WO2006054733A1 - Three-dimensional display device - Google Patents

Abstract

A three-dimensional display device comprises a control panel controller for determining an opening order of a minute aperture in a frame period of a stereoscopic image signal, so that the opening order may be random, and for scanning so that the minute opening of a display control panel may be selectively opened for each sub-frame period of the stereoscopic image signal, and a display panel controller for updating a flat image element to be displayed on an image display panel, in synchronism with the scanning of the minute opening, so that the flat image image of a different flat image at a common view point may correspond to the minute opening in the open state.

Description

 Three display devices

 The present invention relates to a three-dimensional display device, and more particularly to a three-dimensional display device for integral 'photography.

Background

 With the release of high-definition TV and other representatives; ^^ Displaying three ^ ¾ display: ^; and the development of stones is under way.

 Integral photography (IP) is known as a method for displaying such a three-dimensional image. Three-dimensional display devices using integral photography include, for example, three image display devices and image display devices (for example, see Special Terms ¾¾e 1-3). ^ In the display, the display control panel has a large number of micros, and on the back side, there are a large number of screens ^ [^ Yes.

 When three-dimensional display is performed on such a display device, a minute (open position of a minute opening / closing sound) is moved (passed), and a small image seen from the relief unit is made to move along a small scale. If there are several small open / close parts in a one-dimensional pixel, three images

To display a movie with a 3D image frame frequency of 30 Hz, N times the frame frequency

(3 O XN) Image with H z: ^ must be done. In other words, one vertical pixel consists of N 2D pixels (hereinafter referred to as 2 ^ ¾images (called elephant elements), and one frame of a 3D image consists of 2 When the frame consists of frames (hereinafter referred to as subframes), the subframe frequency is N times the frame frequency.

 Therefore, if the period of the image bacteria is 100 to 1, OOOH z, the minute movement avoidance is 1 to 10 msec per frame. This kind of periodic image ^ f and Λ [small ^ moves, and the screen flickers (flickering force).

 瞧 1] Japanese Patent No. 2 7 6 1 8 2 9

 [Special dog 2] JP 7-5 6 1 1 2

 [Special dog 3] JP 9-7 3 1 4 3

Disclosure of the invention

 The problem to be solved by the present invention includes the above problem as an example. The present invention has been made in view of the above-mentioned problems, and the object of the present invention is to provide a 3 ^ display device that can display at high speed without generating flickering force and has an excellent solution iiJt. Is to provide.

A stereoscopic image ii¾ display device according to the present invention includes an image panel that displays an image based on a stereoscopic image signal including a flat MB image element obtained by dividing each of a plurality of flat β images of an object viewed from different viewpoints, A display control panel that is arranged at Ι ^ of the display panel and has a minute opening for a flat image element, and a mari! / ^ Plex · Pinhole · Scanning Integral · Photographic 3D image display device that defines the aperture〗 I 醉 so that the aperture jiff of the minute aperture is random within the frame period of the 3D image signal A control panel controller that makes the micro-opening selectively open during each subframe period of the stereoscopic image signal, and a different image of the same viewpoint in synchronism with the micro-opening of the micro-opening The transillumination element is And a display panel controller that acts as a mirror image element displayed on the screen display panel so as to be in JST with respect to the minute aperture in the state.

Brief Description of Drawings

 FIG. 1 is a block diagram schematically showing the configuration of the third table that is Example 1 of the present invention.

 FIG. 2 is a diagram schematically showing the three-dimensional image area (3D display element) of the image key display panel and the display panel.

 Fig. 3 is a diagram dedicated to the 3D display element Qjk on the screen display panel and the 2D display elements that make up the 3D display element.

 Fig. 4 is a diagram schematically showing the configuration of the display control panel and also shows the screen display panel.

 FIG. 5 is a diagram schematically showing a detailed configuration of the 3D control element T jk shown in FIG.

 FIG. 6 is a cross-sectional view taken along line W—W of the 3D control element Tjk shown in FIG.

 FIG. 7 shows one 3D image as eight 2D images: FIG. 7 schematically shows 2D image elements at t-feed.

 Figure 8! K ¾¾ is a view of the panel and the display control panel as viewed from the y direction (that is, above the carrier carrying the display device), and is a view showing viewpoints VP 1, VP 8 and VP 4.

 Figure 9 is similar to Figure 8 and shows the 3D display device from the viewpoint VP 4: ^.

FIG. 10 is a diagram showing a case where the position of the opening is moved from S 4 to S 5 from the state shown in FIG. 9, and the 2D image element is updated in synchronization with the movement of the opening. FIG. 11 is a block diagram for explaining the operation of the display panel and the display control panel in Example 1 of ¾1.

 FIG. 12 is a diagram showing the opening jll 醉 of minute openings (slits) S 1 to S 8 in a playful manner. Figure 13 shows the opening and closing of slits S1 to S8, the readout of image data from video RAM, and

This is a timing chart showing the timing of 2D image element display.

 Fig. 14 shows the 2D¾ ^ elements seen through the slits S1 to S8 from the viewpoint V P 1;

 FIG. 15 is a diagram showing the relationship between the 2D image element and the 3D display element displayed on the 2D display element that can be seen from the viewpoint VP 1 through the slits S 1 to S 8.

 FIG. 16 is a block diagram schematically illustrating the configurations of the controller, the RAM, and the driver in the three display devices according to the first embodiment.

 FIG. 17 is a block diagram illustrating a configuration of a controller, a RAM, and a driver in the three-dimensional display device which is the second difficult example.

 Fig. 18 is a block diagram showing the configuration of the controller, RAM, and driver in the third example: 3: display device.

 Fig. 19 is a diagram showing the order of opening of the minute openings (slits) in Difficult Case 4.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the examples shown below, equivalent components are denoted by the same reference numerals. [Challenge 1]

 FIG. 1 is a block diagram schematically showing the configuration of the third table 10 which is a difficult example 1 of the present invention.

 This display device 10 is Mali! / ^ Plex · Pinhole · Scanning (Multiple X Pinhole Scanning) type 3D display with Integral and Formography (MPS-IP). (3) Display device 10 displays image ii¾. Display panel, row 12, display panel 11 and display panel 'row driver (hereinafter referred to as DP' row driver) 15 and display panel 'column driver (hereinafter referred to as DP column driver). ) 17, Control panel 'row driver (hereinafter referred to as CP' row driver ') that controls display control panel 12 2 1 and control panel' column driver (hereafter referred to as CP 'column driver) 23 Yes. The image it¾display panel 11 is leaked by the DP • row driver 15 via the row signal lines A 1 to Am, and by the DP • column driver 17 via the column signals 〜 Bl˜Bn. The row signal lines A 1 to Am and the signals ^ ϋΒ 1 to Β η correspond to the stereoscopic image element to be viewed. Thus, each of the lines “^ spring A 1 to Am corresponds to one or more shore lines of the picture panel 11, and each of the column signal lines B 1 to B n: one or more of the picture panel 11 Corresponds to the De-Ichiban line.

 Table ^ J panel 12 is driven by CP / row driver 21 via row signals C 1 to Cm and by CP 'driver 23 via column signal lines D1 to Dn.

 The display device 10 is provided with a display panel controller 25 that controls the drivers 15 and 17 to control the screen display, and a control panel controller 25 A that controls the drivers 21 and 23. Yes.

The panel controller 25 controls the display panel 11 based on the 3D image data signal (video signal, overnight signal) VS input from the input terminal 14 of the table 10. The DP column Dino U 7 includes an image RAM (bid 'RAM) 1 8 which is a memory in which image data inputted from the input terminal 14 is written. Further, the control display panel controller 25 of the video RAM I 8 such as writing data to the video RAM 18 and reading data from the RAM I 8 is performed. Control panel controller 2 5 A »¾ ^ Panel controller 2 Continuation of 5 and functions as 3 ^ ¾ display controller. That is, the overall control of the 3D display device 10 including synchronization between the display panel 11 1 and the display control panel 12 2, timing control, etc. in cooperation with the display panel controller 25 and the control panel controller 25 A. Is made.

 As shown in FIG. 2, in the screen display panel 11, there is a region where a small stereoscopic image is displayed in a matrix of m rows and n columns. In the following, a very small 3D display area is described as a 3D display element (or simply a 3D element). As shown in the figure, the print line display panel 11 is exaggerated to be viewed by the nephew with the X direction (¾¾ ^) as the horizontal direction and the y direction as the vertical direction. In the following, an example will be described in which the screen display panel 11 is composed of a monochrome EL display panel using organic electroluminescence (EL) eaves. E L eaves are particularly suitable for 3D display panels because of their high-speed operation capability. When other types of display elements are used, and color display panels using RGB display elements can be easily used.

FIG. 3 shows the configuration of the 3D display element Qjk in any j-th row and k-th column (j = 1 to m, k = l to n) of the screen display panel 11; As shown in Figure 3, the 3D display element Qjk in any j-th row and k-th column (j = l to m, k = l to n) of the image panel 1 1 is further divided into a plurality of flat display elements (2 D Display element). In the following, one 3D display element is composed of eight 2D display elements P1-P8 partitioned in the horizontal direction (X direction). It is explained by taking t pay as an example. In the following, the subscript "jk" etc. is also shown as "j, k" etc. for clarity of description.

 20 display elements? 1—? 8 has been sent to Yu ^ 1 _ | The 2D display element P i (i = l to 8) is connected to the sequence signal Bki. The screen display panel 11 has a configuration in which a plurality of EL elements are arranged in the xy plane, and each EL house is arranged at a position where the spring and the data line force are bitten. 2 D¾ ^ A small flat display is displayed on each element P i. Therefore, row i BA j (J = 1 to m) is a signal line group consisting of one or more overlines in screen display panel 11, and column signal line Bki (i = l to 8) is 1 The Shin ^! Izumi group is composed of two or more data lines, and the Shin ^! Izumi Bk (k = l ～! 1) is a Shin ^!

 FIG. 4 is a diagram schematically showing the configuration of the front panel 12 and also shows the image display panel 11. Table ^! 卿 Panel 12 is a 3D control element T jk (j = 1 to m) arranged corresponding to the 3D display element Qjk (j = 1 to m, k = 1 to n) of the screen display panel 11. , K = 1 ~! Ι)). The display control panel 12 is attached to the front surface of the display panel 11 such that the 3D control element T] ′ k is JiTT with respect to the 3D display element Qjk. In other words, a display device is configured by combining the screen display panel 11 and the display control panel 12. In the following description, a display device that can be obtained is referred to as a 3D display (device).

FIG. 5 is a diagram devoted to showing the detailed configuration of the 3D control element Tjk described above. The 3D control element Tjk (j = l to m, k = l to; α) of the display control panel 12 has slits S 1 to S 8 which are minute ¾¾¾ (hereinafter referred to as a minute opening). . The slits S1 to S8 correspond to the 2D display elements P 1 to P 8 of the image display panel 11, and are slit openings having a rectangular shape with the vertical direction (y direction) as K2; In the example, 3D display is performed using a slit as a minute opening, but 3D display is performed using a display control panel in which pinholes, microlenses, etc. are arranged as minute openings. You can also.

FIG. 6 is a cross-sectional view taken along line W—W of the 3D control element T jk shown in FIG. The 3D control elements Tjk (j = l to m, k = l to n) are provided with shirts SH1 to SH8 that open and close the slits S1 to S8. In addition, the 3D control element Tjk is coupled to an actuator (not shown) such as a piezoelectric element that β β of each of the shirts SHi (i = 1 to 8). For this overnight, the row signal line C j

Connected to these faiths ^! Based on the shirt evening control signal supplied from the CP ′ row driver 21 and the CP ′ column driver 23 through the spring, the shirt evening SHi (i = 1-8) is configured to be reflected. Also, as shown in the figure, the column signal ^! Izumi Dk is a signal line group consisting of a plurality of column signal lines Dki (i = l to 8) force.

 In the present embodiment, a description will be given by taking as an example a case in which a minute opening (slit) of the 3D control element Tjk is difficult using a mechanical shutter, but other minute openings may be used. For example, a liquid crystal panel or the like that can electrically open and close a minute opening can be used. Next, S and:! Operation of 3D display will be described with reference to the drawings. FIG. 7 is a diagram schematically illustrating the principle of 3D display when one 3D image is displayed as eight 2D images. In the 3D¾ ^ element Q jk of the display control panel 12, eight 2D image elements that are elements of the 3D image are displayed.

In more detail, it is seen from 8 directions (8 viewpoints) to obtain the object to be displayed:! Prepare a ^ image (2D image). Each of these 8 2D images is associated with the 3D display element Qjk. 2D image Vjk divided into 2D images (2D divided images) Vjk (p), which corresponds to the minute opening (slit), and has a long side in the vertical direction (y direction) It is divided into 2D image elements Vjk (p, q) of the square dog («). Here, p is an index of JiTT for the above eight viewpoints (VP 1 to VP8), and p = l to 8. Also, q is an index that corresponds to the position of the rectangular 2D image element in the 2D divided image. In the following, 2D divided image Vjk (p) and 2D image element Vjk (p, q) for 3D display element Qjk will be explained. 2D divided image Vjk (p) is abbreviated as V (p), and 2D image element Vjk (p, q) (p = l ~ 8, Q = 1 ~ 8) is expressed as V (p, q). Abbreviated and described. Therefore, V (p, q) is a 2D image element in the age-based 2D divided image V (p) viewed from the p-th viewpoint VP p. More specifically, as shown in FIG. 7, for example, the 2D divided image V (p) viewed from the pth viewpoint is composed of eight 2D image elements V (p, 1) to V (p 8).

 FIG. 8 is a view of the screen display panel 11 and the display control panel 12 in the y direction (that is, three: ^ above the viewer who looks at the display device 10). The rightmost and leftmost viewpoints VP1 and VP8, VP4, force, and other 2D image elements that can be seen through a small opening (eg, slit S4) are shown. Note that only slit S4 is open, and that slit is closed.

The 2D image element V (i, i) is displayed on the 2D display element P i (1 = :! ~ 8) in the 3D display element Qjk of the picture panel 11. Therefore, from the viewpoints VP 4, VP 1, and VP 8, 2D image elements V (4, 4), V (l, l), V (8 (8) displayed on the 2D display elements P 4, Pl, and P 8 respectively. , 8) is visible. In this state, the viewer can get a standing summary by imitating both eyes (left and right). In addition to binocular parallax, moving the viewpoint can also provide standing. Exercise Net II is also obtained. However, since only information from binocular parallax can be obtained from one viewpoint, the plane resolution is as low as 1/8.

 Note that the image that can be seen through the slit has an inverted relationship of 180 ° to the image displayed on the 2D¾ ^ element; The display panel 1 1 is drawn. The ± 3D image data obtained by inverting each 2D image element in advance is input from the input terminal 14 of the table 10. Alternatively, it may be written into the video RAM 18 by the inversion control corresponding to the 2D image element by the display panel controller 25. Alternatively, inversion control may be performed by the display panel controller —25 when reading from the video RAM I 8.

 In the example, the shirt opening S Hi of the minute opening is sequentially switched at high speed, and the slit opening position is switched (moved), and 2D image elements are also synchronized with the scanning of the opening. The following describes the operation.

 FIG. 9 is a diagram similar to FIG. 8, but shows the Nemi VP 4 to 3D display devices (display panel 11 and display control panel 12). The shutter of S H 4 · ¾ ^ is closed and only slit S 4 is open. As described above, the nephew positioned at the viewpoint VP 4 can see the 2D image element V (4, 4) displayed on the 2D display element P 4 through the slit S 4.

Next, as shown in FIG. 10, the shirt evening SH 5 is opened and the shirt evenings other than SH 5 are closed. That is, the position of the opening is moved from S 4 to S 5. The 2D image element is applied in synchronization with the movement of the opening, and the 2D image element V (4, 5) is displayed on the 2D¾ ^ element P5 at a position visible from the viewpoint VP4. In other words, the 2D image element V (4, 5) is jST to the 2D image from the same viewpoint as the 2D image element V (4, 4) that was visible last time. From the viewpoint VP 4, 2D image elements V (4, 4) and V (4, 5) can be seen by switching (moving) the slit opening position and Hff of the 2D image element. By following the above operations for slit apertures S1 to S8, eight 2D image elements V (4, 1) to V (4, 8) can be seen from viewpoint VP4. By performing this operation within the afterimage i¾f of the eye, the 2D divided image V (4) can be seen as a whole. In the same way, by adding 2D image elements that can be seen from other VPs 1 to 3 and VPs 5 to 8, in addition to vertical # ¾ due to binocular movement and movement, the planar solution «is also large. (8 times) Improved.

 Next, the opening operation of the minute opening (slit) and the display operation of the 2D image element will be described in detail with reference to the drawings. FIG. 11 is a block diagram for explaining the operation of the screen display panel 11 and the display control panel 12 in this difficult example. The display panel controller 1 (DP controller) 25 which controls the sleep of the display panel 3 is provided with a tongue L: generating means. The apologize number generation means will be described as an age provided as tongue β26 in the display panel controller 25 by the hardware configuration, but may be provided as software. Further, the tongue tongue «2 6 may be provided in the control panel controller 25 A instead of the display panel controller 25, or provided outside the controllers 25, 25 A. Also good.

 The display panel controller 2 5 and the control panel controller 2 5 A use the tongue ^: generated in the tongue im raw 2 6 to randomize the open river surface of the minute opening, The display control of 2D image elements is performed in response to 3D¾¾. The force and control method will be described below with reference to FIGS. 12 and 13.

Fig. 12 shows the opening sequence of micro openings (slits) S1 to S8. Fig. 13 shows the opening and closing of slits S1 to S8 and the image data from video RAM 18 Reading and 2D image element display · This is a timing chart showing the update timing. Note that the display image data is displayed by line sequential: ^; and the frame frequency is 30 Hz. Therefore, the opening and closing of the minute opening (slit) and the image (bacteria of the 2D image element) are 240 (= 30X8) Hz. That is, the frame period and subframe period are lZ30sec and 1 / 240sec, respectively.

 The display panel controller 25 takes in the frame synchronization signal FS from the input 3D video data signal VS, and sends the fountain control signal generated based on the frame synchronization signal to the DP line driver 15, · Control the line driver 15. The display panel controller 25 controls the DP column driver 17 and the video RAMI 8 and displays the 3D image data obtained by inverting each 2D image element in advance on the display panel 11 as described above.

 The display panel controller 25 generates a subframe synchronization signal SS from the frame synchronization signal FS, and sends the frame synchronization signal FS and the subframe synchronization signal SS to the control panel controller 25A. Alternatively, the control panel controller 25 A may receive the frame synchronization signal FS from the panel controller 25 and generate the subframe synchronization signal SS based on this.

 First, under the control of the display panel controller 25, the tongue im raw β26 generates a tongue ^: that sequentially designates one of the slits S1 to S8 in response to the frame synchronization signal FS. . For example, the sequence (1, 5, 2, 6, 3, 7, 4, 8) is generated.

The control panel controller 25 制 御 controls to open the slit S1 in the first subframe (SF1) based on the first number (1). Image data is read out from the video RAMI 8 in response to the start of the first subframe (SF1). By reading the image data, the 2D image element is displayed on the 2D element P i. At this time, display panel The controller 25 controls the 2D image element V (4, 1) to be displayed on the 2D display element P1 of the 3D display element Qjk that can be seen through the slit S1 from the Nemi VP4.

 Next, the control panel controller 25 A opens the slit S 5 in the second subframe (SF 2) based on the generated random number (the second number (5) described above). Control of displaying the 2D image element V (4, 5) on the 2D¾ ^ element P5 of the 3D display element Qjk as seen through the slit S5 in the same way as: ^ in the first subframe above Make.

 Similarly, in the 3rd to 8th subframes (SF3 to 8), the slits S2, S6, S3, S7, S4, S8 are opened, and the 3D display element Qjk 2D visible through these slits is opened. Display elements P2, P 6, P3, P 7, P4, P 8 and 2D image elements V (4, 2), V (4, 6), V (4, 3), V (4, 7), V ( 4,4), V (4,8) are displayed. By the above operation, eight 2D image elements V (4, 1) to V (4, 8) can be seen from the viewpoint VP 4. By performing this operation within the afterimage retention time of the eye, the viewpoint V P 4 force and the 2D divided image Vjk (4) as a whole can be seen.

As described above, the display control of the 2D image element is controlled by other viewpoints VP 1 to 3 according to the opening and closing (movement of the opening position) of the slits S 1 to S8 in the first to eighth subframes (SF1 to 8). Repeat for 5-8. FIG. 14 schematically shows the 2D display elements visible through the slits S1 to S8. For the sake of explanation, the age at which all of the slits S1 to S8 are opened is illustrated, but as described above, one of the slits is opened and the other slits are closed during the display. To be controlled. For example, for ne ^ and VP1, as shown in Fig. 14, the 2D display elements seen through slits S1 to S3 are the 2D¾ ^ elements of adjacent 3D display elements Qj and k-1, respectively. The 2D display elements P6, P7, and P8 that can be seen through the slits S4 to S8 are 2D display elements P1 to P5 of 3D¾¾ elements Qj and k, respectively. Obedience Therefore, as shown in Fig. 15, 3D display is provided for the 1st to 3rd, 5th and 7th subframes (SF1 to 3, SF5, SF7) of the 1st to 8th subframes (SF1 to 8). 2D display elements P1, P5, P2, P3, and P4 for elements Qj and k, 2D image elements V (l, 1), V (l, 5), V (l, 2), V (l, 3) Display V (l, 4). In the fourth, sixth, and eighth subframes (SF 4, SF6, and SF8), 2D display elements P6, P7, and P8 of adjacent 3D¾¾ elements Qj and k—1 are assigned 2D image elements V (1, 6), V (l, 7), V (1,8) are displayed. V (l, l) to V (1,8) are all 2D image elements (two Vjk (l, l) to Vjk (l, 8)) of the 2D divided image Vjk (l). By this operation, 8 2D image elements V (1, 1) to V (1, 8) from P 1 can be seen in one frame period. Therefore, the 2D divided image Vjk (l) can be seen as a whole from the viewpoint VP 1 within the eye afterimage time.

 Further, for the subsequent frames, the opening river Iff of the slits S1 to S8 is similarly randomized, and display control of 2D image elements is performed according to the opening lim. Such control is performed for all 3D display elements Q j, k and 3D control element T jk.

 Data processing in the display control method described above can be performed as follows. In other words, the display panel controller 25 displays the 2D image elements for JiST against the small opening of the opening river Jim. Based on this, the image data can be rearranged. RAMI 8 addressing control is performed so that RAM 18 is cultivated.

Alternatively, as shown in FIG. 16, the display panel controller 25 has a sorting circuit 27 A, and is configured to crane the image data after sorting into RAMI 8. May be. More specifically, the display panel controller 25 receives the input 3D video display signal VS. The sorting circuit 27 の of the display panel controller 25 sorts 2D image element data corresponding to the opening of the slit. Display panel connector The controller 25 sends the sorted image data VS ′ to the RAM 18 and stores it.

 The opening of the slit may be stored in RAM I 8. Alternatively, the opening river may be stored in a display area controller 25, a Iff page area (not shown) provided in the control panel controller 25A, or another storage area. Note that the opening order is stored in RAM 1 8, as shown in Figure 16, the PD representing the opening river is sent from RAM I 8 to the control panel controller 25 A. It is done.

 The control panel control unit 2 5 A controls the opening of the slits S 1 to S 8 based on the reserved opening jll trace. The display panel controller 2 5 controls the display of the 2D image elements described above with reference to FIGS. 1 2 and 1 3 by controlling the RAM I 8, row dry I 5 and driver 17. Do.

 In this way, by randomizing the opening of the minute opening and controlling the display of the 2D image element according to the opening Mm, it is possible to perform 3D image display without causing a flickering force. In addition, by loading the image data into the RAM based on the display order of the 2D image elements corresponding to the opening of the minute opening, it takes no time to read the data, so the image can be displayed at high speed. Can be performed. Therefore, it is possible to perform high-speed 3D screen demonstrating with the key unlocking ability.

 [Example 2]

 FIG. 17 is a block diagram schematically showing the configuration of the controller, the RAM, and the driver in the three-display device 10 that is Example 2 of the present invention.

«The display control method described in Example 1, that is, the method of randomly displaying the opening of a small opening and performing 2D image element display according to the opening of the opening is, for example, a plurality of screens. It is also possible to execute using a video RAM capable of storing data. In other words, RAM 18 A and 18 B are provided in place of the above-mentioned RAM 18 as shown in FIG. For example, each of the RAMs I 8 A and 18 B has a memory capacity for at least one subframe.

 More specifically, under the control of the display panel controller 25, the 3D image data input from the input terminal 14 is once written in the RAM 18A. Based on the tongue from the tongue L ¾ β 2 6, the display panel controller 1 25 determines that the opening of the slit in the first to eighth subframes (S F 1 to 8) is random. The display panel controller 25 controls the sorting of the image data based on the display order of 2D image elements corresponding to the opening order of the small openings. That is, the image data is stored in the RAM I 8 B in the sorted state: AMI 8 addressing control is performed. That is, for each sub-frame: Image data is stored in a storage position where 2D image elements corresponding to the opening of the small opening are displayed by sequentially reading the image data from AM I 8 B .

In addition, the display panel controller 25 sends the opening of the slit to the control panel controller 25 A. The control panel controller 25 A opens the slits S1 to S8 based on the opening I 醉. That is, the display panel controller 25 and the control panel controller 25 A swing to perform the opening control of the slits S 1 to S 8 and the display control of the 2D image element. By controlling the display panel controller 25 and the control panel controller 25 A, the display control of the 2D image element described with reference to FIGS. 12 and 13 can be performed. A 3D screen can be displayed without force. In addition, the image data is stored in RAM based on the 2D image elements corresponding to the opening of the minute opening. As a result, it does not take time to read data, so it can perform images at high speed. Therefore, it is possible to solve the problem and to display 3D images at high speed.

 [Challenge 3]

 FIG. 18 is a block diagram schematically showing the configuration of the controller, RAM, and driver in the three table 10 which is the third difficult example 3 of the present invention.

 In this difficult example, the display panel controller 25 has a circuit and a header raw β (hereinafter referred to as a header raw β) 2 7 Β. The header generator 2 7 を sorts 2D image element data corresponding to the opening II 醉 of the minute opening (slit), and also opens the slit opening for 2D image element data. Generate header information (hereinafter simply referred to as the header) that represents. That is, the header header β2 7 generates a 3D image data signal VH in which the header related to the 2D image element data is attached to the sorted 2D image element data. The display panel controller 25 sends the image data VH, to which the header has been activated after the sorting, to the RAM I 8 to control it.

The control panel controller 25 A reads the header stored in the RAM I 8 and performs opening control of the slits S 1 to S 8 based on the opening river head indicated by the header. The display panel controller 25 controls the RAM I 8, row driver 15 and Ό ^ Ό driver 17 to control the 2D image as described with reference to FIGS. Do the element legs. In this way, the opening of the minute opening (slit) is used as a header for 2D image data and stored in the memory, and when the image data is read, the opening position (opened) is based on the header information. (Slit) can be discriminated, and display control with random apertures can be performed at high speed. Therefore, it is possible to perform 3D display without causing flickering at high speed. Yes, I can get J point. In addition, the memory capacity can be reduced, and the cost can be increased at a low cost. It is possible to display images.

 [Challenge 4]

 FIG. 19 is a diagram schematically illustrating the opening II of the minute opening (slit), which is the fourth difficulty of the present invention.

 In the above-mentioned difficult cases, the slit opening II 醉 has been described as randomized, but it is not necessarily random. For example, interlaced display control may be performed in which the even-numbered slits are sequentially opened after the ¾m-th slit is sequentially opened. Below, the display control for the viewpoint VP4 with respect to jST will be described with reference to FIG.

 The control panel controller 25 A controls to open the slit S 1 in the first subframe (S F 1). At this time, the display panel controller 25 performs control to display the 2D image element V (4, 1) on the 2D display element P1 of the 3D display element Qjk that can be seen from the viewpoint VP4 through the slit S1.

 Next, the control panel controller 25A opens the next slit S3 in the second subframe (SF2). The display panel controller 25 performs control to display the 2D image element V (4, 3) on the 2D display element P3 of the 3D display element Qjk that can be seen from the viewpoint VP4 through the slit S3. Similarly, the control panel controller 25A opens slits S5 and S7 in the third and fourth subframes (SF3, SF), and the display panel controller 25 is visible through the slits S5 and S7. Display 2D image elements V (4,5) and V (4,7) in elements P5 and P7.

When the display control is finished for the second slits Sl, S3, S5, and S7, the same display control is performed for the even-numbered slits S2, S4, S6, and S8. Such interlaced display control can also display 3D images without causing a flickering force. Furthermore, since the opening 1 mm is determined in advance, display control can be performed at high speed and simply. Therefore, it is necessary to perform high-speed 3D image ^ which is low cost and easy to unlock.

 In the various difficult cases described above, the control panel uses a display panel in which the 2D display element P i is arranged in the (X direction) and a small opening (slit) jS ”for the 2D display element. We have explained the ± salary provided (Fig. 3), but it is easily applied to the ± ship placed in 2. For example, 2D display elements are arranged in a matrix in the X and y directions. 3D display element Qjk, the control panel corresponds to the 2D display element, and 3D control element T] 'with minute openings (pinholes, etc.) arranged in a matrix in the X and y directions If it consists of k, it is easy to use the T ability.

 It should be noted that the above-described embodiments can be combined. In addition, the numerical values shown in the male examples are only examples, and can be drowned as M ^.

Claims

The scope of the claims

 1. An image panel that displays based on a stereo image signal that includes Toru's flat image elements obtained by dividing each of Toru's flat images viewed from different viewpoints, and a selfish image panel. A display control panel that covers the microscopic aperture of iST with respect to a flat image element, and a 3D image display device comprising: a multiplex, a pinhole, a scanning type integer, and a photographer ¾;

 The self-defining aperture II 醉 is determined so that the aperture ff of the modest microscopic aperture within the frame period of the stereoscopic image signal is random, and the microscopic aperture is selectively selected every subframe period of the stereoscopic image signal. A control panel controller that forms a ¾ to be open;

 In synchronization with the leaked microscopic aperture, the horizontal image element displayed on the screen display panel so that different transilluminated elements of the same perspective image from the same viewpoint are opposed to the microscopic aperture in the open state. A display panel controller that meets the requirements of a three-dimensional image device.

 2. Opening of self-defining microscopic aperture II II has memory that is frT together with the image data of the self-stereoscopic image signal. The scanning of the opening is performed, and the Kenji display panel controller is configured to perform J † of the image element based on the image data stored in the Kamiki memory. 3D image ii¾ display device.

 3. Opening of self-defining micro-opening II There is a part that arranges the image data of the lame image signal according to II 醉, and a memory that stores the inferior image data. The three-dimensional image display device according to claim 1, wherein the 3¾-display panel controller uses a number as a part of the normal transform element based on the image data stored in the selfish memory.

4. The first memory that stores 1 subframe of the image data of the 3D image signal, and the image data displayed in the 1st memory. Image lined up And a second memory for storing data, and the display panel controller is configured to make a trap of the Kagami plane transform element based on the image data stored in the second memory. 3D image # ^ device described in 1.

 5. An image panel that displays images based on a 3D image signal that includes multiple flat image elements obtained by dividing each of multiple transversal images of an object viewed from different viewpoints, and a disgusting panel 15 ^ This is a 3D image display device of multiplex, pinhole, scanning integral, photography ^ ζ, which is composed of a front panel with a small opening for the self-translated element, and And

 A control panel controller that controls the microscopic openings so that the opening order of the microscopic openings is interlaced within the frame period of the stereoscopic image signal;

 Synchronized with the folds of the microscopic aperture of the knitting self, the transversal image displayed on the selfish display panel so that different transversal elements of the planar image of the same viewpoint are ji to the microscopic aperture of the open state. A display panel controller that forms a wisteria of elements,