JP3722204B2 - Projection-type image display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image display device, and more particularly to a single-plate projection type image display device capable of performing color display using a single image display panel without using a color filter. The present invention can be suitably used for a compact projection type color liquid crystal television system or information display system.
[0002]
[Prior art]
A conventional projection type image display apparatus using a liquid crystal display panel will be described.
[0003]
In such a projection type image display device, the liquid crystal display panel itself does not emit light, and thus it is necessary to provide a separate light source. However, compared with a projection type image display device using a CRT, the color reproduction range is wide, small, and lightweight. It has very good features such as no convergence adjustment.
[0004]
In order to perform full color display by a projection type image display apparatus using a liquid crystal display panel, there are a three-plate type using three liquid crystal display panels according to three primary colors and a single-plate type using only one sheet.
[0005]
In the three-plate projection type image display device, an optical system that divides white light into three primary colors of red (R), green (G), and blue (B), and R, G, and B light respectively Full-color display is realized by optically superimposing R, G, and B color images using three liquid crystal display panels that modulate to form images.
[0006]
In the three-plate projection type image display device, light emitted from a white light source can be effectively used. However, since the optical system is complicated and the number of parts increases, generally, a single-plate projection is performed from the viewpoint of cost and size. This is disadvantageous compared to the type image display device.
[0007]
A single-plate projection-type image display apparatus uses a single liquid crystal display panel provided with color filters of three primary colors arranged in a mosaic shape or a stripe shape. Then, the full color image displayed on the liquid crystal display panel is projected onto a projection surface such as a screen by the projection optical system. Such a single-plate projection type image display apparatus is described in, for example, Japanese Patent Application Laid-Open No. 59-230383. In the case of the single plate type, since one liquid crystal display panel is used, the optical system is simpler than that in the case of the three plate type, and it is suitable to provide a small projection type image display device at a low cost.
[0008]
However, in the case of a single plate type using a color filter, light absorption occurs in the color filter, so that the brightness of the image is reduced to about 1/3 compared to the case of a three plate type using an equivalent light source. . In addition, since it is necessary to display one pixel as a set of three pixel areas corresponding to R, G, and B of the liquid crystal display panel, the resolution of the image is reduced to 1/3 of the resolution of the three-plate type. End up.
[0009]
Brightening the light source is one solution to the reduction in brightness, but it is not preferable to use a light source with high power consumption when used for consumer use. In addition, when using an absorption type color filter, the energy of light absorbed by the color filter changes to heat, so brightening the light source not only causes the temperature of the liquid crystal display panel to rise, but also causes the color filter to fade. Accelerated. Therefore, how to effectively use the given light is an important issue in improving the utility value of the projection type image display apparatus.
[0010]
In order to improve the brightness of an image by a single-plate projection type image display device, a liquid crystal display device that performs full color display without a color filter has been developed (Japanese Patent Laid-Open No. 4-60538). In this liquid crystal display device, white light emitted from a light source is divided into R, G, and B light beams by a dielectric mirror such as a dichroic mirror, which differs from the microlens array disposed on the light source side of the liquid crystal display panel. Incident at an angle. Each light beam incident on the microlens passes through the microlens and is condensed on the corresponding pixel region according to the incident angle. Therefore, the separated R, G, and B light fluxes are modulated in separate pixel areas and used for full-color display.
[0011]
JP-A-5-249318 discloses a display device that uses a transmissive hologram element corresponding to R, G, and B light instead of using the dielectric mirror, and has a pixel pitch. JP-A-6-222361 discloses an apparatus in which a transmission hologram element is provided with a periodic structure corresponding to the above and functions as a dielectric mirror and a microlens.
[0012]
With respect to resolution, which is another problem of the single-plate type, by adopting the field sequential method, it is possible to obtain a resolution equivalent to that of the three-plate type with a single liquid crystal display panel. The field sequential method uses a phenomenon (continuous additive color mixture) in which the colors of each image displayed in a time-division manner are formed by additive color mixing by switching the color of the light source at a speed that cannot be resolved by human vision.
[0013]
A projection-type image display apparatus that performs full-color display by a field sequential method has a configuration shown in FIG. 41, for example. In this display device, a disk composed of R, G, and B color filters is rotated at high speed in accordance with the vertical scanning period of the liquid crystal display panel, and an image signal corresponding to the color of the color filter is supplied to a drive circuit for the liquid crystal display panel. Enter them sequentially. The human eye recognizes a composite image of each color.
[0014]
According to such a field sequential display device, unlike the single-plate method, R, G, and B images are displayed in a time-sharing manner on each pixel of the liquid crystal display panel. .
[0015]
As another display device of the field sequential method, a projection type image display device that irradiates different regions of a liquid crystal display panel with R, G, and B light fluxes is disclosed in IDW'99 (P989 to P992). In this display device, white light emitted from a light source is separated into R, G, and B light fluxes by a dielectric mirror, and different regions of the liquid crystal display panel are irradiated with the R, G, and B light fluxes. The light irradiation positions of R, G, B on the liquid crystal display panel are sequentially switched by rotating a cube-shaped prism.
[0016]
Further, in the projection type image display device described in JP-A-9-214997, a liquid crystal display device similar to the liquid crystal display device described in JP-A-4-60538 is used, and the same method is used. The white light is divided into luminous fluxes for each color, and each luminous flux is incident on the pixel region at different angles. In this projection type image display device, each frame image is time-divided into a plurality of sub-frame images and synchronized with the vertical scanning cycle of the liquid crystal display panel in order to realize both improvement of light utilization efficiency and high resolution. The incident angle of the light beam is periodically switched.
[0017]
[Problems to be solved by the invention]
However, according to the devices described in the above Japanese Patent Laid-Open Nos. 4-60538, 5-249318, and 6-222361, the brightness is certainly improved. Remains 1/3 of the three-plate type. The reason is that three pixels for R, G, and B, which are spatially separated, are used as one set to display one pixel (dot).
[0018]
On the other hand, in the case of the normal field sequential method, the resolution is improved to the same level as the resolution of the three-plate type. However, the brightness of the image has the same problem as the conventional single plate type.
[0019]
On the other hand, in the case of the above-described display device described in IDW'99, it is necessary to prevent the R, G, and B light irradiation positions from overlapping each other. For this purpose, illumination with extremely excellent parallelism is required. I need light. Therefore, the light use efficiency is reduced due to the restriction of the parallelism of the illumination light.
[0020]
As described above, none of the above-described conventional technologies achieves improvement of both brightness and resolution, which are problems of a single plate type.
[0021]
The present applicant has disclosed a projection type image display apparatus intended to solve the above-mentioned problems in Japanese Patent Laid-Open No. 9-214997. According to the display device disclosed in Japanese Patent Laid-Open No. 9-214997, it is necessary to sequentially switch the incident angle of the light flux with respect to the liquid crystal panel in synchronization with the vertical scanning period of the liquid crystal panel. In this apparatus, in order to perform such switching, it is necessary to secure a special space between the liquid crystal display panel and the light source, and to drive two sets of hologram elements and mirrors there.
[0022]
In such a display device, a plurality of movable parts are necessary to switch the incident light angle, and the control thereof is complicated. Further, since each pixel of the liquid crystal display panel sequentially displays all the colors, it is not possible to perform adjustment for each color on the liquid crystal display panel.
[0023]
The present invention has been made in view of the above circumstances, and its main object is to provide a projection-type image display device that realizes bright, high-resolution and uniform display and is suitable for downsizing and cost reduction. There is to do.
[0024]
[Means for Solving the Problems]
A projection-type image display apparatus according to the present invention includes a light source, an image display panel having a plurality of pixel regions each capable of modulating light, and light from the light source in the plurality of pixel regions according to a wavelength region. A projection-type image display apparatus comprising: a light control unit that focuses light on a corresponding pixel region; and an optical system that forms an image on a projection surface with light modulated by the image display panel, A circuit that generates data of a plurality of sub-frame images from data of each frame image constituting the image, and displays the plurality of sub-frame images in a time division manner by the image display panel, and the display that is displayed by the image display panel An image shift element for shifting a subframe image selected from the plurality of subframe images on the projection surface, and switching the display of the subframe By performing line scanning of the image display panel and performing a shift operation by the image shift element in synchronization with the switching, light beams belonging to different wavelength regions modulated in different pixel regions of the image display panel are used. The same area on the projection surface is sequentially irradiated.
[0025]
In a preferred embodiment, the sub-frame shift direction on the projection surface is the same as the scanning direction of the image display panel.
[0026]
In another preferred embodiment, a shift direction of the sub-frame on the projection surface does not coincide with a scanning direction of the image display panel.
[0027]
It is preferable that the shift amount of the sub-frame on the projection surface is a substantially integer multiple of the pixel pitch measured along the shift direction on the projection surface.
[0028]
In a preferred embodiment, the image shift element includes a refractive member that shifts a path of light modulated by the image display panel by refraction, and a relative positional relationship of the refractive member with respect to the light modulated by the image display panel. The refraction member is composed of a plurality of regions having different shift amounts of the light path.
[0029]
In a preferred embodiment, the refractive member is composed of a rotating plate having a plurality of transparent regions having at least one of a refractive index and a thickness, and is arranged so as to obliquely cross a light path modulated by the image display panel. The rotating device is rotatably supported, and the driving device rotates the rotating plate so that a plurality of transparent regions of the rotating plate sequentially traverse the light path.
[0030]
It is preferable that a timing at which each boundary of the plurality of transparent regions crosses the light path is synchronized with a timing for switching the display of the subframe.
[0031]
In a preferred embodiment, the refractive member is composed of a transparent plate having a plurality of transparent regions having at least one of a refractive index and a thickness, and is arranged so as to obliquely cross a light path modulated by the image display panel. The drive device is movably supported and moves the transparent plate so that a plurality of transparent regions of the transparent plate sequentially traverse the light path.
[0032]
It is preferable that a timing at which each boundary of the plurality of transparent regions crosses the light path is synchronized with a timing for switching the display of the subframe.
[0033]
In one embodiment, the boundaries of the plurality of transparent regions are perpendicular to the direction of line scanning of the image display panel.
[0034]
In one embodiment, an angle between the main surface of the rotating plate or the transparent plate and the optical axis is set in a range of 45 ° to 88 °.
[0035]
On the projection surface, it is preferable that the speed at which the display area of the sub-frame image increases and the speed at which the shift area by the image shift element increases coincide.
[0036]
For each row of the pixel area, the time interval between the start of scanning and the start of optical path shift by the image shift element may be variable or may be set in advance.
[0037]
In one embodiment, the start of the optical path shift by the image shift element is executed later than the start of scanning for each row of the pixel region.
[0038]
In one embodiment, the refractive member has a light shielding region between two adjacent regions of the plurality of regions.
[0039]
In one embodiment, each of at least two transparent regions of the plurality of transparent regions corresponds to two consecutive subframe images.
[0040]
It is preferable to have a correction element that compensates for differences in optical path lengths in the plurality of regions of the refractive member.
[0041]
In one embodiment, the image shift element includes at least one optical device that shifts a path of light modulated by the image display panel, and the optical device modulates a polarization direction of light. And a second element having a different refractive index depending on the polarization direction of light.
[0042]
The image shift element includes at least one optical device that shifts a path of light modulated by the image display panel, and the optical device is a liquid crystal that exhibits two or more different refractive indexes with respect to polarized light. A layer and two substrates sandwiching the liquid crystal layer;
A minute prism or a diffraction grating is formed on the liquid crystal side surface of one of the two substrates.
[0043]
In one embodiment, the micro prism or diffraction grating is formed of a material having a refractive index substantially equal to a refractive index of at least one of the two or more refractive indexes.
[0044]
DETAILED DESCRIPTION OF THE INVENTION
In the present invention, for example, in a single-plate projection-type image display device that does not use a color filter, data of a plurality of subframe images is generated from data of each frame image constituting the image, and a plurality of subframe images are generated by an image display panel. Is displayed in time division. Then, by sequentially shifting these sub-frame images on the projection surface, light (R, G, B light) belonging to different wavelength regions modulated in different pixel regions of the image display panel is projected on the projection surface. The same area is sequentially irradiated, thereby realizing a high-resolution full color display.
[0045]
In the case of the present invention, when focusing on a specific area corresponding to one pixel on the projection surface, the specific area is, for example, red in a display period of a certain subframe (hereinafter referred to as “subframe period”). Irradiated with light (R light), irradiated with green light (G light) in the next subframe period, and further irradiated with blue light (B light) in the next subframe period. become. Thus, according to the present invention, the color of each pixel on the projection surface is defined by time-division irradiation of R, G, and B light.
[0046]
There is a significant difference between the projection color image display device of the conventional field sequential method and the present invention as described below.
[0047]
In the case of the conventional field sequential method, the image display panel is illuminated alternately with R, G, and B light. Therefore, in one subfield period, all the pixel regions of the image display panel are irradiated with any one of R, G, and B lights. As a result, each sub-frame image on the projection surface is composed of pixels composed of one color of R, G, and B light, but the sub-frame for R image, the sub-frame for G image, and the B image Since the sub-frames are displayed in a time-division manner in units of time shorter than the human visual time resolution, a color image is recognized by the human eye by the afterimage.
[0048]
On the other hand, each of the subframe images used in the present invention is configured by a combination of R, G, and B lights, as will be described in detail later. That is, in a certain subframe period, the projection surface is illuminated by R, G, and B light modulated by the image display panel. The R, G, and B lights modulated by the image display panel irradiate different positions on the projection surface for each subframe period, and are temporally synthesized to display a full-color frame image.
[0049]
In the present invention, such temporal combination of R, G, and B light is performed by an image shift element. The image shift element is disposed between the image display panel and the projection surface, and periodically and regularly changes the light path (optical path) modulated by the image display panel.
[0050]
The scope of application of the present invention is not limited to a projection type image display device, and is preferably applied to a direct-view type image display device such as a viewer or a head-mounted display. By way of example, a preferred embodiment of the present invention will be described.
[0051]
First, an apparatus configuration according to the first embodiment will be described with reference to FIG.
[0052]
(Embodiment 1)
The projection-type image display apparatus according to the present embodiment includes a light source 1, a liquid crystal display panel 8, a light control unit that focuses light from the light source 1 on a corresponding pixel area of the liquid crystal display panel 8 according to a wavelength range, A projection optical system that projects the light modulated by the liquid crystal display panel 8 onto the projection surface.
[0053]
The projection-type image display device further includes a spherical mirror 2 that reflects light (white light) emitted backward from the light source 1 forward, a condenser lens 3 that converts light from the light source 1 and the spherical mirror 2 into parallel light fluxes, Dichroic mirrors 4 to 6 for separating the light beam into a plurality of light beams according to the wavelength range are provided. The light reflected by the dichroic mirrors 4 to 6 is incident on the microlens array 7 at different angles depending on the wavelength range. The microlens array 7 is attached to the light source side substrate of the liquid crystal display panel 8, and light incident on the microlens 7 at different angles is collected in corresponding pixel regions at different positions.
[0054]
The projection optical system of the present projection type image display apparatus includes a field lens 9 and a projection lens 11, and projects a light beam 12 transmitted through the liquid crystal display panel 8 onto a screen (projection surface) 13. In the present embodiment, the image shift element 10 is disposed between the field lens 9 and the projection lens 11. FIG. 1 shows light beams 12 a and 12 b that are shifted by the image shift element 10 in a direction parallel to the projection surface. In order to shift the light flux, the image shift element 10 has only to be inserted at any position between the liquid crystal display panel 8 and the screen 13, and is disposed between the projection lens 11 and the screen 13. Also good.
[0055]
Next, each component of the projection type image display apparatus will be described in order.
[0056]
In the present embodiment, a metal halide lamp having an optical output of 150 W, an arc length of 5 mm, and an arc diameter of 2.2 mm is used as the light source 1, and this lamp is arranged so that the arc length direction is parallel to the drawing sheet. As the light source 1, in addition to the metal halide lamp, a halogen lamp, an ultrahigh pressure mercury lamp, a xenon lamp, or the like may be used. The light source 1 used in the present embodiment emits white light including light in three wavelength ranges corresponding to the three primary colors.
[0057]
A spherical mirror 2 is disposed on the back surface of the light source 1, and a condenser lens 3 having a diameter of 80 mmφ and a focal length of 60 mm is disposed on the front surface of the light source 1. The spherical mirror 2 is arranged so that its center coincides with the center of the light emitting part of the light source 1, and the condenser lens 3 is arranged so that its focal point coincides with the center of the light source 1.
[0058]
With such an arrangement, the light emitted from the light source 1 is collimated by the condenser lens 3 and illuminates the liquid crystal display panel 8. The parallelism of the light that has passed through the condenser lens 3 is, for example, about 2.2 ° in the arc length direction (direction parallel to the paper surface of FIG. 1) and about 1 ° in the arc radial direction.
[0059]
The liquid crystal display panel 8 used in this embodiment is a transmissive liquid crystal display element in which a microlens array 7 is disposed on a transparent substrate on the light source side. The type of liquid crystal and the operation mode are arbitrary, but it is preferable that the liquid crystal can operate at high speed. In this embodiment, the operation is performed in the TN (twisted nematic) mode. The liquid crystal display panel 8 is provided with a plurality of pixel regions for modulating light. The “pixel region” in this specification refers to individual light modulation units spatially separated in the image display panel. Means. In the case of the liquid crystal display panel 8, a voltage is applied to a corresponding portion of the liquid crystal layer by a pixel electrode corresponding to each pixel region, and light modulation is performed by changing the optical characteristics of that portion.
[0060]
In the liquid crystal display panel 8, for example, 768 (H) × 1024 (V) scanning lines are driven in a non-interlaced manner. The pixel areas of the liquid crystal display panel 8 are two-dimensionally arranged on a transparent substrate, and in the case of this embodiment, the pitch of the pixel areas is a value measured along the horizontal direction or a value measured along the vertical direction. 26 μm. In the case of this embodiment, the R, G, and B pixel regions are arranged in a stripe shape along the horizontal direction of the screen, and each microlens has three pixel regions (for R, G, B pixel area).
[0061]
The R, G, and B lights that irradiate the liquid crystal display panel 8 are obtained by separating white light emitted from the light source 1 by dichroic mirrors 4, 5, and 6, as shown in FIG. 8 is incident on the microlens array 7 above at different angles. By appropriately setting the incident angles of the R, G, and B light, as shown in FIG. 2, the microlens 7 appropriately distributes the pixel areas corresponding to the respective wavelength ranges. In the present embodiment, the focal length of the microlens 7 is set to 255 μm, and the angle formed by each light beam is designed to be 5.8 degrees. More specifically, the R light is incident on the liquid crystal display panel 8 perpendicularly, and the B light and the G light are incident on the R light at an angle of 5.8 degrees.
[0062]
The dichroic mirrors 4, 5, and 6 have spectral characteristics as shown in FIG. 3, and selectively reflect green (G), red (R), and blue (B) light, respectively. The wavelength range of G light is 520 to 580 nm, the wavelength range of R light is 600 to 650 nm, and the wavelength range of B light is 420 to 480 nm.
[0063]
In the present embodiment, the dichroic mirrors 4 to 6 and the microlens array 7 are used to collect light of the three primary colors in the corresponding pixel regions. However, other optical means (for example, a light diffraction / spectral function) An imparted transmission hologram) may be used.
[0064]
As described above, since the liquid crystal display panel 8 is driven non-interlaced, 60 frames of images are displayed per second, and the time (frame period) T allocated to each frame is 1/60 seconds, that is, T = 1. / 60 (seconds) ≈16.6 (milliseconds).
[0065]
In the case of driving with interlace, the scanning lines in the screen are divided into even lines and odd lines and displayed alternately, so that T = 1/30 (seconds) ≈33.3 (milliseconds). . Further, the time (one field period) assigned to each of the even field and odd field constituting each frame is 1 / 60≈16.6 (milliseconds).
[0066]
In this embodiment, information (data) of each frame image constituting an image is sequentially stored in a frame memory, and a plurality of subframe images are sequentially formed based on information selectively read from the frame memory. Hereinafter, a method for forming a subframe image will be described in detail.
[0067]
For example, it is assumed that an image of a certain frame (frame image) is an image as shown in FIG. This frame image is to be displayed in color, and the color of each pixel is determined based on data defining the frame image. In the case of interlace driving, an image of a certain field can be handled in the same manner as the “frame image” in the present specification.
[0068]
In the case of a conventional three-plate projection type image display device, data for R, G, and B light is separated for each pixel from the above data, as shown in FIGS. 4 (b), (c), and (d). Then, each data of an R image frame, a G image frame, and a B image frame is generated. Then, using the three image display panels for R, G, and B, the R image frame, the G image frame, and the B image frame are simultaneously displayed and superimposed on the projection surface. FIG. 5A schematically shows a state where R, G, and B image frames are superimposed on a specific pixel on the projection surface 13.
[0069]
On the other hand, in the case of a conventional single-plate projection image display apparatus, R, G, and B pixel regions are provided at different positions on one display panel. Then, based on each of the R, G, and B data, light is modulated in the R, G, and B pixel regions, and a color image is formed on the projection surface. In this case, since the R, G, and B lights are irradiated on the projection surface in a region smaller than the spatial resolution by human vision, the R, G, and B lights are spatially separated from each other. In spite of this, the human eye recognizes that one pixel is formed. FIG. 5B schematically shows the state of irradiation of R, G, and B light for a specific pixel on the projection surface 13.
[0070]
Unlike the conventional method described above, in the present embodiment, R, G, and B lights modulated in different pixel regions of one image display panel 8 are sequentially irradiated onto the same region on the projection surface 13, and the same region. Display one pixel. That is, when attention is paid to an arbitrary pixel on the projection surface 13, the display of the pixel is executed by a method similar to the field sequential method. However, the R, G, and B lights constituting one pixel are greatly different from the conventional field sequential method in that they are modulated in different pixel regions of one image display panel. FIG. 5C schematically shows a state in which R, G, and B lights irradiated in a time division manner are synthesized over one frame period for a specific pixel on the projection surface 13. The screen shown in the left part of FIG. 5C corresponds to three different subframe images on one image display panel 8.
[0071]
As is apparent from FIGS. 5A to 5C, according to the present embodiment, a full color display is realized with the same high resolution and brightness as the three-plate type while using only one display panel. be able to.
[0072]
Next, the configuration of the subframe image will be described in detail with reference to FIG.
[0073]
The left part of FIG. 6 shows data of R, G, and B image frames stored in the R, G, and B frame memories. In the right part of FIG. 6, display subframes 1 to 3 are shown. According to the present embodiment, in the first one-third period (first subframe period) of a certain frame, the image of the display subframe 1 is displayed on the projection surface. In the next one-third period (second subframe period), the image of the display subframe 2 is displayed, and in the last one-third period (third subframe period), the display subframe 2 is displayed. The image of frame 3 is displayed. In the present embodiment, these three sub-frame images are shifted as shown in FIG. 7 and synthesized while being shifted in time. As a result, the original image shown in FIG. Will be.
[0074]
Next, taking the display subframe 1 as an example, the data structure of the subframe image will be described in detail.
[0075]
First, as shown in FIG. 6, the data for the first row pixel area of the display subframe 1 is formed from the data about the first row pixel (R1) stored in the R frame memory. The data for the second row pixel area of the display subframe 1 is formed from data relating to the second row pixel (G2) stored in the G frame memory. The data for the third row pixel area of the display subframe 1 is formed from data relating to the third row pixel (B3) stored in the B frame memory. The data for the fourth row pixel area of the display subframe 1 is formed from data relating to the fourth row pixel (R4) stored in the R frame memory. Thereafter, the data of the display subframe 1 is configured in the same procedure.
[0076]
The data of display subframes 2 and 3 are also configured in the same manner as in display subframe 1. For example, in the case of the display subframe 2, the first row pixel area data is formed from data relating to the first row pixel (B1) stored in the B frame memory, and the second row pixel area of the display subframe 2 is displayed. The data for use is formed from data relating to the second row pixel (R2) stored in the R frame memory. The data for the third row pixel area in the display subframe 2 is formed from data relating to the third row pixel (G3) stored in the G frame memory, and the data for the fourth row pixel area in the display subframe 2 is B. This is formed from data relating to the fourth row pixel (B4) stored in the frame memory.
[0077]
In this way, the data read from each of the R, G, and B frame memories are combined in a preset order, whereby the data of each subframe displayed in a time division manner is generated. As a result, each of the subframe data includes information on all the colors of R, G, and B, but each of R, G, and B is spatially one third of the whole. It only has information about the region. More specifically, in the case of the display subframe 1, the information on R is only related to the pixels in the first, fourth, seventh, tenth rows of the frame image to be formed, as is apparent from FIG. R information about pixels in other rows of the frame image is assigned to display subframes 2 and 3.
[0078]
In the present embodiment, information of the same color is always displayed in each pixel area of the image display panel. However, a frame image can be synthesized by shifting and projecting an image between subframes. it can. As can be seen from FIG. 6, the total number of rows in the pixel area of the image display panel is two rows larger than the total number of rows of pixels constituting one subframe image. These two lines function as image shift margins.
[0079]
Next, a state in which a plurality of shifted subframe images are combined into one frame image will be described with reference to FIGS. 8 and 9.
[0080]
First, referring to FIG. FIG. 8A is a perspective view showing a part of three subframe images projected on a projection surface such as a screen. The display subframes 1 to 3 and the synthesized frame image are schematically shown in order from the left in the drawing. FIG. 8B shows a corresponding pixel region of the pixel display panel, and shows corresponding portions of the display subframes 1 to 3 in order from the left. The third row to the seventh row of the display subframe 1, the second row to the sixth row of the display subframe 2, and the first row to the fifth row of the display subframe 3 are shifted in time on the projection surface. However, one frame image is formed by spatially overlapping.
[0081]
The positions of the R, G, and B pixel regions on the image display panel are fixed as shown in FIG. 8B, but the image shift arranged between the image display panel and the projection surface is performed. The optical path of the subframe image is shifted by the action of the element, and the synthesis of the subframe image as shown in FIG. 8A is achieved.
[0082]
Next, a sub-frame image shift method will be described.
[0083]
In the present embodiment, an image shift element manufactured from a disk-shaped glass plate (refractive member) 20 having three transparent regions A to C as shown in FIG. 9 is employed. The disk-shaped glass plate 20 is made of BK7 glass having a refractive index of 1.52. The transparent region A has a thickness of 0.7 mm, the transparent region B has a thickness of 1.1 mm, and the transparent region C has a thickness. The thickness is set to 1.5 mm. The glass plate is supported so as to be rotatable about the center of the disk, and is arranged so that the main surface of the glass plate forms an angle of 70.2 degrees with the optical axis. FIG. 10 schematically shows a part of a cross section of a glass plate crossing the optical axis. The angle between the plane perpendicular to the optical axis and the principal plane of the glass plate is θ₀, D is the glass thickness, n is the refractive index of the glass_gThen, the shift amount Δx of the optical axis due to refraction is expressed by the following equation.
[0084]
Δx = d · sinθ₀(1-cos θ₀/ (N_g ²-Sin²θ₀)^1/2)
In the present embodiment, the glass thickness d is designed to have a different value in each of the transparent regions A to C, and the shift amount Δx of the optical axis periodically changes as the glass plate 20 rotates. Become.
[0085]
The light beam modulated by the image display panel passes through one of the transparent regions A to C of the glass plate 20 rotated by a driving device (not shown) (not shown) and reaches the projection surface. In the present embodiment, the optical path of the light beam transmitted through the transparent region B is shifted by 26.1 μm with respect to the optical path of the light beam transmitted through the transparent region A. Similarly, the optical path of the light beam transmitted through the transparent region C is shifted by 26.1 μm with respect to the optical path of the light beam transmitted through the transparent region B. Here, the shift amount (= 26.1 μm) is a value converted as a shift amount on the image display panel, and the image shift element is designed to correspond to the vertical pitch of the pixel region. This shift amount can be changed to any other value by adjusting the thickness of each of the transparent regions A to C. For example, if the thickness of each of the transparent regions A to C is increased by 1.4, the shift amount is 26.1 × 1.4 μm.
[0086]
In this embodiment, the direction (shift direction) in which the light flux shift Δx occurs is equal to the vertical direction of the image, but the light flux shift direction may be equal to the horizontal direction of the image or may be an oblique direction. The important point is that the shift amount has a size in units of pixels, and the pixels of each sub-frame image substantially overlap on the projection surface. In other words, the shift amount of the image on the projection surface may be approximately an integral multiple of the pixel pitch measured along the shift direction on the projection surface.
[0087]
In order to make the shift direction of the luminous flux equal to the horizontal direction of the image, for example, the glass plate of FIG. 10 may be rotated by 90 ° about the optical axis so that the luminous flux is shifted along the horizontal direction of the image.
[0088]
FIG. 11 shows a response curve of light transmittance with respect to voltage application in a portion (each pixel region) that modulates light in the image display panel 8. In this embodiment, each pixel region has a structure in which a liquid crystal layer is sandwiched between electrodes, and the response speed of the liquid crystal is finite, so that the light transmittance reaches the maximum value at the moment when voltage application is started. Absent. That is, when the light transmittance reaches the maximum level and the change from the dark state to the bright state is completed, it is delayed from the start of voltage application. There is also a time delay from when the voltage application is stopped until the light transmittance reaches the minimum value (zero).
[0089]
In the present embodiment, as shown in FIG. 8B, it is necessary to display different subframe images for each subframe period on the image display panel. If it takes a long time to switch the display of the subframe image, the brightness of the subframe image is insufficient in the first part of each subframe period, while the subframe period (voltage application period) is completed. Thereafter, the subframe image is unnecessarily displayed for a while. Therefore, even if the subframe image is shifted, the image of the previous subframe is displayed due to the slow response speed of the image display panel, or the image of the previous subframe is overlapped with the image of the next subframe. A frame image is displayed. In such a case, blur or ghost (double image) occurs in the contour or the like in the synthesized frame image.
[0090]
The reason why the bleeding and ghost are generated will be described with reference to FIG. FIG. 12 schematically shows a specific pixel column of a subframe image constituting the nth (n is a positive integer) frame image and a corresponding pixel column of the subframe image constituting the (n + 1) th frame image. Is shown. Each pixel column is moved up and down because the optical path of the sub-frame image is shifted up and down by the image shift element. In FIG. 12, due to a delay in the response of the image display panel, a pixel that is delayed in the transition from the bright state to the dark state is shown. For example, in the first subframe image constituting the nth frame image, the “B” pixel in the bright state is shifted downward by one pixel in the next subframe, but is still completely dark. The state has not changed. Further, in the next subframe, the pixel is further shifted downward by one pixel and completely changed to the dark state. However, in this subframe, the “G” pixel on the subframe remains slightly bright. When such a response delay exists, coloring occurs in the pixel adjacent to the white display pixel (“W” pixel) in FIG. 12 and the pixel separated by one pixel.
[0091]
In order to prevent the occurrence of color blur and ghost due to such a response delay of the image display panel, when the sub-frame image is switched in the image display panel, it is modulated in the pixel region where the response delay occurs. What is necessary is just to prevent light from being projected on the projection surface. For this purpose, only during a period when response delay occurs, a part of the optical path (light path from the light source to the projection surface) is temporarily blocked using a light shielding device such as a liquid crystal shutter or a mechanical shutter, or the light source May be temporarily consumed or reduced.
[0092]
The same problem occurs not only in the period in which the response of the image display panel is delayed, but also in the period in which the display timing of the image display panel and the image shift timing are shifted. For this reason, the optical path may be blocked during a period in which such a timing shift occurs or a period in which a timing shift may occur.
[0093]
Note that, instead of specially using the light shielding device as described above, the image shift element in FIG. 9 may be improved to provide a “light shielding function” to the image shift element itself. For example, as shown in FIG. 13, if the light shielding region 21 is arranged in a portion of the glass plate 20 that crosses the light beam during the response delay period of the image display panel or the timing deviation, the color blur or ghost of FIG. Can be suppressed, and a higher quality image can be obtained. The central angle of the fan-shaped light shielding region 21 is determined according to the response delay of the image display panel. The smaller the ratio of the light shielding region 21 to the entire glass plate 20, the brighter the image displayed on the projection surface.
[0094]
The relationship on the time axis of the period from the start of the image shift to the start of the next image shift with respect to the period from the start to the end of the response of the image display panel, that is, the timing of the image shift period is, for example, It is preferable to adjust as shown in FIG. That is, it is preferable to shift the image in synchronization with a period in which each pixel region of the image display panel shows sufficient brightness.
[0095]
In this embodiment, a TN (twisted nematic) mode liquid crystal display panel is used as the image display panel, but the present invention is not limited to this, and other various modes of liquid crystal display panels may be used. good. If a display panel capable of responding at a higher speed is employed, the area ratio of the light shielding region provided in the image shift element can be reduced, so that a brighter high-quality image can be obtained.
[0096]
According to the projection type image display apparatus of the present embodiment, three sub-frame images are generated in each frame period, and these images are combined while being optically shifted, so that single-plate projection using a conventional color filter is used. Compared with a type image display device, the light utilization rate is greatly improved, and a resolution three times as high can be realized.
[0097]
In this embodiment, a transmissive display panel is used as the image display panel, but a reflective liquid crystal display panel as shown in FIG. 14 may be used. The reflective liquid crystal display panel shown in FIG. 14 is disclosed in, for example, Japanese Patent Laid-Open No. 9-189809. When such a reflective image display panel is used, it is not necessary to separate the white light from the light source with a dichroic mirror, and the transmission hologram on the display panel diffracts and separates the white light into R, G, and B light. Then, the light is condensed on the reflective electrode (pixel electrode) in the corresponding pixel region. The light reflected by the pixel electrode passes through the hologram in accordance with the amount of change in the polarization component. Such a transmission hologram is produced by laminating a holographic lens array layer for R, a holographic lens array layer for G, and a holographic lens array layer for B.
[0098]
Note that in the case of the reflective type, a transistor region can be provided on the back surface side (downward) of the reflective electrode, which is preferable when switching the subframe images collectively.
[0099]
As described above, in the present invention, information of the same color is always displayed in each pixel area of the image display panel. However, by shifting and projecting the selected sub-frame image, each pixel area is displayed for each sub-frame. Information on different positions (pixels) can be displayed, resulting in high resolution.
[0100]
(Embodiment 2)
Next, a second embodiment of the present invention will be described.
[0101]
The projection type image display apparatus of this embodiment also has basically the same configuration as that of the first embodiment, and the main difference is in the subframe image shift method. Therefore, only this difference will be described below.
[0102]
In the case of the first embodiment, as shown in FIG. 12, the direction in which the subframe image constituting the (n + 1) th (n is a positive integer) frame image is shifted is the subframe image constituting the nth frame image. In this embodiment, as shown in FIG. 15, the direction in which the subframe image constituting the (n + 1) th frame image is shifted is the subframe constituting the nth frame image. It is opposite to the direction of shifting the image. That is, in the nth frame, the subframe image is shifted downward, and in the (n + 1) th frame, the subframe image is shifted upward. Moreover, in this embodiment, the first subframe image of the (n + 1) th frame and the last subframe image of the nth frame are projected at the same position on the projection surface.
[0103]
In this embodiment, one period of image shift is equal to two frame periods, and only four image shifts occur within the two frame periods. For this reason, it is possible to reduce image quality degradation that may be caused by a response delay of the image display panel or a shift in timing of image shift. Further, there is no color pixel other than the adjacent pixels, the subfield in which the color pixel is generated is reduced to two thirds compared to the case of the first embodiment, and no ghost is generated.
As described above, in order to prevent the sub-frame image from being shifted at the time of frame switching, the effect of the image shift element on the light flux is changed between the last sub-frame in each frame and the first sub-frame in the next frame. The same condition may be used or the movement of the image shift element may be stopped.
[0104]
An example of an image shift element for performing such image shift is shown in FIG. The image shift element includes a glass plate 22 having transparent regions A to F. Transparent regions E and F are formed from FK5 glass with a refractive index of 1.49, transparent regions A and D are formed from BaK4 glass with a refractive index of 1.57, and transparent regions B and C are SF2 with a refractive index of 1.64. It is formed from glass. Each transparent region has a thickness of 2.0 mm.
[0105]
The main surface of the disk-shaped glass plate 22 having such a structure is set to make an angle of 65 degrees with respect to the optical axis. And the glass plate 22 is rotated synchronizing the timing which each transparent area crosses an optical path with the timing which switches to the sub-frame corresponding to it. By doing so, the optical path is shifted by 34.0 μm in the transparent areas A and D with respect to the transparent areas E and F, and the optical path is shifted by 26.6 μm in the transparent areas B and C with respect to the transparent areas A and D. To do.
[0106]
It is assumed that the transparent area F corresponds to the first subframe of the nth frame shown in FIG. 15, for example. In this case, the transparent area A corresponds to the next subframe of the nth frame, and the transparent area B corresponds to the last subframe of the nth frame. The transparent area C corresponds to the first subframe of the (n + 1) th frame, the transparent area D corresponds to the next subframe of the (n + 1) th frame, and the transparent area E corresponds to the last subframe of the (n + 1) th frame.
[0107]
Since the transparent region B and the transparent region C have the same refractive index and thickness, the shift amount of the optical path is also the same, and no shift occurs between the two corresponding sub-frame images as shown in FIG. . The same thing occurs between the transparent region E and the transparent region F.
[0108]
Here, for the convenience of explanation, each of the transparent regions B and C and further the transparent regions E and F is divided into two regions (in FIG. 16, they are separated by a broken line). Can be composed of one continuous member. Therefore, the disk-shaped glass plate 22 of FIG. 16 can be manufactured by combining four fan-shaped transparent members.
[0109]
Also in this embodiment, a timing shift may occur between image shift and subframe switching due to a response delay of the image display panel. Therefore, as shown in FIG. 17, it is preferable to provide a light shielding region 21 at an appropriate portion of the glass plate 22. In FIG. 17, the light-shielding region 21 may be provided at the boundary between the two regions to be subjected to image shift (on both sides of the transparent regions A and D).
[0110]
In this embodiment, the TN mode liquid crystal display panel is used as the image display panel, but other various modes of liquid crystal display panels may be used. If a display panel capable of responding at a higher speed is employed, the area ratio of the light shielding region provided in the image shift element can be reduced, so that a brighter and higher quality image can be obtained. In this embodiment, a transmissive display panel is used as the image display panel. However, for example, a reflective liquid crystal display panel as shown in FIG. 14 may be used.
[0111]
Also in the projection type image display apparatus according to the present embodiment, three subframe images are generated in each frame period using an image display panel without a color filter, and these images are combined while optically shifted. Compared with a single-plate projection image display apparatus using the color filter, the light utilization rate is greatly improved, and a resolution three times as high can be realized.
[0112]
Further, since the sub-frame image does not shift at the time of frame switching, color blur and ghost due to the response delay of the image display panel described above can be greatly reduced.
[0113]
(Embodiment 3)
Next, a third embodiment of the present invention will be described.
[0114]
The projection type image display apparatus of the present embodiment also has basically the same configuration as that of the first embodiment, and the main difference is in the configuration of subframe images and the shift method. Hereinafter, this difference will be described.
[0115]
In this embodiment, as shown in FIG. 18, the number of subframe images constituting each frame image is two, and each subframe image is sequentially displayed at two different positions on the projection surface. In each frame, a total of three pixels, that is, a certain pixel in the first subframe image and two pixels in the second subframe image projected in the vicinity thereof, are projected on the projection surface. One pixel is configured. Contrary to this, for the other one pixel adjacent to the one pixel on the projection surface, two pixels in the first sub-frame image and one pixel in the second sub-frame image are reversed. Is synthesized. By doing so, the resolution of the image formed on the projection surface is somewhat reduced, but each frame can be composed of two sub-frames, so there is no need to drive the image display panel at high speed, resulting in a response delay. The resulting color blur is also reduced.
[0116]
In this embodiment, an image shift element configured to display subframe images at two different positions on the projection surface is used. This image shift element is composed of, for example, a glass plate having two types of transparent regions that differ in at least one of refractive index and thickness.
[0117]
In this embodiment, the TN mode liquid crystal display panel is used as the image display panel, but other various modes of liquid crystal display panels may be used. If a display panel capable of responding at a higher speed is employed, the area ratio of the light shielding region provided in the image shift element can be reduced, so that a brighter and higher quality image can be obtained. In this embodiment, a transmissive display panel is used as the image display panel. However, for example, a reflective liquid crystal display panel as shown in FIG. 14 may be used.
[0118]
According to the projection type image display apparatus of the present embodiment, two subframe images are generated in each frame period using an image display panel without a color filter, and the images are combined while optically shifted. Compared with a single-plate projection type image display device using a conventional color filter, the light utilization rate is greatly improved and higher resolution can be realized.
[0119]
(Embodiment 4)
Next, a fourth embodiment of the present invention will be described.
[0120]
The projection type image display apparatus of the present embodiment also has basically the same configuration as that of the first embodiment, and the main difference is in the configuration of subframe images and the shift method. Hereinafter, this difference will be described.
[0121]
In this embodiment, as shown in FIG. 19, the number of subframe images constituting each frame image is two, and each subframe image is sequentially displayed at three different positions on the projection surface. Since each frame can be composed of two sub-frames, it is not necessary to drive the image display panel at high speed, and color blur due to response delay is also reduced.
[0122]
According to this embodiment, as shown in FIG. 19, the number of subframe images constituting each frame image is two, but each subframe image is sequentially displayed at three different positions on the projection surface. Therefore, the image shift cycle is 1.5 times the frame period. As a result, R, G, and B pixel information is superimposed on each pixel on the projection surface, so that an image with higher resolution than in the third embodiment can be obtained.
[0123]
In this embodiment, the two sub-frame images respectively correspond to the sub-frames constituting the original picture frame of the video signal. However, the display timings of the sub-frames constituting the original picture frame of the video signal and the display sub-frames are set. There is no need to match exactly. If the display time of the next subframe is not displayed even though the display of the last subframe composing the original image frame of the video signal is not completed, the video signal of the remaining original image frame is discarded and a new original image frame is formed. Display the first subframe to be displayed. In normal video, there is no significant change in image information between frames or sub-frames, so even if there is a difference between the frequency of the frame to be displayed and the frequency of the original image frame, it can be displayed without a sense of incongruity. Is possible. Therefore, according to the present embodiment, the apparatus configuration can be simplified without greatly degrading the display quality.
[0124]
Unlike the third embodiment, the image shift element according to the present embodiment displays subframe images at three different positions on the projection surface. Therefore, the image shift element used in the first embodiment is used as it is, and its rotation is performed. What is necessary is just to reduce speed to 2/3.
[0125]
In this embodiment, the TN mode liquid crystal display panel is used as the image display panel, but other various modes of liquid crystal display panels may be used. If a display panel capable of responding at a higher speed is employed, the area ratio of the light shielding region provided in the image shift element can be reduced, so that a brighter and higher quality image can be obtained. In this embodiment, a transmissive display panel is used as the image display panel. However, for example, a reflective liquid crystal display panel as shown in FIG. 14 may be used.
[0126]
According to the projection type image display apparatus of this embodiment, two subframe images are generated in each frame period using an image display panel that does not use a color filter, and these images are combined while optically shifted. Compared with a single-plate projection image display device using a conventional color filter, the light utilization rate is greatly improved, and higher resolution can be realized.
[0127]
(Embodiment 5)
Next, a fifth embodiment of the present invention will be described.
[0128]
The projection type image display apparatus of the present embodiment also has basically the same configuration as that of the first embodiment, and the main difference is in the configuration of subframe images and the shift method. Hereinafter, this difference will be described.
[0129]
In this embodiment, the number of sub-frame images constituting each frame image is four, and each sub-frame image is sequentially displayed at three different positions on the projection surface, and the four sub-frame images constituting each frame image are displayed. Two sub-frame images of the frame image are displayed at the same position on the projection surface. That is, the subframe of the present embodiment displays the second subframe in each frame again from the subframe data generated in the same manner as in the first embodiment, and displays each frame from a total of four subframes. The image is composed.
[0130]
Hereinafter, this point will be described in more detail with reference to FIG.
[0131]
The image shift in the present embodiment is performed at a pitch of approximately one pixel, and the first and third subframe images are set upward and downward with reference to the second and fourth subframe images in each frame, respectively. Shifting downward. That is, each frame is composed of four subframes, and one period is shifted by four image shifts.
[0132]
In the present embodiment, since the image is reciprocated with the frame unit as a period, the image can always be shifted to three different positions in units of one pixel. Since the image can always be shifted in units of pixels within the frame and between the frames, the occurrence of ghost can be prevented as shown in FIG.
[0133]
Further, if the fourth display subframe is displayed in black as shown in FIG. 21, the number of display times of each color in each frame becomes equal, so that the color balance between pixels is improved.
[0134]
Each frame may be composed of five or more subframe images. In that case, it is preferable to disperse a plurality of sub-frame images for performing black display in each frame so that the number of display times of each color is the same in each frame.
[0135]
In this way, instead of inserting a sub-frame image to be displayed in black into each frame, two sub-frame images displayed at the same position on the projection surface are composed of sub-frame images with reduced luminance. You may do it. Specifically, the display image signal is corrected so that the total light amount of the second and fourth subframe images in each frame is equal to the light amount of the first or third subframe image. May be. By doing so, the color balance between the pixels is improved, and the pixels are always displayed, so that the flickering feeling is also reduced. Such a correction amount of the display image signal is always the same correction in all pixels and in each frame, and thus can be realized with a simple circuit configuration.
[0136]
As shown in FIG. 22, the image shift element used in this embodiment is composed of a glass plate 23 having four transparent regions. The transparent region A is formed of FK5 glass having a refractive index of 1.49, the transparent regions B and D are formed of BaK4 glass having a refractive index of 1.57, and the transparent region C is formed of SF2 glass having a refractive index of 1.64. Yes. The thickness of each of the transparent regions A to D is 2.0 mm. The glass plate 23 crosses the optical path so that its main surface forms an angle of 65 degrees with respect to the optical axis, and rotates so that each of the transparent regions A to D corresponds to the sub-frame image. Then, with respect to the transparent regions B and D, the light beam is shifted upward by 34.0 μm in the transparent region A, and the light beam is shifted by 26.6 μm in the transparent region C.
[0137]
In this embodiment, the TN mode liquid crystal display panel is used as the image display panel, but other various modes of liquid crystal display panels may be used. If a display panel capable of responding at a higher speed is employed, the area ratio of the light shielding region provided in the image shift element can be reduced, so that a brighter and higher quality image can be obtained. In this embodiment, a transmissive display panel is used as the image display panel. However, for example, a reflective liquid crystal display panel as shown in FIG. 14 may be used.
[0138]
According to the projection type image display device of the present embodiment, four subframe images are generated in each frame period using an image display panel without a color filter, and these images are combined while optically shifted. Compared with a single-plate projection type image display device using a conventional color filter, the light utilization rate is greatly improved, and a resolution three times as high can be realized.
[0139]
As described above, in the projection type image display device of the present invention, each frame image is time-divided into a plurality of subframe images, and the subframe images are superimposed while being shifted to synthesize the original frame images. Yes. The timing for shifting the subframe image is preferably performed in synchronization with the timing for switching the subframe image on the image display panel.
[0140]
There are roughly two types of methods for switching subframe images. The first method is a “line scanning (line scanning) method”. According to this method, a plurality of pixel regions arranged in a matrix in the image display panel are driven every one or several rows, and the upper part of the screen is displayed. A new subframe image is displayed vertically from the bottom to the bottom. A method of scanning the screen by dividing the screen into several blocks is included in the “line scanning method”. On the other hand, the second method is a “surface (batch) writing method”. According to this method, all of a plurality of pixel areas arranged in a matrix on the image display panel are collectively driven, and the entire screen is displayed. At the same time, a new subframe image is displayed. The present invention uses an image display panel driven by a scanning method.
[0141]
(Embodiment 6)
FIGS. 23A to 23G show how the sub-frame image is switched by line scanning on the image display panel. FIG. 23A shows a state in which only the pixel region in the first row of the display panel is switched to display a new subframe image (for example, the second subframe image). At this time, the pixel area in the second and subsequent rows continues to display the old subframe image (for example, the first subframe image). In FIGS. 23B to 23G, the scanning line is moved downward in the screen, and the display area of the new subframe image is enlarged accordingly. In FIG. 23 (g), a new sub-frame image is displayed in the pixel areas of the first to seventh rows.
[0142]
As described above, in the image display panel driven by normal line scanning, the boundary line between the new subframe image and the old subframe image moves every horizontal (1H) period by switching the subframe images. In this case, the voltage application start time in FIG. 11 is shifted at regular intervals for each scanning line (row).
[0143]
Therefore, when an image display panel driven by line scanning is used, it is preferable to synchronize the timing for starting the display of a new subframe image and the timing for starting the optical path shift by the image shift element for each pixel. For this purpose, it is preferable that the speed at which the display area of the new sub-frame image increases (inspection line movement speed) matches the speed at which the shift area by the image shift element increases.
[0144]
Hereinafter, various aspects of the image shift element suitable for such an operation will be described.
[0145]
As shown in FIG. 24, the image shift element of the present embodiment is composed of a glass plate 24 having six transparent regions. Transparent regions A and D are formed from FK5 glass having a refractive index of 1.49, transparent regions B and E are formed from BaK4 glass having a refractive index of 1.57, and transparent regions C and F are SF2 glass having a refractive index of 1.64. Formed from. In all cases, the thickness was unified to 2.0 mm.
[0146]
By inserting this image shift element so that the main surface of the glass plate 24 forms an angle of 65 degrees with respect to the optical axis, the transparent regions B and E are 34.0 μm in the transparent regions A and D, and the transparent region In C and F, the image shifted by 26.6 μm. Each transparent area corresponds to a display subframe. In this image shift element, since the thickness of the glass plate 24 is constant, the image shift element rotates stably and stably even at a high speed.
[0147]
In order to suppress color bleeding due to the response delay of the image display panel described in the above embodiment, it is preferable to provide a light shielding region 21 between the transparent regions as shown in FIG. .
[0148]
Moreover, you may use only cheap BK7 glass as a glass material similarly to the glass plate 20 of FIG. In that case, since the thickness of each transparent region can be selected relatively freely, a more accurate image shift element can be obtained at a low cost.
[0149]
As an improved example of the above-described image shift element, the transparent regions A and D may be constituted by notches in the glass plate 24, and BK7 glass having a refractive index of 1.52 may be used for the remaining transparent regions. In this case, the thickness of the transparent regions B and E is set to 0.7 mm, and the thickness of the transparent regions C and F is set to 1.4 mm. If it is inserted at an angle of 8 degrees, the image shift is 26.0 μm in the transparent regions B and E with respect to the transparent regions A and D, and 26.0 μm in the transparent regions C and F with respect to the transparent regions B and E. Can be realized. By adopting such a configuration, the image shift element can be reduced in weight. In addition, the sub-frame images corresponding to the transparent areas A and D do not pass through the glass, so that there is an effect of being sharpened.
[0150]
As another image shift element, the configuration of the glass plate 24 having six transparent regions may be as follows. That is, the transparent regions A and D are made of FK5 glass having a refractive index of 1.49 and have a thickness of 2.0 mm. The transparent regions B and E are made of BK7 glass having a refractive index of 1.52 and have a thickness of 2.09 mm. The transparent regions C and F are made of SF2 glass having a refractive index of 1.64 and have a thickness of 2.0 mm. In this case, if this glass plate is inserted so as to form an angle of 65 degrees with respect to the optical axis, 25.9 μm in the transparent regions B and E with respect to the transparent regions A and D, and with respect to the transparent regions B and E. In the transparent regions C and F, an image shift of 26.8 μm can be realized. In this way, by selecting a glass plate that is relatively easy to mass-produce and adjusting its thickness, the difference in thickness between the transparent regions is relatively small, while a highly accurate image shift element is inexpensive. Can be manufactured.
[0151]
The main part of the image shift element is composed of a transparent plate made of a glass material, but the image shift element in the present invention is not limited to this. As long as it is a transparent material that causes refraction of the optical path, a resin such as plastic may be used.
[0152]
As described above, in order to shift the optical path of the sub-frame image using the transparent plate inclined with respect to the optical axis, a transparent plate having a plurality of transparent regions having at least one of a refractive index and a thickness different from each other is manufactured. Just do it. The thickness of the transparent plate can be easily adjusted by techniques such as surface polishing and etching.
[0153]
When the main surface of the transparent plate is inclined at an angle of 45 to 85 ° with respect to the optical axis, an appropriate value is selected from the range of refractive index of about 1.45 to 1.7 to achieve the required image shift amount. Is possible. Since the transparent plate having such a refractive index can be formed from a general glass material, an image shift element can be manufactured at low cost.
[0154]
When the main surface of the transparent plate is inclined at an angle of 66 to 88 ° with respect to the optical axis, an appropriate value is selected by selecting an appropriate value for the thickness of the transparent plate from a range of about 0.5 to 2.0 mm. A shift amount can be realized. When the main surface of the transparent plate is inclined at an angle of 61 to 80 ° with respect to the optical axis, the thickness of the transparent plate is in the range of about 0.5 to 2.0 mm, and the refractive index is 1.45 to 1. It is possible to realize a necessary image shift amount by selecting an appropriate value from a range of about .7.
[0155]
(Embodiment 7)
When line scanning is performed in the vertical direction of the screen, the boundary portion (image switching boundary) between the nth subframe image and the (n + 1) th subframe image is formed by a horizontal line segment as shown in FIG. This line segment moves from above to below.
[0156]
When image shift is executed using the rotating plate as described above, the boundary line of the adjacent transparent region (the boundary of the image shift region) in the glass plate 24 is rotated around one point as shown in FIG. For this reason, the boundary line and the sub-frame image switching unit may not be parallel to each other and may shift. When such a shift occurs, a part of the subframe image to be shifted is not properly shifted, and a part of the old subframe image that should not be shifted is shifted.
[0157]
In order to eliminate such harmful effects, as described in the first embodiment, the light emitted from the image display panel is not projected onto the projection surface only during the period in which the timing deviation occurs using various methods. It may be.
[0158]
In the present embodiment, in order to eliminate the above-described adverse effects, instead of providing a light shielding portion, an image shift element is configured from a glass plate 25 having three transparent regions as shown in FIG. The image is shifted by reciprocating in the vertical direction by the driving device.
[0159]
In the present embodiment, the transparent region A of the glass plate 25 is formed of FK5 glass having a refractive index of 1.49, the transparent region B is formed of BaK4 glass having a refractive index of 1.57, and the transparent region C has a refractive index of 1.64. The thickness of each transparent region is set to 2.0 mm. If such a glass plate 24 is inserted into the optical path such that the main surface forms an angle of 65 degrees with respect to the optical axis, the transparent area B is 34.0 μm in the transparent area B and the transparent area B is in the transparent area B. In the transparent area C, an image shift of 26.6 μm is performed.
[0160]
According to the present embodiment, it is possible to make the boundary position of the adjacent transparent region (the boundary of the image shift region) on the glass plate 25 coincide with the boundary of image switching. For this reason, any pixel displaying information of a new subframe image is shifted at an appropriate timing, so that an image with less color blur can be obtained.
[0161]
Even when the image shift element of the present embodiment is used, problems such as color blurring due to response delay may occur depending on the image display panel. In such a case, it is preferable to provide a light shielding region (not shown) at the boundary between the transparent regions A to C shown in FIG.
[0162]
According to the present embodiment, the image shift is performed in synchronization with the image switching while maintaining the scanning lines of the image display panel and the boundary lines of the plurality of transparent regions substantially in parallel. In order to realize such an image shift, in this embodiment, the glass plate 25 as shown in FIG. 27 is reciprocated. However, if the boundary line of each transparent region can maintain a parallel relationship with the scanning line of the image display panel. Other means may be used. For example, the transparent regions A to C shown in FIG. 27 may be formed from separate glass plates 26, and these glass plates 27 may be operated by the driving device shown in FIG. Also by such an operation, the boundary lines of the plurality of transparent regions can be moved in synchronization with the line scanning while maintaining a substantially parallel relationship with the scanning lines of the image display panel. Further, the same effect can be obtained by arranging transparent plates corresponding to the transparent regions A to C on the same optical path and sequentially rotating them so as to come on the optical path.
[0163]
(Embodiment 8)
Next, another embodiment of the image shift element will be described with reference to FIGS. The image shift element according to the present embodiment is composed of a plurality of minute prisms or diffraction gratings designed so that the shift amounts on the projection surface are different, and the image shift element is taken in and out of the optical path. , Perform image shift.
[0164]
First, referring to FIG. In the present embodiment, the prism surface of the minute prism plate formed of glass having a refractive index n1 is covered with a resin material having a refractive index n2. The incident light perpendicular to the non-prism surface (smooth surface) of this micro prism plate is angle θ₁When changing the optical path, the image is shifted by one pixel on the projection surface. Further, the pitch of the pixel area on the image display panel 8 is P, and the distance between the pixel area surface of the image display panel 8 and the prism surface (refractive surface) is Z. In this embodiment, θ₁= Tan^-1The structure of the micro prism plate is designed so as to be (P / Z).
[0165]
In the present embodiment, FK5 glass is used as the material of the microprism plate, and Loctite 363 manufactured by Loctite is used as the UV curable resin on the surface of the prism surface, and the prism surface side is leveled.
[0166]
The pitch P of the pixel area is 26 μm, the distance Z is 5 mm, and the inclination angle of the micro prism is θ₂(= Incident angle of the light beam on the inclined surface of the microprism), θ₃Then, θ₁Becomes 0.3 °.
[0167]
Here, since the refractive index of the glass is n1 and the refractive index of the resin is n2, θ₂And θ₃Is Snell's law (n1 · sinθ₃= N2 · sinθ₂) And θ₂= Θ₃+ Θ₁There is a relationship. Therefore, considering that the refractive index of FK5 glass is 1.487 and the refractive index of Loctite 363 is 1.520, the inclination angle θ of the microprism₂If the angle is set to 13.7 °, a shift amount corresponding to the pitch P can be obtained.
[0168]
In addition, as long as various parameters are selected so as to satisfy the above formula, the present invention is not limited to the materials and numerical values. Also, leveling the prism surface with resin is not essential and may be omitted.
[0169]
When the prism plate or the diffraction grating shown in FIG. 29 is used as an image shift element, the distance between the image display panel 8 and the image shift element is defined by a certain distance Z, and after the above optical design is completed, this distance is set. Cannot be changed to an arbitrary size.
[0170]
In order to obtain an image shift element that can be inserted at an arbitrary position on the optical path without such restrictions, for example, as shown in FIG. 30, the above-described minute prism plates or diffraction gratings may be opposed to each other. What is necessary is just to fill the space between a pair of micro prism plates or a pair of diffraction gratings with a resin material having a refractive index n2 different from these materials. Two microprism plates can be formed from, for example, SF2 glass, and these two microprisms can be bonded together using, for example, UV curable resin Loctite 363 manufactured by Loctite. The distance Z between the minute prism plates is set to 1 mm, for example. In this case, since the refractive index of SF2 glass is 1.64 and the refractive index of Loctite 363 is 1.52, if the inclination angle θ of the micro prism is 19.6 degrees, the shift amount ΔD of the optical path is about 26 μm. Become.
[0171]
In order to display subframe images between three different points on the projection surface, an element 27 in which the elements shown in FIGS. 29 and 30 are combined as shown in FIG. The element 27 is designed so that the region A and the region B have different shift amounts ΔD. If such an element 27 is periodically operated so as not to be inserted into the optical path during a certain subframe period and inserted into the optical path during other subframe periods, an appropriate image shift can be performed.
[0172]
In the example of FIG. 29 and FIG. 30 described above, the light beam shifts in the in-plane direction of the drawing. However, the movement direction of the boundary line of the shift region and the light beam shift direction can be considered independently. The direction is not limited to the example shown.
[0173]
Note that the light flux that passes through the image shift element is irradiated onto the projection surface through different optical paths depending on the transparent area that passes through. For this reason, the optical path length between the image display panel and the projection surface fluctuates for each subframe, and it becomes impossible to focus on images corresponding to all of the transparent regions, resulting in deterioration in image quality. In order to prevent such image quality degradation, a transparent plate that compensates for the optical path length difference caused by the transparent plate of the image shift element is inserted into the optical path, and operates (rotates or moves while synchronizing with the transparent plate of the image shift element). ). Then, uniform image quality can be obtained in each subframe.
[0174]
(Embodiment 9)
Refer to FIG. 32 and FIG. The image shift element shown in the figure includes a first element (liquid crystal element) g1 that modulates the polarization direction of the sub-frame image modulated by the image display panel, and a second element (refractive index different depending on the polarization direction of light). Crystal plate) g2. In this example, it is assumed that light exiting the image display panel is polarized in the vertical direction. When no voltage is applied to the liquid crystal layer of the liquid crystal element g1, as shown in FIG. 32, the polarization plane of the light exiting the image display panel does not rotate in the process of light passing through the liquid crystal element g1. On the other hand, when an appropriate level voltage is applied to the liquid crystal layer of the liquid crystal element g1, as shown in FIG. 33, the polarization plane of light exiting the image display panel is rotated by 90 ° by the liquid crystal layer. .
[0175]
Since the quartz plate g2 has birefringence, the refractive index varies depending on the orientation. In the present embodiment, as shown in FIG. 32, when light having a vertical polarization plane is incident on the quartz plate g2, the light is refracted in the direction in which the abnormal optical axis is inclined in the quartz plate, and the light is shifted in the vertical direction. On the other hand, as shown in FIG. 33, when light having a horizontal polarization plane is incident on the quartz plate g2, the polarization plane is orthogonal to the abnormal optical axis of the quartz plate g2, so that the light is not refracted and the light flux does not shift. . In other words, depending on whether or not a voltage is applied to the liquid crystal element g1, the polarization plane of the light incident on the crystal plate g2 can be controlled to adjust the shift of the luminous flux.
[0176]
Here, suppose that the thickness of the quartz plate g2 is t, and the refractive indexes of the extraordinary light and ordinary light of the quartz plate g2 are n, respectively._e1And n_o1And N_e1Is inclined by 45 ° with respect to the polarization direction of the incident light, the light flux shift amount ΔD is expressed by the following equation.
[0177]
t = ΔD · (2 · n_e1・ N_o1) / (N_e1 ²-N_o1 ²)
From this equation, it can be seen that the shift amount ΔD of the luminous flux is proportional to the thickness t of the quartz plate g2. By adjusting the thickness t of the crystal plate g2, the shift amount of the subframe image can be set to an arbitrary value.
[0178]
In the image shift element of this embodiment, the liquid crystal layer is sandwiched between a plurality of strip-shaped transparent electrodes (not shown) and a counter transparent electrode (not shown), thereby applying an appropriate voltage to a selected region of the liquid crystal layer. Sequential application is possible. For this reason, when this image shift element is used, a voltage can be applied only to a selected region of the liquid crystal layer, and the optical path can be shifted in synchronism with the screen scanning of the line scanning method.
[0179]
(Embodiment 10)
Next, refer to FIG. 34 and FIG. The illustrated element has a liquid crystal layer i5 and two transparent substrates sandwiching the liquid crystal layer i5, and a micro prism array is formed on the liquid crystal side surface of one of the transparent substrates. More specifically, the image shift element of this embodiment has a transparent substrate on which a microprism array i3 whose surface is covered with a transparent electrode i1 and an alignment film i2 is formed, and a surface which is covered with the transparent electrode i1 and the alignment film i2. This is a liquid crystal element in which a nematic liquid crystal layer i5 is sandwiched by a transparent substrate. The liquid crystal layer i5 is homogeneously aligned. When a voltage is applied between the two transparent electrodes i1, the liquid crystal layer i5 is aligned in a direction perpendicular to the substrate as shown in FIG. As shown in 35, it is in a homogeneous orientation state. In other words, the refractive index of the liquid crystal layer i5 when no voltage is applied is expressed as n._e2The refractive index of the liquid crystal layer i5 when a voltage is applied is n_o2And In this embodiment, the refractive index is n._o2The microprism array i3 is formed from a material close to.
[0180]
When no voltage is applied, a difference in refractive index is generated between the liquid crystal layer and the microprism array i3. Therefore, the light beam incident on the microprism array i3 is refracted according to Snell's law. On the other hand, when a voltage is applied, the refractive index difference between the liquid crystal layer and the microprism array i3 decreases according to the magnitude of the applied voltage. As the refractive index difference decreases, the refraction angle of the light beam incident on the microprism array i3 also decreases.
[0181]
The apex angle of the small prism is θ_FourAnd the refractive index of the small prism array i3 is n₂Then, the refraction angle δ of the light beam when no voltage is applied to the liquid crystal layer i5 is expressed by the following equation.
[0182]
δ = (n_e2-N₂) × θ_Four
In order to increase the refraction angle, it is preferable to use a liquid crystal layer having a large refractive index anisotropy.
[0183]
If two of the above elements are combined and arranged as shown in FIG. 36, the image shift element of this embodiment is formed. The image shift amount ΔD by the image shift element is expressed by the following equation, where L is the distance between the two microprism arrays.
[0184]
ΔD = L · tan δ
In the present embodiment, the thickness of the glass plate is 0.5 mm, the interval between the minute prism arrays is 1.0 mm, and the apex angle θ of the minute prism._FourAnd a liquid crystal material of product number BL-009 manufactured by Merck Co. is used. In this case, the refractive index n_e2Is 1.82, refractive index n_o2Is 1.53, and the range of the shift amount ΔD is 0 to 50.7 μm. That is, according to the image shift element of this embodiment, a shift of about two pixels is possible.
[0185]
Instead of the microprism array i3, a diffraction grating having a predetermined grating interval may be provided on the transparent substrate. If an appropriate grating interval is selected according to the wavelength of incident light, light can be diffracted at a desired diffraction angle.
[0186]
In the image shift element of this embodiment as well, the electrode is divided into a plurality of strip portions, and the optical path shift can be realized in synchronization with the line scanning of the screen by sequentially driving the divided portions.
[0187]
The image shift elements described in the ninth and tenth embodiments can be applied to a case where images are switched in units of blocks each composed of a plurality of rows or columns of pixels.
[0188]
(Embodiment 11)
Next, a configuration example of the system of the projection type image display apparatus of the present invention will be described with reference to FIG.
[0189]
As shown in FIG. 37, this system mainly includes a video signal processing circuit 100, an illumination optical system (such as a light source) 102, an image display panel (liquid crystal display element) 104, an image shift element 106, and an image shift element control circuit. 108 and a projection lens 110.
[0190]
Since the illumination optical system 102, the image display panel 104, the image shift element 106, and the projection lens 110 have already been described, in the following, the components of each component will be described with a focus on the video signal processing circuit 100 and the image shift element control circuit 108. Explain the relationship.
[0191]
The video signal processing circuit 100 in this embodiment includes an input signal selection circuit 120, a video demodulation circuit 122, a Y / C separation circuit 124, a scaling circuit 126, a frame rate conversion circuit 128, a frame memory circuit 130, a system control circuit 132, And a color signal selection circuit 134.
[0192]
The input signal selection circuit 120 can receive a plurality of types of video signals, and performs processing according to the types of the video signals. Video signals include signals separated into R, G, and B (RGB signals), luminance signal Y and signals separated into color difference signals BY and RY (Y / C signals), and color carrier signals as color difference signals. And a composite video signal (composite signal) obtained by frequency-multiplexing the color signal C and the luminance signal Y modulated in FIG.
[0193]
The Y / C signal is demodulated by the video demodulation circuit 122 through the input signal selection circuit 120. The composite signal is separated into a luminance signal Y and a color signal by the Y / C separation circuit 124 through the input signal selection circuit 120, and then sent to the video demodulation circuit 122 to be demodulated. The video demodulation circuit 122 outputs an RGB signal demodulated from the video signal.
[0194]
The RGB signal input to the input signal selection circuit 120 and the RGB signal output from the video demodulation circuit 122 are sent to the scaling circuit 126. The scaling circuit 126 converts the number of pixels of various input signals into the number of pixels of the image display panel 104. The frame rate conversion circuit 128 converts the frame rate of the input video signal into a frame rate suitable for the operation of this system.
[0195]
The frame memory circuit 130 is composed of three frame memories that store R, G, and B signals, respectively. Data sequentially read from each frame memory is selected in an appropriate order by the color signal selection circuit 134 and sent to the drive circuit unit of the image display panel 104. The image display panel 104 displays a subframe image based on the data output from the color signal selection circuit 134.
[0196]
The system control circuit 132 controls operations of the input signal selection circuit 120, the frame memory 130, the color signal selection circuit 134, and the image shift element control circuit 108.
[0197]
Based on the signal output from the system control circuit 132, the image shift element control circuit 108 controls the operation of the image shift element 106 so as to synchronize with the display of the subframe image.
[0198]
Next, a procedure for reading data from the frame memory of RGB signals will be described with reference to FIGS. 38 and 39. FIG.
[0199]
Signal write rate to frame memory (frequency f_in) Depends on the input signal, but the rate of signal readout from the frame memory (frequency f)_out) Is defined by the clock frequency of the system. Frequency f_inIs, for example, 60 hertz (Hz) and the frequency f_outIs, for example, 180 Hz.
[0200]
In response to the control signal output from the system control circuit 132, the R signal is read from the R frame memory 130a, the G signal is read from the G frame memory 130b, and the B signal is read from the B frame memory 130c. The read rate of these signals is f as described above._outIn each frame period, the read operation from each of the frame memories 130a to 130c is repeated three times.
[0201]
Reference is now made to FIG. The timing chart shown corresponds to the case where the three types of subframe images shown in FIG. 6 are formed. The numbers described at the top of FIG. 39 are the scanning line numbers of the original picture frame.
[0202]
When the first sub-frame image is displayed on the image display panel, the data stored at the address corresponding to the scanning line number 1 of each of the frame memories 130a to 130c is simultaneously read. Since a start signal is output at this timing, line scanning of the image display panel 104 is started. Data (R, G, and B signals) read from each of the frame memories 130a to 130c is sent to the color signal selection circuit 134 shown in FIG. 38, but only the R signal is selected by the color signal selection circuit 134, and the image It is sent to the display panel 104. The color signal selection circuit 134 has R, G, and B switching elements that operate according to the R, G, and B selection signals, and only the switching element that receives the logic high selection signal outputs an input signal. Communicate to the department. In the example of FIG. 39, only the R signal is selected and given to the first row pixel area (R pixel area) of the image display panel 104.
[0203]
After the elapse of one horizontal scanning period (1H period), the R selection signal changes to logic low and only the G selection signal changes to logic high. For this reason, only the G signal read from the G frame memory among the data stored in the addresses corresponding to the scanning line number 2 of the original picture frame in each frame memory 130a to 130c passes through the color signal selection circuit 134. The image is sent to the image display panel 104. Based on the G signal, display of the second row pixel region (G pixel region) of the image display panel 104 is executed.
[0204]
Thereafter, data for the first sub-frame image is sequentially generated by the same procedure, and the sub-frame image as shown in the upper right of FIG. 6 is displayed on the image display panel.
[0205]
When displaying the second sub-frame image, as shown in FIG. 39, the application timing of the start pulse signal and the selection signal is delayed by 1H period. That is, first, the color signal selection circuit 134 selects the R signal stored in the R frame memory from the data corresponding to the scanning line number 2 of the original image frame. Based on the R signal, the first row image region (R pixel region) is displayed on the image display panel 104. Thereafter, the same operation is repeated, and the second subframe image as shown in FIG. 6 is displayed on the image display panel 104.
[0206]
When displaying the third sub-frame image, the application timing of the start pulse signal and the selection signal is further delayed by 1H period. As a result, the third subframe image as shown in FIG. 6 can be displayed.
[0207]
As described above, instead of shifting the start signal application timing for each subframe, the read start address of the frame memory may be circulated between a plurality of addresses corresponding to the scanning line numbers 1 to 3.
[0208]
In this example, the case where each of the R, G, and B pixel regions is arranged so as to be parallel to the scanning line is described, but the present invention is not limited to such a system. When the above 1H period is replaced with the dot clock cycle, it corresponds to the system operation when using the RGB vertical stripe image display panel in which each of the R, G, and B pixel regions is arranged so as to be orthogonal to the scanning line. To do.
[0209]
The circuit of FIG. 38 does not include a special frame memory for storing subframe image data. However, such a frame memory may be provided to temporarily store the subframe image.
[0210]
Embodiment 12
Hereinafter, an embodiment of a projection-type image display device including two image display panels will be described. As shown in FIG. 40, the projection type image display apparatus according to this embodiment includes a light source 1, a liquid crystal display panel 18, and light from the light source 1 among a plurality of pixel regions of the liquid crystal display panel 18 according to the wavelength range. And a projection optical system that projects the light modulated by the liquid crystal display panel 18 onto the projection surface. Furthermore, the apparatus of the present embodiment includes another liquid crystal display panel 28, and light in a specific wavelength region out of white light emitted from the light source 1 is irradiated onto the liquid crystal display panel 28.
[0211]
The apparatus includes dichroic mirrors 14 to 16, and light in a wavelength region selectively reflected by the dichroic mirror 14 is reflected by the mirror 40 and then irradiated to the liquid crystal display panel 28. On the other hand, the light reflected by the dichroic mirrors 15 to 16 is incident on the microlens array 17 of the liquid crystal display panel 18 at different angles depending on the wavelength range. Light incident on the microlens 17 at different angles is collected in corresponding pixel regions at different positions.
[0212]
The light modulated by the first liquid crystal display panel 18 passes through the field lens 9 a, the image shift element 10, the polarization beam splitter 42, and the projection lens 11, and is then projected on the screen 13. In contrast, the light modulated by the second liquid crystal display panel 28 passes through the field lens 9 b, the polarization beam splitter (or dichroic prism) 42, and the projection lens 11, and is then projected on the screen 13.
[0213]
In the present embodiment, the light modulated by the first image display panel 18 is shifted by the image shift element 10 by the same method as that described in the other embodiments. On the first image display panel 18, for example, two subframe images composed of R and B colors are displayed, and the shift amount between the subframe images is set to be approximately equal to the pixel pitch measured along the shift direction. . The data of each subframe image is created by combining the data (R and B signals) of the R image frame and the B image frame shown in FIGS. 4B and 4D.
[0214]
On the other hand, the second image display panel 28 displays an image composed of only G color, for example. This image has a pattern as shown in FIG. 4C, and reflects G color data regarding all the pixels of the frame image.
[0215]
In the second image display panel 28, since it is not necessary to display an image divided into subframes, the first, for example, the first balance can be used to properly balance the R, G, and B color lights that illuminate the projection surface. It is necessary to compensate the luminance between the image display panel 18 and the second image display panel 28 or to compensate the display period. For example, the display period of the image projected from the second image display panel 28 and projected onto the screen may be limited to about one half of one frame period, or instead the luminance is reduced. May be.
[0216]
According to the present embodiment, only two of the R, G, and B colors are displayed on the first image display panel 18. The remaining colors are displayed on the second image display panel 28. In the first image display panel 18, each microlens separates incident light into two colors and focuses it on the corresponding pixel region. Therefore, the pitch and focal length of the microlenses 17 can be reduced to two-thirds compared to the pitch and focal length of the single-plate microlens 7.
[0217]
As mentioned above, although various embodiment of this invention has been described about the projection type image display apparatus which uses a liquid crystal display element (LCD) as an image display panel, this invention is not limited to this. The present invention is also applicable to a projection type image display apparatus that uses a display element other than a liquid crystal display element, such as a DMD (digital micromirror device), for an image display panel.
[0218]
The present invention can also be applied to a direct-view image display device. In this case, an image display panel that performs full color display using a color filter may be used. In the case of a normal direct-view type that does not use an optical system for image formation, a projection surface such as a screen is not necessary, but in the case of a direct-view type in which an image is viewed through an eyepiece, the retina of the eye is covered by the image. Functions as a projection plane.
[0219]
Furthermore, the present invention can also be applied to a direct-view or projection-type image display device that uses a self-luminous image display element that does not require a separate light source as an image display panel.
[0220]
Further, as an embodiment of the image shift element, an example of an element that periodically changes the optical path by a refractive member or the like has been described. However, the light path or the optical system is moved, thereby changing the optical path. It may be. For example, the image can be shifted even when the projection lens 11 shown in FIG. 1 is vibrated.
[0221]
【The invention's effect】
As described above, in the projection type image display apparatus of the present invention, the light from the light source is divided into, for example, light beams of the three primary colors of R, G, and B, and the light beams of the respective colors are associated with the corresponding pixels of the image display panel. R, G, and B modulation is performed in each pixel region by entering the region. In addition, by sequentially switching the optical path of the emitted light from the image display panel in a time-sharing manner and sequentially switching the display image correspondingly, it is possible to realize a high-resolution color image display while increasing the light utilization rate. It becomes possible.
[Brief description of the drawings]
FIG. 1 is a schematic view of a projection type image display apparatus of the present invention.
FIG. 2 is a schematic cross-sectional view of a liquid crystal display panel.
FIG. 3 is a spectral characteristic of a dichroic mirror.
FIG. 4 is a diagram for explaining a method of generating a color-specific image frame from an original image frame.
FIG. 5 is a diagram for explaining a principle difference between a conventional color display and a color display of the present invention.
FIG. 6 is a diagram for explaining a method of generating three subframe data from data of color-specific image frames.
FIG. 7 is a diagram illustrating an aspect of sub-frame image shift (image shift).
FIG. 8 is a diagram illustrating synthesis of a plurality of subframe images.
FIG. 9 is a front view of a rotating plate constituting the image shift element.
FIG. 10 is a cross-sectional view of a rotating plate constituting an image shift element.
FIG. 11 is a graph showing a response curve of a liquid crystal display panel.
FIG. 12 is a diagram illustrating another aspect of subframe image shift.
13 is a front view of an improved example of a rotating plate constituting the image shift element of FIG. 9. FIG.
FIG. 14 is a cross-sectional view of a reflective liquid crystal display panel.
FIG. 15 is a diagram showing still another aspect of image shift.
FIG. 16 is a front view of still another rotating plate constituting the image shift element.
FIG. 17 is a front view of still another rotating plate constituting the image shift element.
FIG. 18 is a diagram showing still another aspect of image shift.
FIG. 19 is a diagram showing still another aspect of image shift.
FIG. 20 is a diagram showing still another aspect of image shift.
FIG. 21 is a diagram showing still another aspect of image shift.
FIG. 22 is a front view of still another rotating plate constituting the image shift element.
FIG. 23 is a partial front view of an image display panel showing a state in which subframe images are switched by line scanning.
FIG. 24 is a front view of still another rotating plate constituting the image shift element.
FIG. 25 is a front view of still another rotating plate constituting the image shift element.
FIG. 26 is a diagram illustrating that the timing of switching the subframe image and the image shift shift depending on the position of the image.
FIG. 27 is a front view of a transparent plate constituting the image shift element.
FIG. 28 is a diagram illustrating a driving method of the transparent plate of FIG.
FIG. 29 is a cross-sectional view of an image shift element.
FIG. 30 is a diagram illustrating an operation of the image shift element.
FIG. 31 is a front view of an image shift element.
FIG. 32 is a perspective view of an image shift element.
FIG. 33 is a perspective view of an image shift element.
FIG. 34 is a perspective view of an image shift element.
FIG. 35 is a perspective view of an image shift element.
FIG. 36 is a cross-sectional view of an image shift element.
FIG. 37 is a block diagram showing a system configuration example of a projection type image display apparatus according to the present invention.
FIG. 38 is a diagram schematically illustrating a circuit configuration for generating a subframe image.
FIG. 39 is a timing chart showing a procedure for generating a sub-frame image.
FIG. 40 is a configuration diagram showing an embodiment of a projection type image display apparatus using two image display panels.
FIG. 41 is a diagram showing a conventional field sequential projection type image display device.
[Explanation of symbols]
1 Light source
2 Spherical mirror
3 Condenser lens
4, 5, 6 Dichroic mirror
7, 17 Micro lens array
8, 18, 28 Image display panel (liquid crystal display panel)
9 Field lens
10 Image shift element
11 Projection lens
12, 12a, 12b
13 Projection surface
40 mirror
100 Video signal processing circuit
102 Illumination optical system (light source, etc.)
104 Image display panel (liquid crystal display element)
106 Image shift element
108 Image shift element control circuit
110 Projection lens
120 Input signal selection circuit
122 Video demodulation circuit
124 Y / C separation circuit
126 Scaling circuit
128 frame rate conversion circuit
130 frame memory circuit
132 color signal selection circuit
134 System control circuit
g1 First element (liquid crystal element)
g2 Second element (crystal plate)

Claims (20)

A light source;
An image display panel having a plurality of pixel regions each capable of modulating light;
Light control means for condensing light from the light source on a corresponding pixel region of the plurality of pixel regions according to a wavelength range;
An optical system for forming an image on a projection surface by light modulated by the image display panel;
A projection-type image display device comprising:
A circuit for generating data of a plurality of sub-frame images from data of each frame image constituting the image, and displaying the plurality of sub-frame images in a time division manner by the image display panel;
An image shift element that shifts a subframe image selected from the plurality of subframe images displayed by the image display panel on the projection surface;
With
The switching of the display of the sub-frame is performed by line scanning of the image display panel, and the shift operation by the image shift element is performed in synchronization with the switching, thereby being modulated in different pixel areas of the image display panel. Sequentially irradiating the same area on the projection surface with light belonging to different wavelength ranges ,
The image shift element is
Having at least one optical device for shifting the path of light modulated by the image display panel;
The optical device includes a first element that modulates a polarization direction of light and a second element that has a refractive index that varies depending on the polarization direction of light.   The projection type image display apparatus according to claim 1, wherein a shift direction of the sub-frame on the projection surface is the same as a scanning direction of the image display panel.   The projection type image display apparatus according to claim 1, wherein a shift direction of the sub-frame on the projection surface does not coincide with a scanning direction of the image display panel.   The projection type image display apparatus according to claim 1, wherein the shift amount of the sub-frame on the projection surface is substantially an integer multiple of a pixel pitch measured along the shift direction on the projection surface. The image shift element is
A refractive member that shifts the path of light modulated by the image display panel by refraction;
A drive device that periodically changes the relative positional relationship of the refractive member with respect to the light modulated by the image display panel;
The projection type image display device according to claim 1, wherein the refractive member is composed of a plurality of regions having different shift amounts of the light path. The refracting member is composed of a rotating plate having a plurality of transparent regions having different refractive indexes and thicknesses, and is rotatably supported in an arrangement that obliquely crosses a light path modulated by the image display panel. And
The projection type image display device according to claim 5, wherein the driving device rotates the rotating plate such that a plurality of transparent regions of the rotating plate sequentially traverse the light path.   The projection-type image display device according to claim 6, wherein a timing at which each boundary of the plurality of transparent regions crosses the light path is synchronized with a timing of switching the display of the subframe. The refractive member is composed of a transparent plate having a plurality of transparent regions having different refractive indices and thicknesses, and is supported so as to be movable in an obliquely traversing path of light modulated by the image display panel. And
The projection type image display apparatus according to claim 5, wherein the driving device moves the transparent plate so that a plurality of transparent regions of the transparent plate sequentially traverse the light path.   The projection type image display device according to claim 8, wherein the timing at which the boundaries of the plurality of transparent regions cross the light path is synchronized with the timing of switching the display of the subframe.   The projection type image display apparatus according to claim 9, wherein each boundary of the plurality of transparent regions is perpendicular to a direction of line scanning of the image display panel.   The projection type image display apparatus according to any one of claims 6 to 10, wherein an angle between a main surface of the rotating plate or the transparent plate and an optical axis is set in a range of 45 ° to 88 °.   The projection type image according to any one of claims 1 to 11, wherein a speed at which the display area of the sub-frame image is increased and a speed at which a shift area by the image shift element is increased on the projection surface. Display device.   The projection type image display apparatus according to claim 1, wherein a time interval between a scan start and an optical path shift start by the image shift element is variable for each row of the pixel region.   The projection type image display apparatus according to any one of claims 1 to 11, wherein a time interval between a scan start and an optical path shift start by the image shift element is set in advance for each row of the pixel region.   The projection type image display apparatus according to claim 14, wherein the start of optical path shift by the image shift element is executed for each row of the pixel region after the start of scanning.   The projection-type image display device according to claim 5, wherein the refractive member has a light shielding region between two adjacent regions of the plurality of regions.   10. The projection type image display device according to claim 7, wherein each of at least two transparent areas of the plurality of transparent areas corresponds to two consecutive subframe images.   The projection type image display apparatus according to claim 5, further comprising a correction element that compensates for a difference in optical path length in the plurality of regions of the refractive member. The image shift element is
Having at least one optical device for shifting the path of light modulated by the image display panel;
The optical device comprises:
A liquid crystal layer exhibiting two or more different refractive indexes with respect to polarized light;
Two substrates sandwiching the liquid crystal layer;
The projection type image display device according to claim 1, wherein a micro prism or a diffraction grating is formed on a liquid crystal side surface of one of the two substrates. The projection-type image display device according to claim 19 , wherein the microprism or the diffraction grating is formed of a material having a refractive index substantially equal to a refractive index of at least one of the two or more refractive indexes.

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