JP4855779B2 - Video display device - Google Patents

Description

   The present invention relates to a display device for projecting an image on a screen using a light valve element such as a liquid crystal panel or a reflective liquid crystal display device, for example, a liquid crystal projector device, a reflective video display projector device, a liquid crystal television, a projection type The present invention relates to a video display device such as a display device.

  2. Description of the Related Art There is known a projection display apparatus such as a liquid crystal projector that projects light on a light valve element such as a light bulb by irradiating light from a light source such as a light bulb. This type of video display device adjusts light from a light source by changing it to light and dark for each pixel with a light valve element, and projects it onto a screen or the like. For example, a twisted nematic (TN) type liquid crystal display element, which is a typical example of a liquid crystal display element, has a polarization direction before and after a liquid crystal cell formed by injecting liquid crystal between a pair of transparent substrates having a transparent electrode film. The two polarizing plates are arranged so that their angles are different from each other by 90 °. By combining the action of rotating the polarization plane by the electro-optic effect of the liquid crystal and the action of selecting the polarization component of the polarizing plate, Image information is displayed by controlling the amount of transmitted light. In recent years, in such a transmissive or reflective video display element, the element itself has been miniaturized and the performance such as resolution has been rapidly improved.

  For this reason, the display device using the light valve element such as the video display element has been improved in size and performance, and not only performs video display by a video signal as in the prior art, but also as an image output device of a personal computer. A projection-type image display device has also been newly proposed. This type of projection-type image display device is particularly required to be small in size and to obtain bright images at every corner of the screen. However, the conventional projection-type video display device has a problem that it is large-sized or has insufficient performance such as brightness and image quality of the finally obtained image.

  For example, miniaturization of the light valve element, that is, the liquid crystal display element itself, is effective for miniaturization of the entire liquid crystal display device. The ratio of the luminous flux on the liquid crystal display element to the total luminous flux emitted from the light source (hereinafter referred to as light utilization efficiency) is reduced because the illuminated area by the illumination means for all luminous flux is reduced, and Problems such as a dark screen periphery occur. Furthermore, since the liquid crystal display element can use only polarized light in one direction, about half of the light from the light source that emits randomly polarized light is not used. As an optical system for irradiating a liquid crystal display element with randomly polarized light from a light source aligned in one direction of polarization, a polarization conversion element such as a polarizing beam splitter as disclosed in JP-A-4-63318 is used. In some cases, random polarized light emitted from a light source is separated into P-polarized light and S-polarized light and synthesized using a prism.

  In addition, in this case, in the conventional optical system, particularly in the illumination optical system using the reflective liquid crystal display device, the polarizing beam splitter and the reflective liquid crystal display element are combined to turn on and off the image and the gradation. The light is analyzed by changing the polarization direction according to the expression, and then the image is projected onto the screen by the projection lens. In this case, color unevenness and contrast reduction become a problem due to the polarization beam splitter. That is, since the characteristics of the transmittance of the P-polarized light and the reflectance of the S-polarized light with respect to the incident angle of light change, the transmittance and reflectance unevenness of the polarizing beam splitter occur with respect to the light at a predetermined angle of the illumination optical system. . As a result, the image quality projected on the screen is degraded.

  A transparent material sandwiching a PB film as disclosed in Japanese Patent Application Laid-Open No. 09-054213 (Patent Document 1) is made of a glass material having an absolute value of photoelastic coefficient of 1.5 × 10 −8 cm 2 / N or less. Some of the polarizing beam splitters using the polarizing beam splitter reduce the birefringence in the polarizing beam splitter glass material and improve the contrast on the screen. However, in the present invention, the polarizing beam splitter glass material itself is heavy (approximately twice or more as compared with the conventional one) and the cost is increased, so it is desired to reduce the number of use. However, other than the embodiment of the present invention, the general optical system uses three polarization beam splitters for each of RGB three reflective panels, so that the size, weight and cost of the optical system can be reduced. Is not considered.

  In an optical system using a reflective liquid crystal display element, etc., a dichroic prism or dichroic mirror with a dichroic coat applied to the color separation / combination system is used, and light is emitted depending on the polarization direction when entering and exiting the color separation / combination system. Is changing the direction. It is known that the characteristics of a dichroic coat change depending on the polarization direction of incident light. That is, there is a difference in the wavelength band to be separated between P-polarized light and S-polarized light. More specifically, on the dichroic blue reflecting surface, the half-value wavelength of the P-polarized incident light is lower than that of the S-polarized incident light. In this case, light incident as S-polarized light is separated into reflected light and transmitted light according to the S-polarized half-value wavelength λs of the blue reflective coating surface. When the image information is white, the light is converted into P-polarized light by the blue reflective liquid crystal display element and re-incident on the blue reflective coating surface. This time, the light is separated into reflected light and transmitted light according to the P-polarized half-value wavelength λp. At this time, there is a wavelength band that is transmitted without being reflected because the half-value wavelength is lower. Since the light in the transmitted wavelength band cannot be used in the video display device, the light of the half-value wavelength difference is lost, and the brightness is reduced and the color performance is deteriorated. The same thing happens on the red reflecting surface.

  Therefore, it is impossible to use light corresponding to the shift of the wavelength band. As a result, the video display device has a problem of a decrease in light utilization efficiency and a decrease in chromaticity performance. In addition, contrast is one of the important performances of an image display device, but in order to improve contrast, between the illumination system and the polarizing beam splitter, and / or between the polarizing beam splitter and the projection lens, Inserting a polarizing plate is effective, but in the conventional configuration, all red, green, and blue light passes through the polarizing plate, resulting in an increase in the temperature of the polarizing plate, a decrease in contrast, and polarization. There was a problem such as burning of the board. From the above, it is necessary to take measures from the viewpoint of reducing the size, weight, and cost of the optical system and the projection type video display device itself while maintaining the brightness and image quality of the video display device.

JP 09-054213 A

  In the above prior arts, there is a problem of a method for realizing size reduction, weight reduction, and cost reduction of the device itself while ensuring the brightness and image quality performance of the video display device. That is, in order to ensure brightness, improve contrast, reduce the size of the device itself, reduce weight, and reduce costs, the light efficiency of the dichroic prism, which is a polarization beam splitter and color separation / combination means, is improved, and the light enters and exits the reflective panel. In order to achieve this, it is necessary to devise a method for efficient arrangement of each of them.

  An object of the present invention is to provide a video display technique that can ensure brightness and high image quality performance at a small size and low cost with respect to the above-described problems in the prior art.

  One aspect of the present invention provides a light source, a color separation unit that separates light emitted from the light source into first and second light, and third light, and the first light and the second light. A first color separation / synthesis unit that performs color separation / synthesis, and a first color separation / synthesis unit that is disposed substantially perpendicular to the first color separation / synthesis unit and separated by the first color separation / synthesis unit. In the vicinity of the first and second reflective liquid crystal display elements into which each light is incident, a second color separation / synthesis unit for performing color separation / synthesis of the third light, and the second color separation / synthesis unit A third reflective liquid crystal display element that is arranged and receives the third light separated by the second color separation / combination unit, and emits light from the first, second, and third reflective liquid crystal display elements A color combining unit that combines the first, second, and third lights, and a projection unit that receives the light combined by the color combining unit.

  According to the present invention, a reduction in size and weight can be achieved, and performance can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings using some examples.

  FIG. 1 is a schematic plan view showing a first embodiment of a projection type liquid crystal display device according to the present invention. The embodiment of FIG. 1 uses a reflective liquid crystal display element 2 as a liquid crystal light valve for a total of three corresponding to three so-called three primary colors R (red), G (green), and B (blue). 3 shows a three-plate projection display device. In FIG. 1, the projection type liquid crystal display device has a light source 1, which is a white lamp such as an ultra-high pressure mercury lamp, a metal halide lamp, a xenon lamp, a mercury xenon lamp, or a halogen lamp. The light source 1 includes at least one reflecting surface mirror 5 having a circular or polygonal exit aperture, and light emitted from the light source 1 passes through a liquid crystal display element 2 that is a light valve element and travels toward a projection lens 3, and is then screen 4. Is projected to.

  Light emitted from the light bulb of the light source 1 is collected by an elliptical, parabolic, or aspherical reflector 5 and is provided in a plurality of rectangular frames having substantially the same size as the exit aperture of the reflecting mirror reflector 5. Consists of a condensing lens, condenses the light emitted from the lamp unit, is incident on the first array lens 6 for forming a plurality of secondary light source images, and further comprises a plurality of condensing lenses, It passes through the second array lens 7 which is disposed in the vicinity of the plurality of secondary light source images and forms the individual lens images of the first array lens 6 on the liquid crystal display element 2. The emitted light is incident on a row of rhombus prisms of approximately ½ size of each lens width arranged so as to conform to the lateral pitch of each lens optical axis of the second array lens 7. The prism surface is provided with a polarizing beam splitter 8. The incident light is separated into P-polarized light and S-polarized light by the polarizing beam splitter 8. The P-polarized light passes through the polarization beam splitter 8 as it is, and the polarization direction is rotated by 90 ° by the λ / 2 wavelength plate 9 provided on the exit surface of the prism, and is converted into S-polarized light and emitted. . On the other hand, the S-polarized light is reflected by the polarization beam splitter 8, reflected once again in the original optical axis direction in the adjacent rhomboid prism, and then emitted as S-polarized light. The emitted light is incident on the collimator lens 10.

  In a projection type liquid crystal display device using a conventional reflective liquid crystal display element, the amount of reflected light is reduced by about half because only one direction of polarized light is reflected by the combination of the incident polarizing plate and the reflective liquid crystal display element. However, since the polarization beam splitter 8 is used, the polarization direction of the randomly polarized light emitted from the light source 1 is aligned and incident on the reflective liquid crystal display element 2, so that it is ideally twice that of a conventional projection liquid crystal display device. Can be obtained. The array lenses 6 and 7 act so that individual images of the lens cells overlap the liquid crystal display element 2 and uniform image quality is obtained.

  The collimator lens 10 has at least one configuration, has a positive refractive power, and has a function of further condensing the S-polarized light. The light that has passed through the collimator lens 10 is reflected by the mirrors 11 and 12. The optical axis direction is converted by 90 ° in a predetermined direction. Thereafter, the light passes through the condenser lens 30 and irradiates the three reflective liquid crystal display elements 2R, 2G, and 2B of each color RGB. First, the color separation mirror 13 or a color separation prism (not shown) The light is divided into R and B light and is incident on polarization beam splitters 16G and 16RB which are polarization separation / combination elements dedicated to the respective colors. That is, the G light is incident on the G-dedicated polarization beam splitter 16G according to the present invention, and is then S-polarized light, so that it is reflected toward the G-dedicated reflective liquid crystal display element 2G side and irradiates this panel. Further, the B light and the R light pass through the B-R light-dedicated polarizing plate 14, enter the RB-dedicated polarizing beam splitter 16RB according to the present invention, and then change the polarization direction only in a specific wavelength region. For example, the B light, which is the P-polarized light whose polarization has been converted, is converted from the S-polarized light to the P-polarized light after passing through the element 17. The beam passes through the beam splitter 16RB and irradiates the B-type reflective liquid crystal display element 2B. On the other hand, since the R light is S-polarized light, it is reflected by the RB-dedicated polarization beam splitter 16RB, and then irradiates the R-dedicated reflective liquid crystal display element 2R. Of course, the above example is one specific example, and the embodiment is not limited to this. R may be converted into P-polarized light, and apart from this, the polarized light of the original illumination system is P-polarized light. There is also a configuration in which one RGB color is converted to S-polarized light and the remaining two colors are P-polarized light. In addition, an RB-dedicated incident polarizing plate 14 and a G-dedicated incident polarizing plate 15 that transmit S-polarized light are arranged on the incident side of the reflective liquid crystal display elements 2R, 2G, and 2B dedicated to each color, and the degree of polarization of each color is increased. It is also possible to enhance the color purity by attaching the polarizing plate 14 to glass and applying a color adjusting film on the opposite side. Thereafter, the polarization is converted by the reflection type image display element 2 dedicated to each color, the light again enters the polarization beam splitters 16G and 16RB dedicated to each color, the S-polarized light is reflected, and the P-polarized light is transmitted.

  The reflective image display element 2 is provided with a number of liquid crystal display units corresponding to the pixels to be displayed (for example, 1024 horizontal pixels by 768 vertical pixels). Then, the polarization angle of each pixel of the liquid crystal display element 2 changes according to a signal driven from the outside, and finally light having a direction perpendicular to the incident polarization direction is emitted, and the light having the same polarization direction is polarized. The light is analyzed by the splitter 2. The amount of light passing through the polarizing beam splitter and the amount of light detected by the light having the polarized light at an intermediate angle are determined by the degree of polarization of the polarizing beam splitter 2. In this way, an image according to a signal input from the outside is projected. At this time, the polarization conversion elements of the G-dedicated polarization beam splitter 16G and the RB-dedicated polarization beam splitter 16RB according to the present invention have the polarization direction incident when the reflective image display elements 2R, 2G, and 2B perform black display. It is equivalent to light and is returned to the light source side as it is along the incident optical path. However, the detection efficiency, which is the degree of polarization and the extinction ratio of the polarizing beam splitter, slightly affects the performance, and slightly leaked or disturbed polarized light passes through the polarizing beam splitter and is emitted from the color synthesizing mirror 19 or the color on the output side. The light passes through the combining prism and is irradiated to the projection lens 20 side, and a slight brightness is detected on the screen during black display. As a result, the contrast performance may deteriorate.

  Naturally, the dielectric multilayer film constituting the polarization conversion element and the color separation / combination prism has the transmission efficiency or the reflection efficiency of the P-polarized light and the transmission efficiency of the S-polarized light with respect to light of a specific wavelength band incident thereon. Alternatively, the reflection efficiency, or the transmission efficiency or reflection efficiency for circularly polarized light has a peak value, and the dielectric multilayer film for exclusive use in a limited wavelength range is applied, for example, the G in the wavelength band from about 500 nm to about 600 nm. Dedicated G-polarized beam splitter 16G with an optimum dielectric multilayer film dedicated to light, dedicated to R light and B light in two or more wavelength bands from near 400 nm to near 500 nm and from near 600 nm to near 700 nm RB-specific polarization beam splitter 16RB with optimal dielectric multilayer coating applied to the dielectric multilayer coating It becomes easy, and transmission efficiency and the reflection efficiency, and even improved over conventional the test light efficiency. Therefore, it is possible to provide a reflective liquid crystal display device that realizes highly accurate color reproducibility, high brightness, high efficiency contrast, and the like. Furthermore, an image with higher uniformity and high color purity can be displayed by adding an inclined film, that is, a film in which the thickness of the dielectric multilayer film is changed depending on the incident angle of light.

  The light emitted from the polarization beam splitter 16RB is converted in the polarization direction of one of the R light and B light by the specific wavelength region polarization conversion element 18, and both the R light and B light are converted into, for example, S polarized light and applied to the dichroic mirror 19. Incident.

  Thereafter, the light of each color of RGB as the image is color-synthesized again by a color synthesis mirror 19 such as a dichroic mirror or a dichroic prism (not shown), and the light is a projection means (for example, a projection lens) such as a zoom lens. Pass through 20 and reach the screen. Images formed on the reflective liquid crystal display elements 2R, 2G, and 2B by the projection means 20 are enlarged and projected on a screen to function as a display device. In the reflection type liquid crystal display device using the three reflection type liquid crystal display elements, a power source 21 drives a lamp and a panel.

  Therefore, in the conventional reflection type liquid crystal display device, the light of the light source is separated into RGB three-color light by at least one or more color separation prisms or color separation mirrors, and then each RGB color is separated by at least three or more polarization beam splitters. Since the light was analyzed, and the three colors were synthesized by the color synthesis prism, and then the image was projected onto the screen by the projection lens, the overall device tends to be large, heavy, and expensive. It was. The configuration using two polarizing beamsplitters dedicated for G and RB according to the present invention can achieve a reduction in size and weight, and also can freely control color purity, further improve color unevenness and improve performance. It can be realized at the same time. Therefore, a compact, high-brightness, high-quality projection-type image display device can be realized. Furthermore, since the number of parts can be reduced, cost reduction can be achieved.

  FIG. 2 is a schematic plan view showing a second embodiment according to the present invention. The light is emitted from the reflection type image display elements 2R, 2G, and 2B, for example, the reflection type liquid crystal display element, the reflection type ferroelectric image display element, the driving micromirror image display element, or the like, and is output by the polarization beam splitter 16G and the polarization beam splitter 16RB. Light of each color of RGB, which is an image analyzed by a certain polarization separation / combination element, is color-combined again by the dichroic dichroic prism 19a, and the light passes through the projection means 20 such as a zoom lens, and is then screened. To reach. The images formed on the reflective liquid crystal display elements 2R, 2G, and 2B by the projection unit 20 are enlarged and projected on the screen to function as a display device. The prism 19a of the present invention has a size larger than that of the polarizing beam splitter so that light rays do not vignett, and has a configuration different from that of the polarizing beam splitter in order to reduce the overall configuration. . In addition, since the inclined film or the like can be set independently by dichroic coating, an image with high uniform color purity can be provided.

  Further, according to the configuration of the present invention, an optical element such as the dichroic prism 19a is provided on the housing with a support portion for the corner chamfered portion 29 and the like, and the corner chamfered portion 29 of the optical element is supported thereby, thereby the dichroic prism 19a. Such an optical element can be easily held and positioned, the assembling time in mass production can be shortened, and the cost of the entire projection display apparatus can be reduced. Further, by this chamfered portion 29, another optical member, for example, a lens or other optical element, which is generated in a space margin, is arranged, and mutual interference is avoided in the case of high density arrangement, and miniaturization can be achieved.

  FIG. 3 is a plan view showing a third embodiment according to the present invention. The illumination light passes through the condenser lens 30 and irradiates the reflective liquid crystal display elements 2R, 2G, and 2B of three colors RGB, first, the polarization direction of light in a predetermined wavelength band by the specific wavelength band polarization conversion element 28. Convert. In this case, if the illumination light is S-polarized light, it is converted to P-polarized light and separated into each color light by the broadband polarization beam splitter 16RGB. For example, when the polarized light of the G light is converted by the specific wavelength range polarization conversion element 28, the polarization beam splitter 16RGB divides the light into G light, R light, and B light, and a polarized light beam that is a polarization separation / combination element dedicated to each color The light enters the splitters 16G and 16RB. That is, the G light is converted into the polarization direction of the P-polarized light into the S-polarized light by the specific wavelength band polarization conversion element 27 and is incident on the G-dedicated polarization beam splitter 16G. The liquid crystal display element 2G is irradiated by being reflected toward the 2G side. Further, the B light and the R light pass through the B-R light-dedicated polarizing plate 14, enter the RB-dedicated polarization beam splitter 16RB, and then pass through the specific wavelength region polarization conversion element 17 that converts the polarization direction only in the specific wavelength region. Then, the polarization of either the B light or the R light is converted from S polarized light to P polarized light. For example, the B light that is P polarized light whose polarization has been converted is transmitted to the RB dedicated polarization beam splitter 16RB. Pass through and irradiate the B-type reflective liquid crystal display element 2B. On the other hand, since the R light is S-polarized light, it is reflected by the RB-dedicated polarization beam splitter 16RB, and then irradiates the R-dedicated reflective liquid crystal display element 2R.

  Of course, the above example is one specific example, and the embodiment is not limited to this. The R light may be converted into P-polarized light. Apart from this, the polarized light of the original illumination system is converted into P-polarized light. In this case, the configuration also holds when one color of RGB is converted to S-polarized light and the remaining two colors are P-polarized light. Further, an RB-dedicated incident polarizing plate 14 and a G-dedicated incident polarizing plate 15 that transmit S-polarized light are disposed on the incident side of the reflective liquid crystal display elements 2R, 2G, and 2B dedicated to each color, and the degree of polarization and / or color of each color is arranged. It is also possible to increase the purity. Thereafter, the polarization is converted by the reflection type image display element 2 dedicated to each color, the light again enters the polarization beam splitters 16G and 16RB dedicated to each color, the S-polarized light is reflected, and the P-polarized light is transmitted.

  The reflective image display element 2 is provided with a number of liquid crystal display units corresponding to the pixels to be displayed (for example, 1024 horizontal pixels by 768 vertical pixels). Then, the polarization angle of each pixel of the liquid crystal display element 2 changes according to a signal driven from the outside, and finally light having a direction perpendicular to the incident polarization direction is emitted, and the light having the same polarization direction is polarized. The light is analyzed by the splitter 16. The amount of light passing through the polarization beam splitter 16 and the amount of light detected by the light having polarization at an intermediate angle are determined by the relationship with the degree of polarization of the polarization beam splitter 16. In this way, an image according to a signal input from the outside is projected. At this time, the polarization conversion elements that are the G-dedicated polarization beam splitter 16G and the RB-dedicated polarization beam splitter 16RB have the same polarization direction as that of the incident light when the reflective image display elements 2R, 2G, and 2B perform black display. It is returned to the light source side along the incident optical path as it is. Thereafter, the light of each color of RGB, which is an image, is color-combined again by the dichroic mirror 19 or a dichroic prism (not shown), and the light passes through the projection means 20 such as a zoom lens and reaches the screen. . Images formed on the reflective liquid crystal display elements 2R, 2G, and 2B by the projection means 20 are enlarged and projected on a screen to function as a display device. In the reflection type liquid crystal display device using the three reflection type liquid crystal display elements, a power source 21 drives a lamp and a panel.

  Therefore, in the conventional reflection type liquid crystal display device, the light of the light source is separated into RGB three-color light by at least one or more color separation prisms or color separation mirrors, and then each RGB color is separated by at least three or more polarization beam splitters. Since the light was analyzed, and the three colors were synthesized by the color synthesis prism, and then the image was projected onto the screen by the projection lens, the overall device tends to be large, heavy, and expensive. It was. The configuration using two polarizing beamsplitters dedicated for G and RB according to the present invention can achieve miniaturization and weight reduction, and further can control color purity freely, further improve color unevenness and improve performance. It can be realized at the same time. In addition, since the color separation means is a combination of a polarization beam splitter and a specific wavelength region polarization conversion element, the influence of the angle dependency is small, so that the design of color performance is facilitated. Therefore, a compact, high-brightness, high-quality projection-type image display device can be realized. Furthermore, since the number of parts can be reduced, cost reduction can be achieved.

  FIG. 4 is a plan view showing a fourth embodiment of the present invention. In addition to the effects of the embodiment of FIG. 3, RGB is an image that is emitted from the reflective image display elements 2R, 2G, and 2B and analyzed by the polarization beam splitter / combining element that is the polarization beam splitter 16G and the polarization beam splitter 16RB. The light of each color is color synthesized again by the dichroic prism 19a, and the light passes through the projection means 20 and reaches the screen. The images formed on the reflective liquid crystal display elements 2R, 2G, and 2B by the projection unit 20 are enlarged and projected on the screen to function as a display device. The prism 19a of the present invention has a size larger than that of the polarizing beam splitter so that light rays do not vignett, and has a configuration different from that of the polarizing beam splitter in order to reduce the overall configuration. . In addition, since the inclined film or the like can be set independently by dichroic coating, an image with high uniform color purity can be displayed.

  Further, according to the configuration of the present invention, an optical element such as the dichroic prism 19a is provided on the housing with a support portion for the corner chamfered portion 29 and the like, and the corner chamfered portion 29 of the optical element is supported thereby, thereby the dichroic prism 19a. Such an optical element can be easily held and positioned, the assembling time in mass production can be shortened, and the cost of the entire projection display apparatus can be reduced. In addition, by this chamfered portion 29, another optical member generated and a polarization beam splitter 16RGB which is a polarization separation / combination element are disposed in a space margin, and avoiding mutual interference when arranged at high density, miniaturization is achieved. it can. FIG. 5 is a plan view showing a fifth embodiment of the image display apparatus according to the present invention, and particularly shows the configuration of the optical system.

  In FIG. 5, the video display device is provided with a light source unit including a light source 1 and a reflective reflector 2, and light emitted from the light source unit passes through a polarization rectifying element 31, for example, a polarizing plate or a polarizing beam splitter (PBS), The light rectified as P-polarized light is separated into G light (green light), R light (red light) and B light (blue light) by the green separation mirror 13. The separated G light is incident on the polarization beam splitter 16G, incident light that is P-polarized light is transmitted, is incident on the reflective liquid crystal display element 2G that is an image display element, and is subjected to polarization conversion corresponding to the image signal and reflected. Then, it enters the polarization beam splitter 16G again. The polarizing beam splitter 16G analyzes the incident light according to the amount of polarization conversion received by the reflective liquid crystal display element 2G, that is, reflects only the S-polarized component generated by the polarization conversion of the incident light. And get a video.

  The R light and B light separated by the green separation mirror 13 are converted into only S light by the specific wavelength region polarization conversion element 17 for converting the polarization direction of the specific wavelength region, and are incident on the polarization beam splitter 16RB. The The R light that is S-polarized light is reflected by the polarization beam splitter 16RB and enters the reflective liquid crystal display element 2R. The light incident on the reflective liquid crystal display element 2R undergoes polarization conversion according to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2R to obtain an image. The B light passes through the polarization beam splitter 16RB as P-polarized light and enters the reflective liquid crystal display element 2B. The light incident on the reflective liquid crystal display element 2B undergoes polarization conversion according to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2B to obtain an image.

  Although not shown in the figure, only the B light may be converted into S-polarized light by the specific wavelength region polarization conversion element 17 that converts the polarization direction of the specific wavelength region. At this time, the polarization-converted B light becomes S-polarized light and enters the polarization beam splitter 16RB. The B light that is S-polarized light is reflected by the polarization beam splitter 16RB and is incident on the reflective display element 2B. The light incident on the reflective liquid crystal display element 2B undergoes polarization conversion corresponding to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2B, and an image is obtained. The R light passes through the polarization beam splitter as P-polarized light, and is incident on the reflective liquid crystal display element 2R. The light incident on the reflective liquid crystal display element 2R undergoes polarization conversion corresponding to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2R to obtain an image.

  The obtained red, blue, and green images are synthesized by a color synthesis unit 19, for example, a dichroic mirror or a dichroic prism, and projected by a projection lens 20. At this time, if necessary, a specific wavelength region polarization conversion element 18 for converting the polarization direction of the specific wavelength region may be inserted on the exit side of the polarization beam splitter 16RB to align the polarization directions of the R light and the B light. Further, at this time, the polarizing screen can be used by setting the wavelength range for polarization conversion of the specific wavelength range polarization conversion element 18 so that the polarization directions of all the R light, G light, and B light are aligned.

  Alternatively, a polarization conversion element 32 that converts S-polarized light into P-polarized light is arranged for the light detected by the polarization beam splitter 16G in the optical path of G light, and P is applied to the color composition means 19 such as a color composition mirror. Polarized light in a specific wavelength range that changes the polarization direction of a specific wavelength range so that the polarization direction of one or both of R light and B light becomes S-polarized light in the red and B optical paths. The polarization conversion wavelength band of the conversion element 18 is set. Accordingly, it becomes possible to widen the transmission band of G light and to broaden the reflection band of one or both of R light and B light by the polarization characteristics of the dichroic mirror or dichroic coat which is the color synthesizing means 19.

  Furthermore, polarization rectifying elements 33, 34, and 35 such as polarizing plates may be arranged on the incident side and / or the exit side of the polarizing beam splitter 16G and / or the polarizing beam splitter 16RB. At this time, the polarization rectifying element 33 arranged before the incidence of the polarization beam splitter 16RB in the red and B optical paths is arranged before the incidence of the optical element 17 for converting the polarization direction of the specific wavelength region. Further, the polarization rectifying element 35 disposed after the incidence of the polarization beam splitter 16RB in the red and B light optical paths is disposed after the emission of the specific wavelength region polarization conversion element 18 that converts the polarization direction of the specific wavelength region. The configuration using two polarization beam splitters according to the present invention can achieve a reduction in size and weight, and can further freely control color purity and further improve color unevenness.

  FIG. 6 is a plan view showing a sixth embodiment of the video display apparatus according to the present invention, which shows the structure of the optical system. In FIG. 6, the video display device has a light source unit including a light source 1 and a reflective reflector 5, and the light source 1 is a white lamp. The light emitted from the light source unit passes through a polarization rectifying element 8 such as a polarizing plate, for example, a polarizing plate or a polarization conversion element (polarizing beam splitter), and the light rectified as S-polarized light is G light by the green separation mirror 13. Are separated into R light and B light. The separated G light is incident on the polarization beam splitter 16G, incident light that is S-polarized light is reflected, is incident on the reflective liquid crystal display element 2G that is an image display element, and is reflected by polarization conversion in accordance with the image signal. Then, it enters the polarization beam splitter 16G again. The polarization beam splitter 16G analyzes the incident light according to the polarization conversion amount received by the reflective liquid crystal display element 2G, that is, only the P-polarized component generated by the polarization conversion of the incident light. Reflect and get an image.

  The R light and B light separated by the green separation mirror 13 are converted into only P light by the specific wavelength region polarization conversion element 17 for converting the polarization direction of the specific wavelength region, and are incident on the polarization beam splitter 16RB. The R light, which is P-polarized light, is transmitted by the polarization beam splitter 16RB and is incident on the reflective liquid crystal display element 2R. The light incident on the reflective liquid crystal display element 2R undergoes polarization conversion according to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2R to obtain an image. The B light is reflected by the polarization beam splitter 16RB as S-polarized light and enters the reflective liquid crystal display element 2B. The light incident on the reflective liquid crystal display element 2B undergoes polarization conversion corresponding to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2B, and an image is obtained. Although not shown in the drawing, only the B light may be converted into P-polarized light by the specific wavelength region polarization conversion element 17 that converts the polarization direction of the specific wavelength region. At this time, the polarization-converted B light becomes P-polarized light and enters the polarization beam splitter 16RB. The polarization beam splitter 16RB transmits the B light, which is P-polarized light, and enters the reflective liquid crystal display element 2B. The light incident on the reflective liquid crystal display element 2B undergoes polarization conversion corresponding to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2B, and an image is obtained. Further, the R light is reflected as S-polarized light by the polarization beam splitter 16RB, and is incident on the reflective liquid crystal display element 2R. The light incident on the reflective liquid crystal display element 2R undergoes polarization conversion corresponding to the video signal, is reflected, and is incident again on the polarization beam splitter 16RB. In the polarization beam splitter 16RB, light is analyzed according to the amount of polarization conversion received by the reflective liquid crystal display element 2R to obtain an image.

  The obtained red, blue and green images are synthesized by a color synthesis means 19 such as a dichroic mirror or a dichroic prism and projected by a projection lens 20. At this time, if necessary, a specific wavelength region polarization conversion element 18 for converting the polarization direction of the specific wavelength region is inserted on the exit side of the polarization beam splitter 16RB, and the polarization directions of all of the R light, G light, and B light. By setting the wavelength range for polarization conversion of the specific wavelength range polarization conversion element 18 so as to be uniform, it is possible to use a polarizing screen.

  Alternatively, at this time, in the optical paths of the R light and the B light, the specific wavelength region polarization conversion element that converts the polarization direction of the specific wavelength region so that the polarization direction of one or both of the R light and the B light becomes S polarized light. 18 polarization conversion wavelength bands are set. As a result, the G light transmission band can be widened and the R light and B light reflection bands can be widened by the polarization characteristics of the dichroic mirror or dichroic coat as the color synthesizing means 19.

  Furthermore, the polarization rectifying elements 33, 34, and 35 may be disposed on the incident side or the exit side of the polarizing beam splitter 16G and the polarizing beam splitter 16RB. At this time, the polarization rectifying element 33 arranged before the incidence of the polarization beam splitter 16RB in the optical path of red and B light is arranged before the incidence of the specific wavelength band polarization conversion element 17 for converting the polarization direction of the specific wavelength band. In addition, the polarization rectifying element 35 disposed after the incidence of the polarization beam splitter 16RB in the optical path of the R light and the B light is disposed on the light exit side of the specific wavelength region polarization conversion element 18 that converts the polarization direction of the specific wavelength region. The configuration using two polarization beam splitters according to the present invention can achieve a reduction in size and weight, and can further freely control color purity and further improve color unevenness.

  FIG. 7 is a plan view showing a seventh embodiment of the projection display apparatus according to the present invention. In the embodiment of FIG. 7, the reflection type liquid crystal display elements 2R, 2G, and 2B as liquid crystal light valves are summed up corresponding to the three primary colors R (red), G (green), and B (blue). A three-plate projection display device using three sheets is shown. In the projection type liquid crystal display device of FIG. 7, the light source 1 is a white lamp. The light emitted from the light source 1 is reflected by at least one reflecting mirror 5 having a circular or polygonal exit aperture, passes through the liquid crystal display elements 2R, 2G, and 2B, which are light valve elements, toward the projection lens 20, and the screen. Is projected to.

  Between the polarizing beam splitter 8 and the reflective liquid crystal display element 2, a dichroic mirror 13 which is a color separation means that transmits or reflects only the G light out of the three primary colors R light, G light, and B light, or A dichroic prism or the like is disposed and separated from other R light and B light. The G light separated by the dichroic mirror 13 is transmitted or reflected by the polarization beam splitter 16G and is incident on the liquid crystal display element 2G. At this time, polarizing plates 15 and 29 having a polarization rectifying action on the G light may be arranged on the incident side and / or on the exit side of the polarizing beam splitter 16G. The light incident on the liquid crystal display element 2G is modulated and reflected as readout light and emitted, and the modulated light is detected by the polarization beam splitter 16G. Further, the R light and B light separated from the G light pass through a specific wavelength band polarization conversion element 17 that performs polarization conversion only on a band of a specific wavelength that is approximately 510 nm to 580 nm or less, and R light, or The polarization of any one of the B lights changes, and the polarization directions of the R and B lights are orthogonal. Thereafter, the light enters the polarizing beam splitter 16RB, and the R light and B light having different polarization directions are separated and enter the respective liquid crystal display elements 2R and 2B. At this time, a polarizing plate 14 having a polarization rectifying function may be disposed on the incident side of the specific wavelength band polarization conversion element 17. In addition, a specific wavelength region polarization conversion element 18 that performs polarization conversion only on a band of a specific wavelength that is greater than or less than a specific wavelength of approximately 510 nm to 580 nm may be disposed on the output side of the polarization beam splitter 28RB. Further, at this time, a polarizing plate 29 having a polarization rectifying action may be disposed on the emission side of the specific wavelength region polarization conversion element 18.

  The light incident on the liquid crystal display elements 2R and 2B is modulated and reflected by the liquid crystal display elements corresponding to the respective colors as readout light, and is reflected and emitted, and the modulated lights of the respective colors are respectively analyzed by the polarization beam splitter 16RB. The The detected R light, G light, and B light are combined by a dichroic mirror 19 or a dichroic prism that is a color combining filter, pass through the projection means 20, and reach the screen. At this time, the specific wavelength region polarization conversion element 18 is set so that light in the optical path that passes through the color synthesis filter becomes P-polarized light and light in the optical path that reflects the color synthesis filter becomes S-polarized light. Thus, the transmission and reflection bands of the color synthesis filter are widened, and a highly efficient optical system can be realized. The image formed on the liquid crystal display element 2 by the projection means 20 is enlarged and projected on the screen and functions as a display device. Further, since the polarizing plate is provided at the entrance and exit of the polarizing beam splitter, the contrast can be improved.

  The configuration using two polarizing beam splitters according to the present invention can achieve a reduction in size and weight, and can further freely control color purity, further improve color unevenness and the like, and can simultaneously improve performance. Therefore, a compact, high-brightness, high-quality projection-type image display device can be realized. Furthermore, since the number of parts can be reduced, cost reduction can be achieved.

  Hereinafter, an eighth embodiment of the optical engine according to the present invention will be described with reference to FIG. FIG. 8 is a schematic plan view showing an eighth embodiment of the optical engine used in the video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. In the figure, light from a light source (not shown) is converted into S-polarized light through a polarization conversion element 101 typified by a combination of a polarizing beam splitter prism and a half-wave plate, and S-polarized light. The light is emitted as S-polarized light as it is. As the polarization conversion element 101, an element that converts S-polarized light into P-polarized light may be used. In this embodiment, a case where P-polarized light is converted to S-polarized light by the polarization conversion element 101 will be described as an example.

  Of the S-polarized light that has passed through the polarization conversion element 101, the B light passes through the color separation mirror 102 such as a dichroic mirror, and the polarization conversion element such as a polarizing plate 103a and a 1 / 2λ wavelength plate (polarization specific wavelength region polarization conversion). 115 may pass through the color adjustment film 104a and enter the polarization beam splitter 105RGB. The polarizing plate 103a is used to remove P-polarized light mixed in addition to S-polarized light which is the original light. Details of the color adjustment film 104a will be described later. The B light, which is S-polarized light, is converted into S-polarized light by the polarization conversion element 115, then passes through the polarization beam splitter 105RGB, enters the total reflection prism 108, and is reflected there. The B light reflected by the total reflection prism 108 is incident on the reflective liquid crystal display element 107B through the quarter-wave plate, and the P-polarized light is converted into S-polarized light by the liquid crystal display element 107B, and is reflected by the total reflection prism 108 again. After that, the light is incident on a color combining polarization beam splitter (or dichroic prism) 105RGB, reflected there, and emitted to a projection lens (not shown). The ¼λ wavelength plate 106a is used mainly for aligning the polarization axis of the liquid crystal display element 107B with the polarization axis of the polarization beam splitter 105RGB and the illumination optical system.

  The R light and G light, which are S-polarized light reflected by the color separation mirror 102, are reflected by the reflection mirror 109, and enter the specific wavelength band polarization conversion element 112a through the polarizing plate 103b for removing the S-polarized light. Here, the R light is converted from S-polarized light to P-polarized light, and the G light remains as S-polarized light, passes through the color adjustment film 104b, and is incident on the polarization beam splitter 105RG for color separation / synthesis. The G light, which is S-polarized light, is reflected by the polarization beam splitter 105RG, passes through the ¼λ wavelength plate 106b, and is incident on the reflective liquid crystal display element 107G for G light, and the S-polarized light is reflected by the liquid crystal display element 107G. The light is converted into P-polarized light, reflected, and again incident on the polarization beam splitter 105RG as P-polarized light, passes therethrough, and enters the specific wavelength band polarization conversion element 112b.

  The R light converted into the P-polarized light is transmitted through the polarization beam splitter 105RG for color separation / synthesis, transmitted through the ¼λ wavelength plate 106c, and then incident on the reflective liquid crystal display element 107R for R light. P-polarized light is converted to S-polarized light by the display element 107R, reflected, and emitted as S-polarized light. The R light, which is S-polarized light, is reflected by the polarization beam splitter 105RG and is incident on the specific wavelength region polarization conversion element 112b. The specific wavelength region polarization conversion element 112b converts the S-polarized light of the R light into P-polarized light, and transmits the G light as P-polarized light. R light and G light, which are P-polarized light, are removed from the P-polarized light component contained in the R light and G light by the polarizing plate 103c in order to prevent the deterioration of contrast, and then the polarization beam splitter for color synthesis ( (Or dichroic prism) 105 RGB. R light and G light, which are P-polarized light, are transmitted through the polarizing beam splitter (or dichroic prism 105RGB), and B light, which is S-polarized light, is reflected by the polarizing beam splitter (or dichroic prism) 105RGB to be a projection lens (not shown). The P-polarized light component mixed in the B light is not reflected by the polarizing beam splitter 105RGB but is transmitted therethrough, so that the P-polarized light component is not incident on the projection lens.

  In the embodiment of FIG. 8, the light incident on the color separation mirror 102 is converted to S-polarized light, but it may be configured to use light converted to P-polarized light. The specific wavelength region polarization conversion element 112a converts R light from S polarized light to P polarized light, but may be configured to convert G light to P polarized light. As the color adjustment film 104, for example, a dielectric multilayer film is directly deposited on a polarizing beam splitter or a dichroic prism, or a dielectric multilayer film is deposited on a polarizing plate or a glass plate attached to a half-wave plate. A polarizing beam splitter, a dichroic mirror attached to a dichroic mirror, a color filter such as a color film or colored glass, and the like can be applied as long as it can reduce the transmittance in a specific wavelength region.

  In the present embodiment, the total reflection prism 108 is not necessarily required, and may be disposed facing the B light emission surface of the color combining polarization beam splitter 105RGB. However, by providing the total reflection prism 108 as in the present embodiment, the height of the optical path of each R, G, B light can be made uniform, so that the efficiency of each color light is good and the contrast is made suitable. be able to.

  The ninth embodiment of the optical engine according to the present invention will be described below with reference to FIG. FIG. 9 is a schematic plan view showing a ninth embodiment of the optical engine used in the video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. In the figure, light from a light source (not shown) is converted into S-polarized light through a polarization conversion element (not shown) represented by a combination of a polarizing beam splitter prism and a half-wave plate. The S-polarized light is emitted as S-polarized light as it is.

  In FIG. 9, G light passes through the color separation mirror 102, P-polarized light contained in the S-polarized light component is removed by the polarizing plate 103 a, converted into P-polarized light by the polarization conversion element 115, and then polarized. The light passes through the beam splitter 105RGB, is reflected by the total reflection mirror 108, and enters the liquid crystal display element 107G for G light through the ¼λ wavelength plate 106a. The G light incident on the liquid crystal display element 107G is converted into S-polarized light here, passes through the ¼λ wavelength plate 106a again, is reflected by the total reflection prism 108, and enters the polarization beam splitter 105RGB. Since the G light is S-polarized light, it is now reflected by the polarizing beam splitter 105RGB.

  The R light and B light, which are S-polarized light, pass through the polarizing plate 103b, are reflected by the reflecting prism 110, and pass through the specific wavelength region polarization conversion element 112a. The specific wavelength region polarization conversion element 112a converts the B light from S-polarized light to P-polarized light, and the R light is transmitted as S-polarized light without being converted, and the B light and R light are separated by color separation and The light is incident on the combining polarization beam splitter 105RB. Since the B light is P-polarized light, it is transmitted through the polarization beam splitter 105RB, is transmitted through the ¼λ wavelength plate 106b, and is incident on the B-light liquid crystal display element 107B, where it is converted into S-polarized light and reflected. The light again enters the polarization beam splitter 105RB through the quarter-wave plate 106b and is reflected there. Since the R light is S-polarized light, it is reflected by the polarization beam splitter 105RB, and enters the liquid crystal display element 105RB for R light through the ¼λ wavelength plate 106c. The light enters the polarizing beam splitter 105RB through the λ wave plate 106c. Since the R light is P-polarized light, it now passes through the polarizing beam splitter 105RB. The R light and B light emitted from the polarization beam splitter 105RB enter the specific wavelength band polarization conversion element 112b. The specific wavelength region polarization conversion element 112b converts the B light, which is S-polarized light, into P-polarized light, and transmits the R light, which is P-polarized light, without being subjected to polarization conversion. The R light and B light transmitted through the specific wavelength region polarization conversion element 112b are incident on the color combining polarization beam splitter 105RGB. Since both the R light and the B light are P-polarized light, they pass through the polarization beam splitter 105RGB and enter the specific wavelength band polarization conversion element 112c. The specific wavelength region polarization conversion element 112c converts the G light from S-polarized light to P-polarized light. Accordingly, R light, G light, and B light are transmitted as P-polarized light through the polarizing plate 103c and are incident on a projection lens (not shown). The polarization directions of the R light and the B light are not limited to this, and the R light may be incident on the polarization beam splitter 105RB as P polarization and the G light as S polarization.

  FIG. 10 is a schematic plan view showing a tenth embodiment of the optical engine used in the video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. In the figure, compared to the eighth embodiment of FIG. 8, the R, G, and B lights whose polarization directions are converted to S-polarized light by a polarization conversion element (not shown) are subjected to polarization conversion in a specific wavelength range. The incident light is incident on the element 112d, where the B light is converted into P polarized light, the color separation polarizing beam splitter 111 is provided in place of the color separation mirror 102, and the reflection mirror 109 is replaced with all of them. The main difference is that the reflecting prism 110 is provided.

  The B light is converted from S-polarized light to P-polarized light by the specific wavelength region polarization conversion element 112d, and then transmitted through the polarization beam splitter 111, and the color adjustment film 104 and the polarizing plate 103 (an example of rectification by the polarizing plate). And enters the polarization beam splitter 105RGB for color synthesis. The B light thereafter is emitted from the polarization beam splitter 105RGB through the same path as in the embodiment of FIG. The R light and G light, which are S-polarized light, are reflected by the total reflection mirror 110 and then enter the polarizing plate 103b. The subsequent R light and B light are processed in the same manner as in the embodiment of FIG. 8, and are emitted from the polarizing beam splitter 105RGB. The polarizing plate 103a may be provided at the position of the specific wavelength region polarization conversion element 112d, and a polarizing plate, a vapor deposition polarizing plate, a polarization separation sheet, or the like may be attached to the prism 111 together with the specific wavelength region polarization conversion element 112d. Further, in this case, the prisms 111 and 110, the polarization beam splitter 105RGB, and the total reflection prism 108 can all be attached, and the assemblability can be improved. Also, the adjustment of the optical axis is easy.

  FIG. 11 is a schematic plan view showing an eleventh embodiment of the optical engine used in the video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. In the present embodiment, of the light from the light source unit (not shown), the P-polarized light is transmitted through the polarization conversion element as it is, and the S-polarized light is converted to P-polarized light by the polarization conversion element (not shown). Is done. Only the G light is converted into S-polarized light by the specific wavelength range polarization conversion element 112d and is incident on the polarization beam splitter 111 for separation. Only the G light that is S-polarized light is reflected here, and the total reflection prism 108 is further reflected. And enters the liquid crystal display element 107G for G light through the ¼λ wavelength plate 106a, and enters the polarization beam splitter 111 as P-polarized light. Since the G light is P-polarized light, it is transmitted through the polarizing beam splitter 111, and further transmitted through the polarizing plate 103a and the color combining polarizing beam splitter 105RGB and is incident on a projection lens (not shown). Since the B light and the R light are P-polarized light, they pass through the polarization beam splitter 111 and the polarizing plate 103b for color separation, and enter the specific wavelength region polarization conversion element 112a. The R light is converted into S-polarized light by the specific wavelength region polarization conversion element 112a, and the B light is not polarized but is incident on the polarization beam splitter 105RB for color separation / combination (or detection) as P-polarized light. Since the R light is S-polarized light, it is reflected by the polarization beam splitter 105RB, enters the liquid crystal display element 107R for R light through the ¼λ wavelength plate 106b, is converted to P-polarized light, and passes through the polarization beam splitter 105RB. To do. Since the B light is P-polarized light, it passes through the polarizing beam splitter 105RB and enters the liquid crystal display element 107B for B light through the ¼λ wavelength plate 106c. Here, the light is converted into S-polarized light, and this time, since it is S-polarized light, it is reflected by the polarization beam splitter 105RB and is incident on the specific wavelength region polarization conversion element 11b. Here, the R light is converted into S-polarized light, the B light is converted into polarized light, passes through the S-polarized light as it is, is reflected by the total reflection prism 117 through the polarizing plate 103c, and is incident on the combining polarization beam splitter 105RGB. Is done. Since the R light and the B light are S-polarized light, they are reflected by the polarization beam splitter 105RGB and enter a projection lens (not shown). In this embodiment, the polarizing plate 103a is not necessary, and in that case, the total reflection prism 108, the polarization beam splitters 111 and 105RGB, and the total reflection prism 117 can be bonded together.

  FIG. 12 is a schematic plan view showing a twelfth embodiment of the optical engine used in the video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. Compared with the embodiment of FIG. 10, the embodiment of the figure is provided with a polarization conversion element 115 instead of providing the specific wavelength region polarization conversion element 112 d, and a dichroic prism 111 b is provided instead of the polarization beam splitter 111. However, the arrangement of the liquid crystal display element 107 is different. Note that the color adjustment film 104 is not illustrated, but may be provided as appropriate, for example, at the same position as in FIGS.

  In the present embodiment, description will be made assuming that R light, G light, and B light are S-polarized light. The G light passes through the dichroic prism 111b and the polarizing plate 103a, is converted into P-polarized light by the polarization conversion element 115, passes through the polarization beam splitter 105RGB, is reflected by the total reflection prism 108, and passes through the 1 / 4λ wavelength plate 106a. , Is incident on the liquid crystal display element 107G for G light. Thereafter, the light enters the polarization beam splitter 105RGB again through the same path as the B light in FIG. 10, and is reflected there.

  On the other hand, the R light and the B light are reflected by the dichroic prism 111b, reflected by the total reflection prism 110, transmitted through the polarizing plate 103b, and the B light is changed from S-polarized light to P-polarized light by the specific wavelength region polarization conversion element 112a. The converted R light is not polarized in the polarization direction and enters the polarization beam splitter 105RB for color separation / synthesis. The B light that is P-polarized light is transmitted through the polarization beam splitter 105RB, is transmitted through the ¼λ wavelength plate 106c, and is reflected as S-polarized light by the liquid crystal display element 107B for B light. The B light is further reflected by the polarization beam splitter 105RB, converted into P-polarized light by the specific wavelength region polarization conversion element 112b, passes through the polarizing plate 103c, and then passes through the polarization beam splitter 105RGB. Since the R light is S-polarized light, it is reflected by the polarization beam splitter 105RB for color separation / combination, passes through the quarter-wave plate 106b, is reflected as P-polarized light by the liquid crystal display element 107R for R light, and is analyzed by the analyzer. The light passes through a certain polarization beam splitter 105RB, the specific wavelength region polarization conversion element 112b passes through the polarized light as it is, is rectified by the polarization plate 103c, and then passes through the polarization beam splitter 105RGB. Of the R light, B light, and G light, the G light is changed to P-polarized light by the specific wavelength region polarization conversion element 112c. For this reason, R light, B light, and G light are all polarized and rectified through the polarizing plate 103d as P-polarized light and then input to a projection lens (not shown). Accordingly, the polarizing plate 103c may be eliminated, and the polarization rectification of all the emitted light of R light, G light, and B light may be performed by the polarizing plate 103d. In this case, the outgoing polarization direction is aligned with all the light. Further, it is not necessary to cool the polarizing plate 103c, the structure is simplified, and the back focus distance is shortened, which is optically advantageous.

  FIG. 13 is a schematic plan view showing a thirteenth embodiment of an optical engine used in a video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. Compared with the embodiment shown in FIG. 11, the embodiment shown in FIG. 13 is provided with a specific wavelength region polarization conversion element 112c on the exit surface of the polarizing beam splitter 105 for separation. Further, in FIG. The polarizing plate 103c provided between the total reflection prism 117 is provided on the exit surface of the specific wavelength region polarization conversion element 112c, and the polarizing plate 103c provided between the polarization beam splitter 111 and the polarization beam splitter 105RGB is removed. The difference is different.

  The G light is reflected by the liquid crystal display element 107G through the same path as in FIG. 11, and then passes through the polarizing beam splitter 111 and the polarizing beam splitter 105RGB as P-polarized light. Similarly to the case of FIG. 11, the R light and the G light are reflected by the liquid crystal display elements 107R and 107B, respectively, and then the R light is converted from P-polarized light to S-polarized light by the specific wavelength region polarization conversion element 112b. And B light are reflected by the total reflection prism 117 as S-polarized light and further reflected by the polarization beam splitter 105RGB. Thereafter, only the G light is converted from P-polarized light to S-polarized light by the specific wavelength region polarization conversion element 112c, and the R light, G light, and B light are projected as a S-polarized light through the polarizing plate 103c (not shown). Is incident on. Furthermore, even if the polarizing plate 103b and the specific wavelength region polarization conversion element 112b are removed, the color separation and combination function sufficiently. The size of the polarizing beam splitter is the largest for the polarizing beam splitter 105RGB, the smallest for the polarizing beam splitter 105RB, and the size of the polarizing beam splitter 111 is intermediate between them. Even if the light incident on the system is telecentric, it is possible to prevent the light incident on the liquid crystal display element from being vignetted by the polarizing beam splitter or the total reflection prism.

  FIG. 14 is a schematic plan view showing a 14th embodiment of an optical engine used in a video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. Compared with the embodiment of FIG. 8, the condenser lens 119a is provided between the color separation mirror 102 and the color combining polarization beam splitter 105RGB in the embodiment of FIG. The difference is that a condenser lens 119 b is provided between the mirrors 109. Therefore, the reflection and transmission paths of G light, R light, and B light are the same. FIG. 14 is a schematic plan view showing a fourteenth embodiment of the optical engine used in the video display apparatus according to the present invention. The light is indicated by a solid line and a dotted line, the solid line indicates S-polarized light, and the dotted line indicates P-polarized light. The embodiment of FIG. 15 differs from the embodiment of FIG. 9 in that a condenser lens 119 is provided on the incident side of the color separation mirror 102. The reflection and transmission paths of G light, R light, and B light are the same as those in FIG.

  Hereinafter, the function and effect of the embodiment of FIGS. 8 to 15 will be described. The liquid crystal display element 107B shown in FIGS. 8, 10, and 14 and the liquid crystal display element 107G shown in FIGS. You may attach facing the splitter 111. FIG.

  8 to 15, the color separation means such as the color separation mirror 102, the polarization beam splitter 111, and the color separation dichroic prism 111b, and the color separation such as the polarization beam splitter 105RG and the polarization beam splitter 105RB for color separation / combination. It can be configured by combining means and color combining means indicated by a color combining polarizing beam splitter 105RGB. Therefore, RGB color separation and composition can be easily performed at a low weight and at a low cost.

  In all the embodiments, the first reflection unit such as the reflection mirror 109 and the total reflection prisms 110 and 117 and the second reflection unit such as the total reflection prism 108 are provided, so that the R light, the B light, and the like. The optical path length of G light can be made the same. Moreover, by comprising in this way, while being able to make it lightweight and low cost, various arrangement | positioning can be comprised. That is, the triangular prism having the same optical path length than the rectangular prism block can be reduced in weight by about half if the same glass material is used, thereby reducing the material cost.

  As the reflection means such as the reflection mirror 109, the total reflection prisms 110 and 117, and the total reflection prism 108, aluminum, a silver vapor deposition mirror, a reflection prism, a mirror vapor deposition prism, or the like can be used. As a result, the reflection efficiency can be improved, and a reduction in size and weight can be achieved. Alternatively, a dichroic mirror or a dichroic prism provided with a dielectric multilayer film can be used as the reflecting means. Thus, unnecessary light is cut and color adjustment is possible. Further, by using the color adjusting film 104 for the reflecting means, color adjustment can be performed more finely.

  8 to 10 according to the present invention, among the R light, G light, and B light by the color separation means such as the separation mirror 102, the polarization beam splitter 111, the color separation dichroic prism 111b, etc. The first and second lights are separated into the third light, and the optical axis direction is bent, for example, in a substantially right angle direction by the first reflecting means such as the reflection mirror 109 and the total reflection prisms 110 and 117, and the polarization beam splitter. The light is incident on color separation / combination means such as 105RG and polarization beam splitter 105RB. The light incident on the color separation / combination means is separated into the first light and the second light, and is incident on an image display element that is a light valve corresponding to each color light, which is arranged substantially at right angles to each other. The first light and the second light reflected by these video display elements are incident on the color synthesizing means. After the third light is separated by the color separation means, it passes through the color composition means constituted by the polarization beam splitter 105RGB arranged in the direction of the emission optical axis of the third light in the direction of the optical axis, For example, after being bent in a substantially right angle direction by the reflecting means 2 and entering the image display element that is the light valve for the third light, the image display element that is the light valve corresponding to the light of each color is reflected. The image light emitted from the image display element is combined with the first and second lights by the color combining means. Therefore, in this embodiment, the efficiency and contrast ratio of each color of the first to third lights, for example, R light, G light, and B light, can be optimized.

  In the embodiment of the present invention, the polarized light unified into S-polarized light or P-polarized light in the illumination optical system is the light separated into R light, G light, and B light by the color separation means. The first and second two-color light beams are bent in the direction substantially perpendicular to the optical axis direction by the first reflecting means, and the first light of the first and second two-color light beams is polarized by the specific wavelength band polarization conversion element. If the direction is different from the polarization direction of the second light, for example, if the first light is S-polarized light, the second color light is converted into P-polarized light and then incident on the color separation / combination means. The light incident on the color separation / combination means is separated into first and second lights, and is incident on video display elements, which are light valves corresponding to the respective color lights, arranged substantially at right angles to each other. The remaining third light separated by the color separation means is separated by the color separation means, and then the polarization conversion element, for example, the polarization conversion element 115, 1 / 2λ wavelength, disposed in the direction of the third light emission optical axis. The polarization direction is converted by a plate or the like, for example, the S-polarization direction is converted to the P-polarization direction (see FIG. 8), and the color synthesizing means, for example, the polarization beam splitter 105RGB disposed on the output side of the polarization conversion element is The light passes in the direction of the optical axis, and the third light is bent in a substantially right angle direction by the second reflecting means, and is incident on an image display element that is a light valve corresponding to the color of the third light. . In this case, without using the second reflecting means, it simply enters the image display element, which is a light valve of this color, in the direction of the outgoing optical axis of the color synthesizing means via an optical medium such as glass material or air. Also good. The light is reflected by the image display element which is a light valve of each color. Of the image light emitted from these image display elements, the first light is emitted from the image display element as P-polarized light, and the second color light is emitted from the image display element as S-polarized light, respectively. Color synthesis or black display or the like is analyzed by a synthesis unit, for example, polarization beam splitters 105RB and 105RG, and emitted in a direction orthogonal to the incident optical axis of the color separation and synthesis unit. Thereafter, the second color light, which is S-polarized light, is converted into P-polarized light by the specific wavelength region polarization conversion element (for example, the specific wavelength region polarization conversion element 112b) arranged on the output optical axis, The polarization direction is aligned with that of the P-polarized light, which is color light, and is incident on the color combining means. On the other hand, after the third light is reflected from the image display element, if the incident light is P-polarized light, the polarization direction is converted by the image display element so that the outgoing light becomes S-polarized light, and the light is transmitted through the second reflecting means. Is incident on the color composition means. The third light is then reflected by the color synthesizing means and synthesized with the light that is the first and second P-polarized light, and the outgoing optical axis is different from the incident optical axis of the third light to the color synthesizing means. It is emitted from. In addition, when the light incident on the color separation means is P-polarized light, the third light polarization conversion element 115 and the 1 / 2λ wavelength plate described above are not necessary and the P-polarized light is transmitted through the color separation means. And enters the second reflecting means. Since the first light and the first light need to be separated into P-polarized light and S-polarized light, respectively, a specific wavelength region polarization conversion element is required on the incident / exit optical path of the color separation / combination means as described above. In this case, the number of polarization conversion elements for the third light can be reduced and the cost can be reduced.

  In the present embodiment, as shown in the eighth embodiment, the first color separation unit may reflect the R light and the G light and transmit the B light. A color separation / combination prism may be disposed at the light incident position of the total reflection prism 108 to transmit the R light and the B light and reflect the B light. Further, as in the embodiment of FIG. 11, R light and B light may be transmitted and G light may be reflected. In this configuration, R light and G light may be transmitted and B light may be reflected. Similarly, as shown in FIG. 9, the color separation unit may reflect R light and B light and transmit G light. Alternatively, the color separation / combination prism may be arranged at the light incident position of the total reflection prism 108 to transmit the R light and the B light and reflect the G light.

  Further, the color separation unit may be configured to reflect G light and B light and transmit R light, or to transmit G light and B light and reflect R light. In the embodiment of the present invention, the color separation means is constituted by a dichroic mirror or a dichroic prism. The color separation / synthesis means and the color synthesis means are configured by a polarization beam splitter which is a polarization separation / synthesis element.

  In this embodiment, a specific wavelength region polarization conversion element is disposed between the first color separation unit and the color separation / synthesis unit. In addition, since the specific wavelength polarization conversion element is arranged between the first color separation unit and the color synthesis unit, and between the color separation and synthesis unit and the color synthesis unit, each of the R, G, and B lights Efficiency and contrast ratio are improved. Further, in these configurations, by disposing a polarizing plate (or a polarization rectifying element) between the first color separation unit and the color synthesis unit and between the color separation and synthesis unit and the color synthesis unit, R, The contrast ratio of each color light of G and B can be improved.

  The color separation / combination means takes the peak value of the optical characteristics so that the transmission efficiency or reflection efficiency is optimal for the two incident colors. For example, a configuration that is a polarization beam splitter 105RG specialized in characteristics for color separation / synthesis of R light and G light, or a polarization beam splitter 105RB specialized in characteristics for color separation / synthesis of R light and B light, or G A polarization beam splitter configuration in which characteristics are specialized for color separation and combination of light and B light may be used. Thereby, the efficiency and contrast ratio of each color light of R, G, and B can be improved.

  The color separation / synthesis unit and the color synthesis unit are polarization separation / analysis elements. Thereby, the contrast ratio of each color light of R, G, and B can be improved. The color separation / synthesis means and the color synthesis means can eliminate light vignetting by making the size of the color separation / synthesis means larger than the size of the color synthesis means. In this embodiment, the color synthesizing means has two colors (BG light, RB light, or RG light) that are P-polarized light incident from substantially orthogonal directions, and one color that is S-polarized light (R light, Alternatively, G light or B light) may be combined to emit three colors in the direction of the P-polarized light axis. In this embodiment, the optical axis of the color synthesizing means is parallel to the optical axis of the projection means, but the optical axis may be shifted.

  In the present embodiment shown in FIG. 9, since the reflection mirror portion is made of total reflection prisms 108 and 110, the optical path length can be made uniform with R light, G light and B light, and the back focus can be shortened. it can. Further, by bonding the total reflection prism 108 to the color synthesis prism or the polarization beam splitter 105RGB, it is possible to reduce an error in assembly accuracy.

  The light emitted from the liquid crystal display element 107G for G light is S-polarized light, the light emitted from the liquid crystal display element 107R for R light is P-polarized light, and the light emitted from the liquid crystal display element 107B for B light is emitted. By making the incident light S-polarized light, the efficiency and contrast ratio of each color light of R, G, and B can be improved.

  In the embodiment shown in FIG. 11, after passing through the specific wavelength region polarization conversion 112d, the color is separated by the polarization beam splitter 111 which is the color separation means, and the first and second light colors are separated by the color separation / combination means (for example, the polarization beam). Through the splitter 105RG), the light is input / exited to the liquid crystal display element corresponding to the first and second light, synthesized by the color separation / synthesis means, and emitted from the orthogonal optical axis different from the incident, and the mirror (total reflection mirror) 117) through the color composition means. The third light enters / exits the liquid crystal display element corresponding to the third light through the mirror (total reflection mirror 108), passes through the color separation unit, and enters the color synthesis unit. Thereafter, the first, second and third lights are synthesized by the color synthesizing means. The first to third light exit directions are parallel to both the direction orthogonal to the illumination optical axis if a 1 / 2λ wavelength plate is inserted in place of the polarizing plate 103 or the specific wavelength region polarization conversion element 112. Can also be emitted.

  In the embodiment of FIG. 12, the dichroic mirror 102 shown in FIG. 1 is replaced with a dichroic prism 111b. Thereby, the effective length of the incident optical path to the liquid crystal display element can be shortened, and the diffused light can be suppressed. In particular, if a condenser lens 119 is inserted as shown in FIG. 15 before entering the dichroic prism 111b to make a telecentric system, for example, the change in characteristics with respect to the light beam angle in the polarizing beam splitter, dichroic prism, dichroic mirror, and polarizing plate is minimized. In addition, adverse effects such as reflection on the inner surface of the prism due to diffused light can be reduced.

  Further, as in the embodiment shown in FIG. 13, when the PBS 105RGB and the prism surface of the polarization beam splitter 111 are bonded together, and the polarization beam splitter 111 and the total reflection mirror 108 are bonded together, the assembly accuracy is improved and the position accuracy is improved. Easy to put out.

  As shown in FIG. 14, when a telecentric system is formed by inserting condenser lenses 119a and 119b on each optical path, the characteristic change with respect to the light beam angle in the polarizing beam splitter, dichroic prism, dichroic mirror, and polarizing plate is minimized. In addition, adverse effects such as internal reflection of the prism due to diffused light can be reduced.

  Further, as shown in FIG. 15, when a telecentric system is provided by providing a condenser lens 119 in front of the first color separation means, the characteristic change with respect to the light beam angle in the polarizing beam splitter, dichroic prism, dichroic mirror, and polarizing plate is changed. It can be suppressed to the minimum, and adverse effects such as reflection of the inner surface of the prism due to diffused light can be reduced.

  In the embodiment of FIG. 8, as the color adjustment film 104, for example, a dielectric multilayer film is directly deposited on a polarization beam splitter or a dichroic prism, the dielectric multilayer film is a polarizing plate, a specific wavelength region polarization conversion element, 1 / 2λ wavelength plate or 1 / 4λ wavelength plate deposited on a polarizing beam splitter or dichroic mirror dichroic mirror, color film or color filter such as colored glass, etc. Any device that can reduce the transmittance in a specific wavelength range can be applied.

  In the present embodiment, the total reflection prism 108 is not necessarily required, and may be disposed facing the B light emission surface of the color combining polarization beam splitter 105RGB. However, by providing the total reflection prism 108 as in the present embodiment, the height of the optical path of each R, G, B light can be made uniform, so that uneven color can be eliminated.

  Further, according to the present embodiment, one color separation mirror 102, color separation / combination means such as a polarization beam splitter (or dichroic prism) 105RG, and color composition means such as a polarization beam splitter (or dichroic prism) 105RGB. Since the optical engine can be configured by R, R light, G light, and B light can be separated at a light weight and low cost.

  8, 10, and 14, color selection can be performed and color reproducibility can be improved by selecting a wavelength band for reducing the wavelength of light by the color adjustment film 104. . For example, the color adjustment films 104a and 104b may be used to select a wavelength band in which the transmittance is reduced, and the transmittance in the yellow wavelength region and the cyan wavelength region may be reduced to obtain a good color. Moreover, when making it bright, you may increase a yellow component. In this case, in order to maintain white balance, the color adjustment film 104 can be adjusted to cut cyan.

  In the embodiment of FIG. 8, the color adjustment film 104a is provided on the B light incident surface of the polarizing beam splitter 105RGB, but may also be provided on the B light exit surface of the polarizing beam splitter 111 as shown in FIG. Good. In FIG. 8, the color adjustment film 104b is provided on the R light and B light incident surfaces of the polarizing beam splitter 105RG for color separation / synthesis (analysis). As shown in FIG. The polarizing beam splitter 105RG may be provided on the R light and B light exit surfaces, or may be provided on the R light and B light incident surfaces of the color combining polarizing beam splitter or dichroic prism 105RGB. That is, the same effect can be obtained even if the color adjustment film 104 is provided on the light incident surface or the light exit surface of the analyzing polarization beam splitter, the color combining polarization beam splitter, or the dichroic prism.

  In the embodiment of FIG. 9, color adjustment can be performed by adjusting the color separation mirror 102 such as a dichroic mirror and the specific wavelength range polarization conversion elements 112a and 112b. However, the embodiment described below can be applied not only to FIG. 9 but also to other embodiments.

An example of this case will be described with reference to FIG.
FIG. 16 is a spectral characteristic diagram showing the light transmittance. The horizontal axis represents the wavelength W, and the vertical axis represents the light output P. FIG. 16A shows the output characteristic curve P0 of the color separation mirror 102 of FIG. 9, and it is assumed that, for example, it is configured not to transmit light having a half value between approximately 500 nm and approximately 600 nm. Of the light transmitted through the color separation mirror 102, as shown in FIG. 10 (b), light of S1 or less having a wavelength longer than about 600 nm is converted from S-polarized light to P-polarized light, The characteristic curve P1 of the specific wavelength region polarization conversion element 112a is configured so that the light is transmitted as it is as the S-polarized light. This light is reflected by the liquid crystal display elements 107B and 107R to change the polarization, light having a wavelength up to S1 is converted to S-polarized light, and light having a wavelength longer than S1 is converted to P-polarized light. As shown in FIG. 10 (c), the characteristic curve is such that light having a wavelength of S2 or less is converted from S-polarized light to P-polarized light, and the polarization direction of the light having a wavelength of S1 or more is not changed but remains P-polarized light. When the light passes through the specific wavelength region polarization conversion element 112b having P2, the light from this region is reflected by the polarization beam splitter 105RGB because it remains as S-polarized light from the wavelength S2 to S1, and is not incident on the projection lens. In this way, light with wavelengths S1 and S2 can be cut.

  Thus, the transmittance of the specific region of the wavelength can be changed by the combination of the reflection mirror 110 and the specific wavelength region polarization conversion elements 112a and 112b. In this embodiment, yellow can be eliminated by setting approximately 600 nm to approximately 580 nm. Similarly, the brightness can be improved by changing the configuration of the specific wavelength region polarization conversion element 112 and the color adjustment film 104. For example, when aiming to improve brightness by adding bright line light, the light of 500 nm to 515 nm, for example, light of 500 nm to 515 nm is cut by combining the half value of the color adjustment film 104 and the half value of the specific wavelength region polarization conversion element 112. Brightness and white balance can be improved by putting light in the vicinity of 580 nm.

  The same effect can be obtained by combining the dichroic mirror 102 and the color adjustment film 104. In this embodiment, the dichroic mirror 102 and the total reflection mirror 110 can be replaced with a dichroic prism. Therefore, in the above description, the dichroic mirror 102 and the total reflection mirror 110 can be read as a dichroic prism.

  8 and 9, the polarizing plate 103b is provided in the vicinity of the polarizing beam splitter 105RG, and the polarizing plate 103c is provided in the vicinity of the polarizing beam splitter 105RGB. When these polarizing plates 103 are attached to a nearby polarizing beam splitter, the interface is reduced and the light transmittance can be increased. In addition, the polarizing beam splitter 105 has a large heat radiation effect and absorbs heat from the polarizing plate 103, so that the cooling property of the polarizing plate 103 can be increased. Note that the optical engine shown in FIGS. 8 and 9 can be formed of a dichroic prism. In this case, the polarizing plate 103 may be attached to the dichroic prism. In this case, the polarizing plate 103 is preferably formed of a film.

  In the embodiments of FIGS. 8 and 9, etc., when a color adjusting film is provided on the incident surface of the color separation mirror 102, for example, a dichroic mirror, for example, when a dielectric multilayer film is deposited, the thickness of the portion where the incident angle of light is large. When the film thickness is changed so that the thickness of the light incident angle is small and the thickness of the light incident angle is small, the half-wavelength value shifts and the color and color unevenness of the emitted light can be adjusted. . When the optical engine shown in FIGS. 8 and 9 is configured by a dichroic mirror or a dichroic prism, that is, the color separation mirror 102 is configured by a dichroic mirror or a dichroic prism, and a dichroic prism is provided instead of the polarization beam splitter 105. In this case, the same effect can be obtained by providing the color adjusting film with a different thickness on these incident surfaces.

  In the embodiments of FIGS. 8, 9 and the like, it is preferable to change the glass materials of the polarization beam splitters 105RG and 105RB for color separation / synthesis and the polarization beam splitter 105RGB for color synthesis. For example, a glass material with a small amount of birefringence such as PBH53W is selected for the polarization beam splitters 105RG and 105RB for color separation / synthesis, and a light and low-cost glass material such as BK7 is used for the synthesis polarization beam splitter 105RGB. By selecting, performance optimization, cost reduction, and weight reduction can be achieved. The same applies to the case where the color separation mirror 102 is constituted by a dichroic prism or a polarizing beam splitter and the polarizing beam splitter 105 is replaced by a dichroic prism. In this case, the separation dichroic prism may be made of a light and low-cost glass material, similar to the polarization beam splitter or dichroic prism for synthesis.

  8 and 9, when the volume of the polarization beam splitters 105 RG and 105 RB for color separation / combination is V 1 and the volume of the polarization beam splitter 105 RGB for color synthesis is V 2, V 1 is made smaller than V 2, as described above. Thus, when the glass material is selected, the performance can be optimized in accordance with the usage characteristics, the low-cost glass material can be used, and the weight can be reduced. As a modification, the present invention can also be applied to a case where a dichroic mirror or a dichroic prism is used as the color separation mirror 102 and a dichroic prism is used instead of the polarization beam splitter 105. In particular, if the size of the polarization beam splitter 105RGB or dichroic prism for color separation and color synthesis is increased, it is possible to prevent vignetting of incoming and outgoing light rays. In this case, by changing the glass material of the polarizing beam splitter or dichroic prism for the purpose of use such as the transmission efficiency or reflectance of the glass material, the performance can be reduced, the cost can be reduced, and the weight can be reduced by using a glass material with a low specific gravity. Aim. For example, the analyzing polarization beam splitter has a high extinction ratio with a glass material having a high refraction, a light elastic constant of 0.5 × 10 −12 N / m 2, a size □ 32, and a stress of 5.3 × 10 4 Pa or less. However, the specific gravity of dichroic prisms and polarizing beam splitters for color separation and color synthesis is light, and using glass materials with good overall transmission efficiency, including dielectric multilayers, increases the volume to prevent vignetting In addition, it is possible to improve performance, reduce weight, and reduce costs.

  Next, an example in which the liquid crystal display element is attached to the polarization beam splitter 105 will be described with reference to FIG.

  FIGS. 17A and 17B are partial cross-sectional plan views showing examples of how to attach the liquid crystal display element to the polarization beam splitter. In FIG. 17A, a liquid crystal display element 107G has a liquid crystal material 132 sealed in a frame 107, and cover glasses 133a and 133b are provided on both sides thereof. After adjusting the position of the liquid crystal display element 107G, the frame 130 is directly bonded to the polarizing beam splitter 105G with adhesives 134a and 134b. As the adhesive, for example, a UV adhesive or a thermosetting adhesive may be used for curing. In this embodiment, the cover glass 133a and the polarizing beam splitter 105G may be bonded or fixed with an adhesive.

  FIG. 17B shows another embodiment. In this embodiment, an adjustment plate 134 is provided, and this adjustment plate 134 is bonded to the polarizing beam splitter 105G with an adhesive 134. After the position of the liquid crystal display element 107G is adjusted with respect to the polarization beam splitter 105G, the frame 130 is bonded or fixed to the adjustment plate 134. In addition, an air layer can be eliminated between the cover glass 133a and the polarizing beam splitter 105G using silicon oil or an adhesive. According to the present embodiment, since the interface between the polarizing beam splitter 105G and the liquid crystal display element 107G can be reduced, the light utilization efficiency can be increased. In the embodiment of FIG. 17, the polarizing beam splitter 105G and the liquid crystal display element for G light have been described as an example. Similar effects can be obtained by direct attachment.

  Next, assembly of the polarization beam splitter will be described with reference to FIG. FIG. 18A is a perspective view showing an embodiment of the polarizing beam splitter, and FIG. 18B is a perspective view showing an embodiment of the assembly structure portion of the polarizing beam splitter. In this embodiment, the color separation mirror 102 and the total reflection mirror 110 shown in FIG. 8 are used as polarization beam splitters or dichroic prisms, and four prisms are used.

  In FIG. 18A, reference numeral 151 denotes a polarization beam splitter or dichroic prism for color separation, which is composed of a triangular prism 151H having a long height and a prism 151L having a short triangular prism in order to provide a step on the bonding surface. ing. Reference numeral 152 denotes a polarization beam splitter for G light, which includes a long triangular prism 152H and a short triangular prism 152L in order to provide a step on the bonding surface. Reference numeral 153 denotes a polarization beam splitter for R light and B light, which is composed of a long triangular prism 153H and a short triangular prism 153L in order to provide a step on the bonding surface. The light is color-separated by the polarization beam splitter 151 or dichroic prism for color separation, and the G light is reflected by the polarization beam splitter or dichroic prism 152, is incident on the G light liquid crystal display element 107G, and is reflected by the liquid crystal display element 107G. The G light is reflected by the polarization beam splitter 154 for color synthesis and is incident on a projection lens (not shown). The R light and B light separated by the polarization beam splitter 151 are separated by the polarization beam splitter 153 and are incident on the liquid crystal display elements 107R and 107B, respectively. The R light and B light reflected by the liquid crystal display elements 107R and 107B are transmitted through the color combining polarization beam splitter 154 and incident on a projection lens (not shown). A polarizing plate, a 1 / 2λ wavelength plate, a specific wavelength band polarization conversion element, or the like is inserted in the gap between the polarizing beam splitters. Steps 155 are respectively provided above and below the polarization beam splitters 151 to 154 by a combination of a long triangular prism and a short triangular prism. In FIG. 18B, reference numeral 157 denotes an assembly structure portion, which is provided with base portions 158H to 161H on which long triangular prisms 151H to 154H are placed and base portions 158L to 161L on which short triangular prisms 151L to 154L are placed. It has been. In addition, the protrusion part 163 provided in this assembly structure part 157 is used for positioning.

  In order to assemble the polarizing beam splitter of FIG. 18A into the assembly structure portion 157, the bottoms of the long triangular prisms 151H to 154H are arranged on the bases 158H to 161H so as to be in contact with the positioning projections 163, and a short triangular prism is formed. The prisms 151L to 154L are arranged on the bases 158L to 158L so as to be in contact with the positioning projections 163. A groove is provided between each of the polarization beam splitters 151 to 154, and a polarizing plate, a specific wavelength region polarization conversion element, and the like are disposed. At this time, if it is positioned by a spring, a foam or the like, it can be placed with high accuracy.

  In this embodiment, the polarizing beam splitters 151 to 154 are provided with stepped portions, and positioning is performed at these stepped portions. Therefore, the surface of the dielectric multilayer film of the polarizing beam splitter becomes the reference surface, and assembly accuracy is improved. Therefore, the performance is also improved. Further, as is apparent from the figure, in this embodiment, the polarization beam splitter 151 for color separation widens the area of the prism 151H on the light incident side, and the output side polarization beam splitter, that is, the color combining polarization beam. The area of the prism 154H on the exit side of the splitter is increased. Until the light reaches the liquid crystal display element, it is preferable to reduce the light transmission area as it goes ahead, and the light emitted from the liquid crystal display element is set so that the transmission area increases as it goes ahead Thus, it is preferable to prevent light vignetting. In the present embodiment, such an effect can be achieved. In FIG. 18, it goes without saying that the same effect can be obtained even when some of the polarization beam splitters are formed of dichroic prisms.

  Next, the adjustment mechanism of the quarter-wave plate will be described with reference to FIG. FIG. 19 is a side view for explaining attachment of the quarter-wave plate. In the figure, reference numeral 160 denotes, for example, a mounting plate for the quarter-wave plate 106b in FIG. The quarter-wave plate 106b is fixed to the shaft 161. The shaft 161 is rotatably attached to the attachment plate 160, adjusted so that the polarization axis of light with the liquid crystal display element 107 </ b> G is aligned, and fixed to the attachment plate 160 after adjustment. The center of the rotation axis of the quarter-wave plate 106b is positioned according to the upper surface of the prism 152L. That is, the ¼λ wavelength plate 106b is based on the upper surface or the lower surface of the polarizing beam splitter 152, the emission side, or the left and right surfaces. Accordingly, the reference is constant even when the liquid crystal display element is replaced, and the original position is clear, so that the adjustment procedure can be clarified. Needless to say, the above embodiment can be applied to mounting of other quarter-wave plates.

  In FIGS. 8 and 9, etc., each of the polarization beam splitters 105RG, 105RB, and 105RGB has a surface that does not contribute to the transmission or reflection of light. It is preferable that the surface not used in the above is made of frosted glass or painted black. The same applies when the polarizing beam splitter is replaced with a dichroic prism.

  Referring to FIG. 8, the B light incident on the color combining polarization beam splitter 105RGB is S-polarized light, the RG light is P-polarized light, and the optical axis emitted from the B light liquid crystal display element 107B. The outgoing optical axes of the color combining polarization beam splitter 105RGB are arranged so as to be at right angles. A dichroic mirror or a dichroic prism can be used instead of the polarization beam splitter RGB for color synthesis.

  When a dichroic mirror or dichroic prism is used in place of the color combining polarization beam splitter 105RGB shown in FIG. 8, the light combined with other light as reflected light is S in the color combining dichroic mirror or dichroic prism. Polarized light is more efficient, and conversely, light synthesized as transmitted light is more efficient with P-polarized light. That is, when the reflected light is S-polarized light, the reflection bandwidth of the dielectric multilayer film provided in the dichroic mirror or the dichroic prism is widened and is not easily affected by film characteristics due to band shift or the like. Further, when the transmitted light is P-polarized light, the transmission bandwidth of the dielectric multilayer film provided in the dichroic mirror or dichroic prism is widened and is not easily affected by the film characteristics due to band shift or the like. Therefore, the B light is reflected as S-polarized light, the RG light transmitted through the dichroic mirror or dichroic prism is combined as P-polarized light, and the light is emitted in the direction of the optical axis reflected by the dichroic mirror or dichroic prism. Good. On the other hand, when the polarization beam splitter 105RGB for color synthesis is used, the light from the liquid crystal display element 107B for B light is reflected by the polarization beam splitter 105RGB, and is combined with the RG light and emitted. However, it is necessary that the reflected light is S-polarized light and the transmitted light is P-polarized light.

  In FIG. 9, the G light incident on the polarization beam splitter 105RGB which is the color synthesizing means is S-polarized light, the RB light is P-polarized light, and the emitted light from the liquid crystal display element 107G for G light. The output optical axis of the polarization beam splitter 105RGB serving as the output means is provided so as to be parallel to the output. Referring to FIG. 9, the liquid crystal display element 107R for R light and the liquid crystal display element 107B for B light are arranged substantially at right angles, and the polarization beam splitter 105RB for separation / combination that separates and combines R light and B light. The incident optical axis and the outgoing optical axis are substantially perpendicular, and the projection lens 113 is arranged substantially parallel to the outgoing optical axis. In this embodiment, it goes without saying that a dichroic mirror or a dichroic prism can be used instead of the polarization beam splitter 105RB for separation and synthesis. By configuring the optical engine as shown in FIGS. 8 and 9, etc., an image display device as shown in FIG. 14 is obtained.

  FIG. 20 is a schematic perspective view showing an embodiment of a video display device according to the present invention. In the figure, the optical system is shown through. In the figure, reference numeral 171 denotes an illumination optical system, and reference numeral 172 denotes an optical engine as shown in FIGS. The optical axis of the light incident on the light separation / combination unit 172 from the illumination optical system 171 is bent at a substantially right angle and emitted from the light separation / combination unit 172. This light is reflected by the reflection mirror 174 provided on the back surface of the cabinet through the projection lens 118 and projected onto the screen 175. In this case, the angle of incidence on the back reflecting mirror 174 may be changed by shifting the optical axes of the separation / combination unit 172 and the projection lens 118. As a result, the mirror size can be reduced, and the size of the set in the depth direction can be reduced. In this case, the optical axes of the analyzing prism and the color combining prism may be shifted. Furthermore, the optical axis of the projection lens 118 and the optical axis of the color synthesis prism may be shifted stepwise.

  FIG. 21 is a perspective view showing another embodiment of the optical system. The figure differs from FIG. 14 in that a mirror 176 for converting the optical axis is provided. In this embodiment, by providing the mirror 176, an image can be projected directly on the screen. 20 and FIG. 21, the optical system can be arranged in a compact manner.

  In FIG. 8, R light, B light, and G light are directly incident on the reflection mirror 109 from the polarization conversion element 101, the G light and B light are transmitted through the reflection mirror 109, the B light is reflected, and the B light is polarized. The light is reflected by the beam splitter and incident on the liquid crystal display element for B light, and the light from the liquid crystal display element for B light is incident on the polarizing beam splitter 105RGB for synthesis and transmitted and emitted, while the G light And R light are respectively incident on liquid crystal display elements for R light and BG light, and the light emitted from the liquid crystal display element is reflected by the combining polarization beam splitter 105RGB and emitted, whereby a mirror 109 serving as a color separation mirror is obtained. The optical axis incident on the optical axis and the optical axis output from the polarization beam splitter 105RGB to the projection lens can be configured to be substantially parallel. In this case, it is natural for those skilled in the art that the polarization beam splitter can be replaced with a dichroic mirror or a dichroic prism.

  An image display apparatus using the above-described optical engine will be described with reference to FIG.

  FIG. 22 is a schematic perspective view showing another embodiment of the video display device according to the present invention. In the drawing, the incident axis of light incident on the optical engine 178 from the illumination optical system 171 and the optical axis emitted from the optical engine 178 are substantially parallel, and the light emitted from the optical engine 179 is reflected by the reflection mirror 179. The light is reflected and incident on the projection lens 118, reflected by the reflection mirror 174 provided on the back surface of the cabinet 173, and projected onto the screen 175.

  In this embodiment, since the back focus of the projection lens can be shortened, the number of projection lenses can be reduced and the size can be reduced. FIG. 23 is a perspective view showing still another embodiment of the optical system. In the drawing, an example of arrangement in which the reflection mirror 179 is not used is shown. Compared with the embodiment of FIG. 22, the video display device is slightly longer in the vertical direction, but can be shorter in the horizontal direction. 20 and 22, when the light emitted from the projection lens is projected onto the screen 175 by the reflection mirror 174 provided on the back surface of the cabinet 173, a light, such as a Fresnel lens, is provided on the screen 175 so as to spread the light. The size of the set can be reduced by making them substantially parallel.

  In FIG. 1, the condenser lens 30 disposed in front of the liquid crystal display elements 2R, 2G, and 2B is considered to be integrated with the projection lens 20, and is configured so that the first synthetic focal position exists in the vicinity of the diaphragm surface of the projection lens 20. Since the light beams passing through the polarization beam splitters 16G and 16RB and the color synthesis mirror 19 can be narrowed down, they can be reduced in size. In particular, when a color synthesis polarization beam splitter or a dichroic prism is used in place of the color synthesis mirror 19, the prism becomes lighter and the cost can be reduced.

  8 or 9, when a dichroic prism or dichroic mirror is used instead of the color separation mirror 102 and a dichroic prism or dichroic mirror is used instead of the polarizing beam splitter 105 RGB, the half value of the color separation dichroic prism or dichroic mirror is used. By setting the wavelength and the half-value wavelength of the color synthesis dichroic prism or dichroic mirror to different values, unnecessary light can be eliminated and color purity can be improved. For example, if the incident dichroic characteristics, that is, the low-pass half-value wavelength of the bandpass filter is 500 nm and the high-pass half-wave wavelength 590 nm, and the low-pass half-wave wavelength of the dichroic characteristic of the output prism is defined as 510 nm and the high-pass half-value wavelength 580 nm, 510 nm cyan and yellow light between 580 nm and 590 nm can be excluded. This combination can be a combination of a specific wavelength band polarization conversion element and a dichroic, and further can be a combination of a specific wavelength band polarization conversion element and a polarization beam splitter. The light to be cut may be near purple light or near infrared light, and there are ten combinations.

  In the embodiments of FIGS. 8 and 9 and the like, if a cooling flow path is provided between the polarizing beam splitter 105RG or 105RB and the polarizing beam splitter 105RGB, the specific wavelength polarization conversion element 112 and the polarizing plate 103 can be directly cooled. Is good. Polarizing beam splitter 105RG or 105RB and polarizing beam splitter 105RGB light incident surface or by providing a cooling medium outlet between polarizing beam splitter 105RG or 105RB and polarizing beam splitter 105RGB, the specific wavelength polarization conversion element 112 or Since the polarizing plate 103 can be directly cooled, the cooling efficiency is good. By simultaneously providing an entrance / exit of the cooling medium between the light incident surfaces of the polarizing beam splitter 105RG or 105RB and the polarizing beam splitter 105RGB or between the polarizing beam splitter 105RG or 105RB and the polarizing beam splitter 105RGB, the flow rate of the cooling medium can be reduced. Since it can be increased and directly cooled, the cooling efficiency is even better. In the above cooling method, the polarization plane 103 provided between the polarizing beam splitter 105RG or 105RB and the polarizing beam splitter 105RGB or the polarizing beam splitter 105RG or 105RB and the polarizing beam splitter 105RGB is directly cooled. Thus, the polarizing plate 103 can be directly cooled, cooling can be realized with high efficiency, and performance can be improved.

  According to the present invention, it is possible to achieve a reduction in size and weight, and furthermore, color purity can be freely controlled, color unevenness and the like can be improved, and performance improvement can be realized simultaneously. In addition, since the color separation means is a combination of a polarization beam splitter and a specific wavelength region polarization conversion element, there is little influence due to angle dependency, and design of color performance is facilitated. Therefore, a compact, high-brightness, high-quality optical engine or projection-type image display device can be realized. Furthermore, since the number of parts can be reduced, cost reduction can be achieved.

1 is a schematic plan view showing a first embodiment of a projection type liquid crystal display device according to the present invention. FIG. 6 is a schematic plan view showing a second embodiment of the projection type liquid crystal display device according to the present invention. FIG. 6 is a schematic plan view showing a third embodiment of the projection type liquid crystal display device according to the present invention. It is a schematic plan view which shows the 4th Example of the projection type liquid crystal display device by this invention. It is a schematic plan view which shows the 5th Example of the projection type liquid crystal display device by this invention. It is a schematic plan view which shows the 6th Example of the projection type liquid crystal display device by this invention. It is a schematic plan view which shows the 7th Example of the projection type liquid crystal display device by this invention. It is a schematic top view which shows the 8th Example of the optical engine used for the video display apparatus by this invention. It is a schematic top view which shows the 9th Example of the optical engine used for the video display apparatus by this invention. It is a schematic top view which shows the 10th Example of the optical engine used for the video display apparatus by this invention. It is a schematic top view which shows the 11th Example of the optical engine used for the video display apparatus by this invention. It is a schematic plan view which shows the 12th Example of the optical engine used for the video display apparatus by this invention. It is a schematic plan view which shows the 13th Example of the optical engine used for the video display apparatus by this invention. It is a schematic plan view which shows the 14th Example of the optical engine used for the video display apparatus by this invention. It is a schematic plan view which shows the 16th Example of the optical engine used for the video display apparatus by this invention. It is a characteristic view which shows the transmittance | permeability of light. It is a partial cross section top view which shows the Example of the attachment method of the liquid crystal display element to a polarizing beam splitter. It is a perspective view which shows one Example of a polarizing beam splitter and its assembly base tool. It is a side view for demonstrating attachment of a 1 / 4lambda wavelength plate. It is a schematic perspective view which shows one Example of the video display apparatus by this invention. It is a perspective view which shows the other Example of an optical system. It is a schematic perspective view which shows the other Example of the video display apparatus by this invention. It is a perspective view which shows other Example of an optical system.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Light source, 2G, 2R, 2B, 107R, 107G, 107B ... Reflective type liquid crystal display element, 5 ... Reflector, 6 ... First array lens, 7 ... Second array lens, 8 ... Polarizing beam splitter (PBS), 10 DESCRIPTION OF SYMBOLS: Condenser lens, 11 ... Reflection mirror, 13 ... Dichroic mirror, 14 ... Incident polarizing plate, 16 ... G polarization beam splitter, RB polarization beam splitter, 17, 112a, 112b ... Specific wavelength selective polarization conversion element, 20 DESCRIPTION OF SYMBOLS ... Projection lens, 22 ... Optical member, 23 ... Prism glass material, 25 ... Dielectric multilayer film, 101 ... Polarization conversion element, 102 ... Color separation mirror, 103 ... Polarizing plate, 105RG, 105RB, 105RGB ... Polarization beam splitter, 106 ... 1 / 4λ wavelength plate, 109... Reflection mirror.

Claims (1)

A light source that emits the emitted light by aligning it with polarized light in a specific direction; and
A color separation unit for wavelength-separating light from the light source into B-color and R-color light and G-light light;
A first polarizing beam splitter that performs color separation and synthesis of the B light and the R light;
A specific wavelength region polarization conversion element disposed on the incident side of the first polarization beam splitter and converting a polarization direction of the B-color light;
B is arranged on the side where the incident light of the first polarization beam splitter passes and exits , and after being separated by the first polarization beam splitter, the polarization direction is converted by the specific wavelength region polarization conversion element A first reflective liquid crystal display element on which colored light is incident;
A second reflective liquid crystal display element that is disposed on a side where the incident light of the first polarizing beam splitter is reflected and emitted , and on which R light separated by the first polarizing beam splitter is incident;
A second polarization beam splitter on which the G color light separated by the color separation unit is incident;
A third reflective liquid crystal display element disposed in the vicinity of the second polarizing beam splitter and receiving G-color light from the second polarizing beam splitter;
B-color and R-color light emitted from the first polarizing beam splitter and reflected by the first and second reflective liquid crystal display elements, and the third reflective type emitted from the second polarizing beam splitter. A color synthesizing unit that synthesizes the wavelength of the G light reflected by the liquid crystal display element;
A projection unit on which the light synthesized by the color synthesis unit is incident;
A video display device comprising:

Images