wavelength (cutoff wavelength) that separates the polarization plane rotation wavelength region and the polarization surface non-rotation wavelength region is the wavelength at which the conversion rate is 50%, that is, the light amount of the converted light and the light amount of the non-converted light. The wavelength range becomes equal. One cutoff wavelength λ1 of the color selective polarization converter 5 is set to the boundary wavelength between the blue wavelength range and the green wavelength range, and the other cutoff wavelength λ2 is the boundary between the green wavelength range and the red wavelength range. Is set to the wavelength.
[0057]
That is, in the color selective polarization converter 5, green light in the green wavelength region out of the light incident on the cross dichroic prism 6 becomes P-polarized light with respect to the color separation surface of the cross dichroic prism 6, and Polarization is controlled so that blue light and red light become S-polarized light with respect to the color separation surface of the cross dichroic prism 6. As shown in FIG. 7, when S-polarized white light from the superimposing lens 4 enters the color-selective polarization converter 5, green light in the green wavelength region is converted to P-polarized light and output. The cross dichroic prism 6 receives S-polarized blue light and red light with respect to the color separation surface and P-polarized green light with respect to the color separation surface.
[0058]
7 shows a case where light having a rectangular wavelength characteristic having a constant light quantity in the visible wavelength region is incident on the color selective polarization converter 5 in order to simplify the description. The cross dichroic prism 6 has a function of separating light emitted from the color selective polarization converter 5 into three color lights of red, green, and blue. In the cross dichroic prism 6, a dielectric multilayer film that reflects red light and a dielectric multilayer film that reflects blue light are formed in an approximately X shape at the interface of four right-angle prisms. With these dielectric multilayer films, the green light component of the light emitted from the color selective polarization converter 5 is transmitted, and the blue light component and the red light component are respectively reflected left and right.
[0059]
Here, in general, dichroic optical elements such as a dichroic prism and a dichroic mirror have different spectral characteristics depending on whether incident light is P-polarized light or S-polarized light with respect to the color separation surface. FIGS. 8A and 8B and FIGS. 9A and 9B are diagrams illustrating spectral characteristics of a general dichroic mirror with respect to P-polarized light and S-polarized light. When P-polarized light and S-polarized light are incident from the same angle with respect to the color separation surface of the dichroic optical element, the cutoff frequency of P-polarized light is shifted so that the transmission characteristics are stronger than S-polarized light. The cutoff wavelength is shifted so that the reflection characteristic is stronger than that of P-polarized light.
[0060]
Therefore, the transmission wavelength region for P-polarized light is wider than the transmission wavelength region for S-polarized light. That is, in the case of a color separation surface that transmits light in the long wavelength region and reflects light in the short wavelength region, the transmission wavelength region for P-polarized light is spread in the short wavelength direction compared to the transmission wavelength region for S-polarized light (see FIG. 8 (A)). In the case of a color separation surface that transmits light in the short wavelength region and reflects light in the long wavelength region, the transmission wavelength region for P-polarized light is wider in the longer wavelength direction than the transmission wavelength region for S-polarized light (see FIG. 9 (A)). In the dichroic optical element, the reflection wavelength region for S-polarized light is wider than the reflection wavelength region for P-polarized light.
[0061]
That is, in the case of a color separation surface that transmits light in the long wavelength range and reflects light in the short wavelength range, the reflection wavelength range for S-polarized light is wider in the long wavelength direction than the reflection wavelength range for P-polarized light (see FIG. 8 (B)). Also, in the case of a color separation surface that transmits light in the short wavelength region and reflects light in the long wavelength region, the reflection wavelength region for S-polarized light spreads in the short wavelength direction compared to the reflection wavelength region for P-polarized light (see FIG. 9 (B)). The transmitted wavelength range is a wavelength range where the color separation surface transmits light. For example, a wavelength range where the transmittance is 50% or more, that is, a wavelength range where the amount of transmitted light is equal to or greater than the amount of reflected light. It is. On the other hand, the reflection wavelength region is a wavelength region in which the color separation surface reflects light, for example, a wavelength region in which the reflectance is 50% or more, that is, a wavelength region in which the amount of reflected light is greater than or equal to the amount of transmitted light. It is. Note that the long wavelength region and the short wavelength region described here do not indicate specific wavelength regions but are shown by comparing the two.
[0062]
FIGS. 10A and 10B are diagrams illustrating spectral characteristics of the cross dichroic prism 6 according to the first embodiment with respect to P-polarized light and S-polarized light. Although the cross dichroic prism 6 has two color separation surfaces, the spectral characteristics of these two color separation surfaces are illustrated as one spectral characteristic. In this spectral characteristic, the transmission wavelength range of P-polarized light with respect to the color separation surface extends in the long wavelength and short wavelength directions compared to the transmission wavelength range of S-polarized light (see FIG. 10A), and the reflection wavelength range of S-polarized light is It spreads in the long wavelength and short wavelength directions as compared to the transmission wavelength region of P-polarized light (see FIG. 10B). The reflection wavelength region and the transmission wavelength region also change depending on the incident angle with respect to the color separation surface of the cross dichroic prism 6.
[0063]
That is, when divergent light having an incident angle in the range of 45 ° ± α is incident on the color separation surface of the cross dichroic prism 6, the set angle with respect to the main optical axis (the main optical axis and the normal of the color separation surface The reflection wavelength range and the transmission wavelength range are the spectral characteristics for light having an incident angle of 45 degrees, the spectral characteristics for light having an incident angle of 45 degrees + α, and the spectral characteristics for light having an incident angle of 45 degrees−α. The separation boundary wavelength (cutoff wavelength) that divides is different.
[0064]
The characteristic of the cross dichroic prism 6 is, for example, a cutoff wavelength λ for P-polarized light having an incident angle of 45 degrees. _3P Cutoff wavelength λ for S and S polarized light _3S So that the cut-off wavelength λ1 of the color-selective polarization converter 5 is included in the wavelength range λ3 between and the cut-off wavelength λ for P-polarized light having an incident angle of 45 degrees _4P Cutoff wavelength λ for S and S polarized light _4S Is set so that the cut-off wavelength λ2 of the color selective polarization converter 5 is included in the wavelength range λ4 between. Preferably, the wavelength at the approximate center of the wavelength range λ3 is set to the wavelength λ1, and the wavelength at the approximate center of the wavelength range λ4 is set to the wavelength λ2. As a result, as shown in FIG. 11, the P-polarized green light between the cutoff wavelength λ1 and the cutoff wavelength λ2 is efficiently transmitted within the transmission wavelength range of the cross dichroic prism 6. Further, as shown in FIG. 12, the S-polarized blue light having a shorter wavelength than the cutoff wavelength λ1 and the S-polarized red light having a longer wavelength than the cutoff wavelength λ2 are reflected by the cross dichroic prism 6. Reflected efficiently in the area.
[0065]
By setting the characteristics of the color selective polarization converter 5 and the cross dichroic prism 6 in this way, the influence of the incident angle dependency of the cross dichroic prism 6 is reduced, and the reflectance of light in the wavelength region to be reflected is increased. The transmittance of light in the wavelength region to be transmitted can be increased, and the color mixture of separated light can be reduced. The color selective polarization converter 5 may be disposed anywhere between the cross dichroic prism 6 and the polarization conversion element array 23, for example, may be disposed in front of the superimposing lens 4. If the green light incident on the cross dichroic prism 6 becomes P-polarized light and the red light and blue light become S-polarized light, the polarization planes in the red and blue regions may be rotated. In this case, the arrangement of the λ / 2 phase difference plate 25 may be changed so that the light emitted from the polarization conversion element array 23 becomes P-polarized light.
[0066]
The red light reflected by the color separation surface of the cross dichroic prism 6 passes through the lens 7b, is reflected by the reflecting mirror 8b, passes through the lens 9b, is reflected by the reflecting mirror 10b, passes through the lens 11b, and has a λ / 2 phase difference. The plate 12b rotates the polarization plane by 90 degrees to become P-polarized light with respect to the incident surface of the transmissive liquid crystal panel 14b, and reaches the transmissive liquid crystal panel 14b for red light through the incident-side polarizing plate 13b. The lenses 7b, 9b, and 11b are lenses that constitute a relay optical system. The lens 11b also has a function of converting each partial light beam 20 emitted from the superimposing lens 4 into a light beam parallel to the central axis.
[0067]
On the other hand, the blue light reflected by the color separation surface of the cross dichroic prism 6 passes through the lens 7a, is reflected by the reflecting mirror 8a, passes through the lens 9a, is reflected by the reflecting mirror 10a, passes through the lens 11a, and passes through λ / 2. The polarizing plate rotates 90 degrees by the phase difference plate 12a to become P-polarized light with respect to the incident surface of the transmissive liquid crystal panel 14a, and reaches the transmissive liquid crystal panel 14a for blue light through the incident side polarizing plate 13a. The green light transmitted through the cross dichroic prism 6 passes through the lens 11c, passes through the incident-side polarizing plate 13c, and reaches the transmissive liquid crystal panel 14c for green light. Similarly to the lenses 7b, 9b, and 11b, the lenses 7a, 9a, and 11a are lenses that constitute a relay optical system. The lenses 11a and 11c have the same function as the lens 11b.
[0068]
Note that the relay optical system is used in the optical path of blue light and red light because the length of the optical path of blue light and red light is longer than the length of the optical path of green light. This is to prevent a decrease in light use efficiency due to the above. That is, the partial light beam 20 incident on the lenses 7a and 7b is transmitted as it is to the lenses 11a and 11b. The three transmissive liquid crystal panels 14a, 14b, and 14c have a function as a light modulation device that modulates incident light in accordance with given image information (image signal). Thereby, each color light incident on the three transmissive liquid crystal panels 14a, 14b and 14c is modulated in accordance with the given image information.
[0069]
The blue modulated light and red modulated light emitted from the transmissive liquid crystal panels 14a and 14b are incident on the cross dichroic prism 17 through the exit-side polarizing plates 15a and 15b, respectively. Further, the green modulated light emitted from the transmissive liquid crystal panel 14 c passes through the emission side polarizing plate 15 c, and the polarization plane is rotated by 90 degrees by the λ / 2 phase difference plate 16, and is incident on the cross dichroic prism 17. Here, light that is not related to the formation of the projected image becomes P-polarized light and is absorbed by the exit-side polarizing plates 15a, 15b, and 15c.
[0070]
The cross dichroic prism 17 has a function of combining three colors of modulated light to form a color image. In the cross dichroic prism 17, a dielectric multilayer film that reflects red light and a dielectric multilayer film that reflects blue light are formed in a substantially X shape at the interface of four right-angle prisms. These dielectric multilayer films combine three colors of modulated light to form combined light for projecting a color image. The combined light generated by the cross dichroic prism 17 is emitted in the direction of the projection lens 18. The projection lens 18 has a function of projecting the combined light onto a projection surface such as a screen (not shown).
[0071]
In the present embodiment, in order to increase the efficiency of synthesis by the cross dichroic prism 17, the green light transmitted by the cross dichroic prism 17 is converted to P-polarized light with respect to the color synthesis surface of the cross dichroic prism 17. The blue light and red light reflected by the light are S-polarized light with respect to the color synthesis surface of the cross dichroic prism 17. Here, the spectral characteristics of the cross dichroic prism 17 and the spectral characteristics of the cross dichroic prism 6 are not necessarily matched. However, by substantially matching these spectral characteristics, the effect of the incident angle dependency of the cross dichroic prism 17 is reduced and the use of light is the same as the effect of reducing the effect of the angle dependency in the cross dichroic prism 6. Efficiency can be improved.
[0072]
In the example described above, the light is separated by the cross dichroic prism 6, but the light may be separated by using another dichroic optical element instead of the cross dichroic prism 6. For example, as shown in FIG. 13, a cross dichroic mirror 31 in which two dichroic mirrors are crossed may be used, or as shown in FIG. 14, two dichroic mirrors 32 and 33 may be used. Even when these dichroic optical elements are used, by setting the spectral characteristics of the cross dichroic prism 17 and the spectral characteristics of these dichroic optical elements to substantially coincide with each other, the influence of the incident angle dependency of the cross dichroic optical element 17 can be reduced. It can reduce and can improve the light utilization efficiency.
[0073]
In the above-described example, the light is synthesized by the cross dichroic prism 17. However, as shown in FIG. 15, the projector has a three-throw configuration, and the three color lights are synthesized on a projection surface such as a screen (not shown). You may make it do. That is, instead of the cross dichroic prism 17 and the projection lens 18, three projection lenses 18a, 18b, and 18c may be used.
[0074]
As described above, according to the first embodiment, the color-selective polarization converter 5 provided in the previous stage of the cross dichroic prism 6 receives the linearly polarized light, and the green light out of the light incident on the cross dichroic prism 6. The green wavelength range of the linearly polarized light that is input is rotated by 90 degrees so that P is polarized light for the color separation surface of the cross dichroic prism 6 and red light and blue light are S polarization for the color separation surface. As a result, green light is more easily transmitted by the cross dichroic prism 6 and red light and blue light are more reliably reflected by the cross dichroic prism 6, so that the loss of light energy is suppressed and the separated light is reduced. Color mixing can be reduced and the color purity of each separated light can be improved.
[0075]
(Embodiment 2)
The second embodiment of the present invention separates light in a plurality of stages using a plurality of dichroic mirrors as color separation means, and combines light in a plurality of stages using a plurality of dichroic optical elements for synthesis. is there. FIG. 16 is a plan view showing the configuration of the projector according to the second embodiment of the invention. Note that portions having the same configuration as in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0076]
This projector includes a light source 1, a uniform illumination optical system 19, color selective polarization converters 5a, 5b, 49a and 49b, dichroic mirrors 41a and 41b as color separation means, reflection mirrors 42a and 42b, and λ. / 2 phase difference plates 43a and 43c, incident side polarizing plates 44a, 44b and 44c, transmissive liquid crystal panels 45a, 45b and 45c, exit side polarizing plates 46a, 46b and 46c, and dichroic mirrors as color combining means 48 a and 48 b and a projection lens 18 are provided.
[0077]
The light emitted from the superimposing lens 4 is incident on the color selective polarization converter 5a in the same manner as in the first embodiment. The color selective polarization converter 5a rotates only the polarization plane in the red wavelength region by 90 degrees. That is, in the color selective polarization converter 5a, red light of the light incident on the dichroic mirror 41a becomes S-polarized light with respect to the color separation surface of the dichroic mirror 41a, and green light and blue light with respect to the color separation surface of the dichroic mirror 41a. The polarization is controlled so as to be P-polarized light.
[0078]
The dichroic mirror 41a has a function of separating the light emitted from the color selective polarization converter 5a into red light and cyan light (blue light and green light). The red light component incident on the dichroic mirror 41a is reflected, and the green light component and the blue component are transmitted. The characteristic of the dichroic mirror 41a is that the color selective polarization converter 5a is in a wavelength region between the cutoff wavelength for P-polarized light and the cutoff wavelength for S-polarized light having an incident angle of 45 degrees, which is a set angle with respect to the main optical axis. Are set so as to include the cutoff wavelength. Preferably, it is set so that the wavelength in the approximate center of the wavelength band is the cutoff wavelength of the color selective polarization converter 5a. Thereby, it is possible to separate the light while suppressing the influence of the incident angle dependency of the dichroic mirror 41a.
[0079]
The cyan light transmitted through the dichroic mirror 41a enters the color selective polarization converter 5b. The color selective polarization converter 5b rotates only the polarization plane in the green wavelength region by 90 degrees. That is, in the color selective polarization converter 5b, of the light incident on the dichroic mirror 41b, the green light becomes S-polarized light with respect to the color separation surface of the dichroic mirror 41b, and the red light becomes P-polarized light with respect to the color separation surface of the dichroic mirror 41a. The polarization is controlled so that
[0080]
The dichroic mirror 41b has a function of separating light emitted from the color selective polarization converter 5b into green light and blue light. The green light component incident on the dichroic mirror 41b is reflected and the blue component is transmitted. The dichroic mirror 41b cuts the color selective polarization converter 5b in a wavelength region between the cutoff wavelength for P-polarized light and the cutoff wavelength for S-polarized light having an incident angle of 45 degrees that is a set angle with respect to the main optical axis. It is set to include an off wavelength. Preferably, it is set so that the wavelength in the approximate center of the wavelength band becomes the cutoff wavelength of the color selective polarization converter 5b. Thereby, it is possible to separate light while suppressing the influence of the incident angle dependency of the dichroic mirror 41b.
[0081]
The red light reflected by the dichroic mirror 41a is reflected by the reflection mirror 42a, and the polarization plane is rotated 90 degrees by the λ / 2 phase difference plate 43a to become P-polarized light with respect to the incident surface of the transmissive liquid crystal panel 45a. The light reaches the transmissive liquid crystal panel 45a for red light through the plate 44a. The green light reflected by the dichroic mirror 41b is rotated by 90 ° by the λ / 2 phase difference plate 43c to become P-polarized light with respect to the incident surface of the transmissive liquid crystal panel 45c, and passes through the incident-side polarizing plate 44c. It reaches the transmissive liquid crystal panel 45c for green light. The blue light transmitted by the dichroic mirror 41b passes through the incident-side polarizing plate 44b and reaches the transmissive liquid crystal panel 45b for blue light.
[0082]
The three transmissive liquid crystal panels 45a, 45b, and 45c have a function as a light modulation device that modulates incident light in accordance with given image information (image signal). Thereby, each color light incident on the three transmissive liquid crystal panels 45a, 45b and 45c is modulated in accordance with given image information. The red light emitted from the transmissive liquid crystal panel 45a passes through the emission-side polarizing plate 46a, and the polarization plane is rotated by 90 degrees by the λ / 2 phase difference plate 47a, so that the color composition means also acts on the color composition surface of the dichroic mirror 48a. P-polarized light enters the dichroic mirror 48a.
[0083]
The green light emitted from the transmissive liquid crystal panel 45c passes through the emission-side polarizing plate 46c and enters the dichroic mirror 48a as S-polarized light with respect to the color synthesis surface of the dichroic mirror 48a. Further, the blue light emitted from the transmissive liquid crystal panel 45b passes through the emission-side polarizing plate 46b, is reflected by the reflection mirror 42b, and enters the dichroic mirror 48b as S-polarized light with respect to the color composition surface of the dichroic mirror 48b as color composition means. Incident.
[0084]
The dichroic mirror 48a has a function of transmitting incident red light, reflecting incident green light, and combining these lights. The dichroic mirror 48a has a spectral characteristic almost opposite to that of the dichroic mirror 41a. That is, it has a spectral characteristic in which the reflection curve and the transmission curve of the dichroic mirror 41a are interchanged. Thereby, it is possible to separate the light while suppressing the influence of the incident angle dependency of the dichroic mirror 48a.
[0085]
The combined light of red light and green light synthesized by the dichroic mirror 48a is incident on the color selective polarization converter 49a. Here, the light incident on the color selective polarization converter 49a is P-polarized in the red wavelength region and S-polarized in the green wavelength region with respect to the color combining surface of the dichroic mirror 48b. The color selective polarization converter 49a rotates only the polarization plane in the green wavelength region by 90 degrees. In other words, the color selective polarization converter 49a aligns the combined light incident on the dichroic mirror 48b with P-polarized light.
[0086]
Further, the cutoff wavelength between the red wavelength range and the green wavelength range by the color selective polarization converter 49a and the cutoff wavelength between the green wavelength range and the blue wavelength range are red by the color selective polarization converter 5a. It substantially matches the cutoff wavelength between the wavelength range and the green wavelength range, and the cutoff wavelength between the green wavelength range and the blue wavelength range by the color selective polarization converter 5b. The dichroic mirror 48b has a function of transmitting the combined light of the incident red light and green light, reflecting the incident blue light, and combining these lights. The dichroic mirror 48b has spectral characteristics almost opposite to those of the dichroic mirror 41b.
[0087]
That is, the dichroic mirror 48b has a color-selective polarization converter 49a in a wavelength region between the cutoff wavelength for P-polarized light and the cutoff wavelength for S-polarized light having an incident angle of 45 degrees that is a set angle with respect to the main optical axis. Are set so as to include the cutoff wavelength. Thereby, it is possible to combine light while suppressing the influence of the incident angle dependency of the dichroic mirror 48b. As described above, the spectral characteristics of the dichroic optical element on the color combining side composed of the dichroic mirrors 48a and 48b are substantially opposite to the spectral characteristics of the dichroic optical element on the color separation side composed of the dichroic mirrors 41a and 41b.
[0088]
The light synthesized by the dichroic mirror 48b enters the color selective polarization converter 49b. Here, the light incident on the color selective polarization converter 49b is P-polarized in the yellow wavelength range (red wavelength range and green wavelength range) with respect to the incident surface of the color selective polarization converter 49b, and is in the blue wavelength range. Is S-polarized light. The color selective polarization converter 49b rotates only the polarization plane in the blue wavelength region by 90 degrees. Thereby, the polarization direction of the light to be projected is aligned. As described above, the conversion characteristics of the color selective polarization converters 49a and 49b on the color combining side match or correspond to the conversion characteristics of the color selective polarization converters 5a and 5b on the color separation side. The light emitted from the color selective polarization converter 49b is projected onto a projection surface such as a screen (not shown) by the projection lens 18.
[0089]
As described above, according to the second embodiment, the color-selective polarization converter 5a provided in the front stage of the dichroic mirror 41a receives linearly polarized light and out of the light incident on the dichroic mirror 41a, green light and blue light The green and blue wavelength regions of the input linearly polarized light are rotated by 90 degrees so that the light is P-polarized light with respect to the color separation surface of the dichroic mirror 41a and the red light is S-polarized light with respect to the color separation surface. Further, the color selective polarization converter 5b provided at the front stage of the dichroic mirror 41b converts blue light into P-polarized light with respect to the color separation surface of the dichroic mirror 41b and color separation of green light. The green wavelength region of the input light is rotated by 90 degrees so as to be S-polarized light with respect to the surface. Thereby, the green light and the blue light are more easily transmitted through the dichroic mirror 41a, and the red light is more easily reflected by the dichroic mirror 41a. Further, blue light is more easily transmitted by the dichroic mirror 41b, and green light is more easily reflected by the dichroic mirror 41b. For this reason, it is possible to reduce the color mixture of the separated light while suppressing the loss of light energy, and to improve the color purity of each separated light. Further, the color selective polarization converter 49a receives the combined light obtained by combining the polarized lights in a plurality of wavelength regions, and changes the polarization surface in the green wavelength region so that the emitted light becomes P polarized light with respect to the color combining surface of the dichroic mirror 48b. It is rotated and injected. Thereby, the influence of the incident angle dependence of the dichroic mirror 48b can be reduced, and the light utilization efficiency can be improved.
[0090]
The light incident on the color selective polarization converter 49a is a combined light of S-polarized red light and P-polarized green light with respect to the color combining surface of the dichroic mirror 48b, and the color selective polarization converter 49a is green. The light is converted to S-polarized light so that the combined light is aligned with S-polarized light, and the dichroic mirror 48b reflects the light from the color-selective polarization converter 49a, transmits blue light, and combines these lights. Needless to say, the same effects as described above can be obtained.
[0091]
(Embodiment 3)
Embodiment 3 of the present invention uses a reflective panel as a color modulation device. FIG. 17 is a plan view showing the configuration of the projector according to the third embodiment of the invention. In addition, about the part of the same structure as FIG. 1, the same code | symbol is attached | subjected and the description is abbreviate | omitted. This projector includes a light source 1, a uniform illumination optical system 19, reflection mirrors 51 a and 51 b, an incident side polarizing plate 52, color selective polarization converters 5 and 57, and color as color separation means and color composition means. Separating / combining prisms 53a, 53b and 53d, a λ / 2 phase difference plate 55, reflective panels 56a, 56b and 56c, an exit-side polarizing plate 58, and a projection lens 18 are provided.
[0092]
The light emitted from the superimposing lens 4 in the same manner as in the first embodiment is reflected by the reflection mirrors 51a and 51b, and the degree of polarization is increased by the incident side polarizing plate 52, and then the color selective polarization converter 5 is used. Is incident on. The color selective polarization converter 5 rotates only the polarization plane in the green wavelength region by 90 degrees. Thereby, the color selective polarization converter 5 makes green light of the light incident on the color separation / combination prism 53 P-polarized light with respect to the color separation / combination surface of the color separation / combination prism 53, and red light and blue light are color-separated. The polarization is controlled so as to be S-polarized light with respect to the color separation / synthesis surface of the synthesis prism 53. If the degree of polarization of light emitted from the uniform illumination optical system 19 is sufficiently high, the polarizing plate 52 can be omitted.
[0093]
The color separation / combination prism 53 is a combination of triangular prisms 53a and 53b and a prismatic prism 53c, and the light emitted from the color selective polarization converter 5 is divided into three colors, blue, green and red. It has a function of separating into colored lights and a function of synthesizing each colored light emitted after being modulated by the reflective panels 56a, 56b and 56c. The green light component incident on the color separation / combination prism 53 is transmitted, and the red-green light component and the blue component are reflected. The characteristics of the dichroic optical films 54a and 54b are such that the color-selective polarization converter 5 has a wavelength range between the cutoff wavelength for P-polarized light and the cutoff wavelength for S-polarized light having an incident angle set to the main optical axis. The cutoff wavelength is set to be included. Thereby, it is possible to separate and combine light while suppressing the influence of the incident angle dependency of the color separation / combination prism 53.
[0094]
The red light is reflected by the dichroic optical film 54a for reflecting blue light. This is because the incident angle of red light is increased, and this incident angle satisfies the total reflection condition of the dichroic optical film 54a. The green light transmitted through the color separation / combination prism 53 is rotated by 90 ° by the λ / 2 phase difference plate 55 to become S-polarized light, and reaches the green light reflection type panel 56c. On the other hand, the blue light and red light reflected by the color separation / combination prism 53 reach the blue light reflection panel 56a and the red light reflection panel 56b, respectively. The three reflective panels 56a, 56b, and 56c have a function as a light modulation device that modulates incident light in accordance with given image information (image signal). In this embodiment, a micro mirror type modulation device that modulates the angle of the emitted light by changing the angle of the mirror is used as the reflection type panel as a pixel. As such a modulation device, DMD (registered trademark of Texas Instruments Inc.) is known.
[0095]
Each color light incident on the three reflective panels 56a, 56b and 56c is modulated in accordance with given image information. The blue modulated light and red modulated light emitted from the reflective panels 56 a and 56 b are incident on the color separation / combination prism 53 as S-polarized light with respect to the color separation / combination surface of the color separation / combination prism 53. The green modulated light emitted from the reflective panel 56 c is rotated by 90 ° by the λ / 2 phase difference plate 55, and the color separation / combination prism is P-polarized light with respect to the color separation / combination surface of the color separation / combination prism 53. 53 is incident.
[0096]
Of each color light incident on the color separation / combination prism 53, the modulated light, that is, the light related to the projected image is synthesized to form synthesized light for projecting the color image. The combined light generated by the color separation / combination prism 53 is emitted in the direction of the projection lens 18. On the other hand, light that has not been modulated, that is, light that is not related to the projected image is reflected by the reflective panels 56a, 56b, and 56c and then returns to the incident direction, so that it is not emitted in the direction of the projection lens 18. . The light synthesized by the color separation / combination prism 53 enters the color selective polarization converter 57. Here, the light incident on the color selective polarization converter 57 is S-polarized in the blue wavelength range and red wavelength range and P-polarized in the green wavelength range with respect to the incident surface of the color selective polarization converter 57. ing.
[0097]
The color selective polarization converter 57 rotates only the polarization plane in the green wavelength region by 90 degrees. Thereby, the polarization direction of the light to be projected is aligned. The conversion characteristics of the color-selective polarization converter 57 on the color composition side substantially match the conversion characteristics of the color-selective polarization converter 5 on the color separation side. The light emitted from the color selective polarization converter 57 passes through the emission side polarizing plate 58 and reaches the projection lens 18. The projection lens 18 displays a color image on a projection surface such as a screen (not shown). As described above, according to the third embodiment, even when the reflective panels 56a, 56b, and 56c are used, the influence of the incident angle dependency of the color separation / synthesis optical system is reduced, and the loss of light energy is suppressed. The color mixture of the separated light can be reduced and the color purity of each separated light can be improved. In this example, the case where the reflective panels 56a, 56b and 56c are DMDs has been described. However, these may be reflective liquid crystal panels. In this case, light not related to the projected image reflected by the reflective panel is absorbed by the exit-side polarizing plate 58.
[0098]
In the above-described first to third embodiments, the projector has been described as an example. However, the above-described configuration can be applied to other devices such as a digital camera, a video camera, and a TV camera using 3 CCDs, for example. And similar effects can be obtained. The projector includes a front projector that projects an image from the direction of observing the projection surface and a rear projector that projects an image from the opposite side to the direction of observing the projection surface. The configuration of 3 can be applied to any projector.
[0099]
Moreover, the blue wavelength range, the green wavelength range, and the red wavelength range described above are not particularly limited. For example, the blue wavelength range is 400 nm to 500 nm, the green wavelength range is 500 nm to 600 nm, and the red wavelength range is 600 nm to 700 nm. It is good. Further, it may be separated into three wavelength bands of red, orange and cyan. Further, it may be separated into four colors of red, orange, green and blue, or a wavelength range of many more colors. In this way, when separating into multiple color wavelength ranges, transmissive liquid crystal panels or reflective panels for multiple colors are provided, color selective polarization converters, dichroic optical elements that separate light, and light synthesis A plurality of dichroic optical elements are provided, and rotation conversion of the polarization plane, light separation, and light synthesis are performed in a plurality of stages.
[0100]
【The invention's effect】
As described above, according to the present invention, it is possible to reduce the influence of the incident angle dependency by utilizing the polarization dependency of the spectral characteristics of the color separation unit and the color synthesis unit. Therefore, in the color separation means, it is possible to improve the characteristics of both the light to be reflected and the light to be transmitted, so that the loss of both the light to be reflected and the light to be transmitted is suppressed, Color mixing can be prevented, and the color purity of each separated light can be improved. Further, in the color composition means, it is possible to prevent loss of light to be reflected and light to be transmitted, and the light use efficiency in color composition can be improved. Therefore, when such color separation means and color composition means are used in an optical device such as a projector, it is possible to improve the color reproducibility of the image, reduce color unevenness, and improve brightness.
[Brief description of the drawings]
FIG. 1 is a plan view showing a schematic configuration of a projector according to a first embodiment of the invention.
2 is a plan view showing a schematic configuration of a light source and a uniform illumination optical system shown in FIG. 1. FIG.
FIGS. 3A and 3B are a front view and a side view showing a schematic configuration of the lens array shown in FIG.
4 is a perspective view showing a schematic configuration of the polarization conversion element array shown in FIG. 2; FIG.
FIG. 5 is an explanatory diagram for explaining the principle of polarization conversion of the polarization conversion element array according to the first embodiment;
6 is an explanatory diagram showing a schematic configuration of the light shielding plate shown in FIG. 2. FIG.
FIG. 7 is an explanatory diagram for explaining conversion by the color selective polarization converter according to the first embodiment;
FIGS. 8A and 8B are diagrams showing spectral characteristics of a general dichroic mirror with respect to P-polarized light and S-polarized light.
9A and 9B are diagrams showing spectral characteristics of other general dichroic mirrors with respect to P-polarized light and S-polarized light.
10A and 10B are diagrams illustrating spectral characteristics of the cross dichroic prism according to the first embodiment with respect to P-polarized light and S-polarized light.
FIG. 11 is an explanatory diagram for explaining the transmission of green light by the cross dichroic prism according to the first embodiment;
12 is an explanatory diagram for explaining reflection of blue light and red light by the cross dichroic prism according to the first embodiment; FIG.
FIG. 13 is a plan view showing a configuration of another projector according to the first embodiment.
FIG. 14 is a plan view showing a configuration of still another projector according to the first embodiment.
FIG. 15 is a plan view showing a configuration of still another projector according to the first embodiment.
FIG. 16 is a plan view showing a configuration of a projector according to a second embodiment of the invention.
FIG. 17 is a plan view showing a configuration of a projector according to a third embodiment of the invention.
FIG. 18 is a plan view showing a configuration of a conventional projector.
FIG. 19 is an explanatory view for explaining the incidence of light on the dichroic mirror shown in FIG.
FIG. 20 is a diagram showing the incident angle dependence of spectral characteristics of a conventional dichroic mirror.
FIG. 21 is an explanatory diagram for explaining color separation by a conventional dichroic mirror.
[Explanation of symbols]
1 Light source
1a Light source lamp
1b Concave mirror
2,21 Lens array
2a, 21a Small lens
4 Superimposing lens
5, 5a, 5b, 49a, 49b, 57 Color selective polarization converter
6,17 Cross dichroic prism
7a, 7b, 9a, 9b, 11a, 11b, 11c Lens
8a, 8b, 10a, 10b, 42a, 42b, 51a, 51b Reflective mirror
12a, 12b, 16, 25, 43a, 43c, 47a, 55 λ / 2 phase difference plate
13a, 13b, 13c, 44a, 44b, 44c, 52 Incident-side polarizing plate
14a, 14b, 14c, 45a, 45b, 45c transmissive liquid crystal panel
15a, 15b, 15c, 46a, 46b, 46c, 58 Exit side polarizing plate
18, 18a, 18b, 18c Projection lens
19 Uniform illumination optical system
20 Partial luminous flux
22 Shading plate
22a opening
23, 23a, 23b Polarization conversion element array
24 Polarizing beam splitter array
26 Translucent member
27 Polarized light separation membrane
28 Reflective film
29 Polarization conversion element
31 Cross dichroic mirror
32, 33, 41a, 41b, 48a, 48b Dichroic mirror
53a, 53b, 53c Color separation / combination prism
54a, 54b Dichroic optical film
56a, 56b, 56c reflective panel

Claims (15)

Color separation means for transmitting light in a predetermined wavelength range, reflecting light in other wavelength ranges, and separating the light into a plurality of wavelength ranges;
By rotating the polarization plane of the predetermined wavelength range or the other wavelength range, out of the light incident on the color separation means, the light of the predetermined wavelength range is P-polarized light with respect to the color separation plane of the color separation means, Color selective polarization conversion means for making light in the other wavelength range S-polarized light with respect to the color separation surface;
Equipped with,
The color separation device, wherein the light in the predetermined wavelength region and the light in the other wavelength region are incident on the color separation unit and separated by the color separation unit.   The polarization boundary wavelength that divides the polarization plane rotation wavelength range and the polarization plane non-rotation wavelength range of the color selective polarization conversion means is between the cutoff wavelength for S-polarized light and the cutoff wavelength for P-polarized light of the color separation means. The color separation device according to claim 1, wherein the color separation device is included in a wavelength region. A color synthesizing unit that transmits light in the first wavelength band, reflects light in a second wavelength band different from the first wavelength band, and combines these lights;
Color selection for converting S-polarized light with respect to the color synthesis surface of the color synthesis unit into P-polarized light out of the light in the first wavelength range or the light in the second wavelength range incident on the color synthesis unit Polarization conversion means,
Equipped with,
The color synthesizing apparatus according to claim 1, wherein the light in the first wavelength range and the light in the second wavelength range are incident on the color synthesizing unit and synthesized by the color synthesizing unit.   The polarization boundary wavelength that separates the polarization plane rotation wavelength range and the polarization plane non-rotation wavelength range of the color selective polarization conversion means is between the cutoff wavelength for S-polarized light and the cutoff wavelength for P-polarized light of the color synthesis means. The color composition device according to claim 3, wherein the color composition device is included in a wavelength range. A color separation device according to claim 1 or 2,
A color synthesizing unit that synthesizes light separated by the color separating unit, having a cutoff wavelength that substantially matches the color separating unit;
A color separation / synthesis apparatus characterized by comprising: A color separation device according to claim 1 or 2,
A color composition device according to claim 3 or 4,
Comprising
The color separation / synthesis apparatus characterized in that the color synthesis means synthesizes the light separated by the color separation apparatus. A color separation device according to claim 1 or 2 ,
Color synthesizing means for synthesizing the separated light by the color separation device ,
The color synthesizing means, the color separating and synthesizing apparatus, wherein the color separation device is in the color separation means comprises. In a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image
The color separation device according to claim 1 or 2, which separates light from the light source;
Light modulating means for modulating the light separated by the color separation device;
A projector comprising: In a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image
A light modulating means for modulating the separated light;
The color synthesizing device according to claim 3 or 4, which synthesizes the light modulated by the light modulation means;
A projector comprising: In a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image
The color separation / synthesis apparatus according to claim 5 or 6,
A light modulation means for modulating the light separated by the color separation device, provided in a subsequent stage of the color separation apparatus and in the previous stage of the color synthesis means or the color synthesis apparatus;
A projector comprising: In a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image
A color separation / synthesis apparatus according to claim 7;
Light modulating means for modulating the light separated by the color separation device;
Comprising
A projector characterized in that the light modulated by the light modulation means is synthesized by the color separation means provided in the color separation device. In a projector that separates light from a light source, modulates the separated light to generate an image, and projects the image
First transmits light in a wavelength region, the first wavelength region longer wavelength third compared to the light and the first wavelength range of the second wavelength region shorter wavelength than the wavelength region Color separation means for reflecting the light and separating the light into three wavelength ranges;
Polarization conversion means for converting light from the light source into linearly polarized light;
By the polarization converting means rotates the polarization plane of the front Symbol first wavelength region light and the second wavelength region light and the third wavelength region of the light of the linearly polarized light is converted, the color Of the light incident on the separation means, the light in the first wavelength range is P-polarized light with respect to the color separation surface of the color separation means, and the light in the second wavelength range and the light in the third wavelength range are A color-selective polarization conversion means for making S-polarized light with respect to the color separation surface;
Three modulation means for modulating the light separated by the color separation means;
Equipped with,
The projector according to claim 1, wherein the light in the first wavelength band, the light in the second wavelength band, and the light in the third wavelength band are incident on the color separation means and separated by the color separation means .   The polarization boundary wavelength that divides the polarization plane rotation wavelength range and the polarization plane non-rotation wavelength range of the color selective polarization conversion means is between the cutoff wavelength for S-polarized light and the cutoff wavelength for P-polarized light of the color separation means. The color separation device according to claim 12, wherein the color separation device is included in a wavelength range.   14. The projector according to claim 12, wherein a cross dichroic prism or a cross dichroic mirror is provided as the color separation means. Before SL has a cutoff wavelength color separation means substantially coincides projector according to claim 12, 13 or 14, characterized in that it comprises a color combining means for combining the light which the light modulating means is modulated.

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