JP2009145829A - Pseudo stereoscopic display apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pseudo stereoscopic display apparatus capable of reducing flickers, thereby achieving a pseudo stereoscopic display. <P>SOLUTION: The pseudo stereoscopic display apparatus includes: a plurality of display sections; a reflecting mirror that reflects images displayed on the display sections toward observing positions. The display apparatus makes the image signals displayed by the display sections different from one another and changes a display image every predetermined period. A pseudo-stereoscopic display apparatus includes: a display section, a mirror that reflects an image displayed on the display section toward an observing position; and an angle varying means for changing the angle of the mirror. The display period for one field of an image signal is composed of a plurality of sub-fields. The display apparatus switches one image signal to another image signal different according to a sub-field and changes the angle of the mirror in synchronism with the corresponding sub-field. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a pseudo-stereoscopic display device that displays a stereoscopic image.

As a pseudo three-dimensional display device, a half mirror is arranged between the display device and the three-dimensional object to be observed, and the viewer reflects the display image of the display device reflected by the half mirror to the direct light of the three-dimensional object that has passed through the half mirror. There is a display device that superimposes reflected light (Patent Document 1). In this display device, the reflection angle of the half mirror is changed by an angle control mechanism. As a result, the display image of the display device superimposed on the three-dimensional object is composed of the near-field image reflection light and the far-field image reflection light in front and behind the three-dimensional object according to the angle change of the half mirror, and the observer displays It can be seen as if a three-dimensional object exists in the background of the image.
Japanese Patent No. 3521930

  However, in such a conventional pseudo stereoscopic display device, a configuration in which a pseudo stereoscopic image display is performed by switching a video signal for each field and changing a mirror angle in synchronization with the field is shown. Due to the switching, the flicker is conspicuous, which is insufficient as a pseudo stereoscopic display image.

  The problems to be solved by the present invention include the above-mentioned problems as an example, and it is an object of the present invention to provide a pseudo-stereoscopic display device that enables pseudo-stereoscopic display by reducing flicker.

  A pseudo stereoscopic display device according to a first aspect of the present invention is a pseudo stereoscopic display device including a display unit and a mirror that reflects an image displayed on the display unit toward an observation position. A plurality of display units are used, and video signals displayed on each of the plurality of display units are made different from each other, and a display image is changed at a predetermined cycle.

  According to a third aspect of the present invention, there is provided a pseudo-stereoscopic display device comprising: a display unit; a mirror that reflects an image displayed on the display unit toward an observation position; and an angle variable unit that changes an angle of the mirror. A pseudo-stereoscopic display device, in which a display period of one field of a video signal is configured by a plurality of subfields, and each subfield is switched to a different video signal and the angle of the mirror is changed in synchronization with the subfields. It is characterized by letting.

  In the pseudo-stereoscopic display device according to the first aspect of the present invention, the display images of each of the plurality of display units are reflected through the mirror to reach the observer at the observation position, and the virtual images of the different display images of each of the plurality of display units. Are spatially synthesized so that the viewer can see them as one image. In addition, a stereoscopic effect can be given depending on the perspective according to the arrangement position of each display unit, the angle of the mirror is fixed, and the display image changes at a predetermined cycle, so that occurrence of flicker can be prevented.

  In the pseudo-stereoscopic display device of the invention according to claim 3, the display image of the display unit is reflected through the mirror and reaches the observer at the observation position, and the angle of the mirror is changed for each subfield by the angle variable means. In synchronism with this, the display image on the display unit is different, so that the virtual image of the display image is temporally synthesized, so that the observer can see it as one image. In addition, since the video image is switched for each subfield, flicker can be reduced.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows a side view of a pseudo stereoscopic display device to which the invention according to claim 1 is applied. This pseudo-stereoscopic display device includes four display units 1 to 4 and a total reflection mirror 5.

  Each of the four display units 1 to 4 displays a video in accordance with a video signal supplied from a video signal generation unit 6 described later. The four display units 1 to 4 are observed so that the display images of the four display units 1 to 4 are reflected by the reflection surface of the total reflection mirror 5 and reach the eye E (observation position) of the viewer (viewer). The display unit 1 is positioned at the uppermost position, and the display units 2, 3, and 4 are positioned at different positions so as to be positioned in the lower order. The video display surfaces of the display units 1 to 4 are slightly tilted upward on the total reflection mirror 5 side. The total reflection mirror 5 is disposed in front of the observer, and the reflection surface is slightly inclined upward. The video display surfaces of the four display units 1 to 4 are not parallel to each other and have different angles with respect to the vertical direction. The angle increases in the order of the four display units 1 to 4.

  As shown in FIG. 2, the video signal generation unit 6 includes first to fourth video partial extraction units 11 to 14. The same input video signal is supplied to each of the first to fourth video partial extraction units 11 to 14. The video indicated by the input video signal is divided into four by the first to fourth video partial extraction units 11 to 14. The first video portion extraction unit 11 extracts the video signal of only the horizontal band-like first video portion located at the top of the video indicated by the input video signal. The second video part extracting unit 12 extracts only the video signal of the horizontal band-like second video part that continues downward from the first video part in the video indicated by the input video signal. The third video portion extraction unit 13 extracts only the video signal of the horizontal band-like third video portion that continues downward from the second video portion of the video indicated by the input video signal. The fourth video portion extraction unit 11 extracts only the video signal of the horizontal band-like fourth video portion that continues downward from the third video portion of the video indicated by the input video signal. In the first to fourth video portions, there may be a slight overlapping portion at the boundary portion.

  Further, each of the first to fourth video partial extraction units 11 to 14 generates a video signal by extending the extracted video signal to a length of one field (or one frame). In other words, each of the first to fourth video parts is expanded in the vertical direction so as to be displayed on the entire display screen of the four display parts 1 to 4. The video signal indicates 60 frames of video per second.

  In the pseudo-stereoscopic display device having such a configuration, when the input video signal is supplied to the first to fourth video partial extraction units 11 to 14, the video signals are individually transmitted from the first to fourth video partial extraction units 11 to 14. It is supplied to each of the four display units 1 to 4.

  As shown in FIG. 1, the display image of the display unit 1 is reflected by the total reflection mirror 5 and reaches the eyes E of the observer, and the observer can see the virtual image 1a. The display image of the display unit 2 is reflected by the total reflection mirror 5 and reaches the observer's eyes E, and the observer sees the virtual image 2a. The display image of the display unit 3 is reflected by the total reflection mirror 5 and reaches the observer's eyes E, and the observer sees the virtual image 3a. The display image of the display unit 4 is reflected by the total reflection mirror 5 and reaches the observer's eyes E, and the observer sees the virtual image 4a.

  These virtual images 1a to 4a are spatially synthesized and can be viewed as one image by an observer as shown in FIG. As shown in FIG. 1, the virtual images 1 a to 4 a are formed obliquely so that they are farther away from the observer as they are higher, so that one image is displayed in a three-dimensional manner. If the first video part shows a distant view, the second video part shows a mid-scene, and the third and fourth video parts show a close-up view, the observer can feel more stereoscopic.

  The video signal generator 6 that supplies video signals to the display units 1 to 4 includes first to fourth video signal sources 21 to 24 as shown in FIG. The video signals generated by the signal sources 21 to 24 may be supplied individually in synchronization.

  Further, a display period of one field of the video signal supplied to the display units 1 to 4 may be configured by a plurality of subfields, and may be switched to different video signals for each subfield.

  In the above-described embodiment, the number of display units is four. However, the number is not limited thereto, and a plurality of display units may be used.

  FIG. 5 shows a pseudo stereoscopic display device to which the invention according to claim 3 is applied. This pseudo-stereoscopic display device includes a single display unit 7 and a total reflection mirror 8. The total reflection mirror 8 is disposed in front of the observer. As shown in FIG. 5, the total reflection mirror 8 is provided with an angle adjustment mechanism 10 (see FIG. 6) so that the reflection surface is directed upward by four angles θ1 to θ4 with respect to the vertical direction. θ1 <θ2 <θ3 <θ4. The angle adjustment mechanism 10 includes, for example, a step motor.

  The display unit 7 displays a video according to the video signal supplied from the video signal generating unit 9. The display unit 7 is arranged above the position of the eyes E of the observer so that the display image of the display unit 7 is reflected by the reflection surface of the total reflection mirror 8 and reaches the observer, and the image display surface is in the vertical direction. Is directed upward.

  As shown in FIG. 6, the video signal generation unit 9 includes first to fourth video signal sources 31 to 34, a signal switch 35, and a display control unit 36.

  Each of the first to fourth video signal sources 31 to 34 generates the first to fourth video signals. The first video signal source 31 generates a first video signal of only a horizontal belt-like first video portion located at the top of the video to be viewed stereoscopically by the observer. The second video signal source 32 generates a second video signal of only a horizontal belt-like second video portion that continues downward from the first video portion of the video to be viewed stereoscopically to the observer. The third video signal source 33 generates a third video signal of only a horizontal belt-like third video portion that continues downward from the second video portion of the video to be viewed stereoscopically to the observer. The fourth video signal source 34 generates a fourth video signal of only the lowermost horizontal band-like fourth video portion that continues downward from the third video portion of the video to be viewed stereoscopically to the observer. In the first to fourth video portions, there may be a slight overlapping portion at the boundary portion. The first to fourth video signals generated by the first to fourth video signal sources 31 to 34 are expanded to a length of one field (or one frame) so as to be displayed on the entire screen on the display unit 7. Yes.

  The first to fourth video signals generated from the first to fourth video signal sources 31 to 34 are supplied to the signal switch 35. The signal switching unit 35 switches the first to fourth video signals every 1/240 seconds, which is a subfield period, in accordance with a command from the display control unit 36 and outputs it to the display unit 7. For example, the first video signal, the second video signal, the third video signal, and the fourth video signal are output in this order and are repeated.

  The display control unit 36 controls switching of the signal switch 35 and controls synchronization of generation of the first to fourth video signals by the first to fourth video signal sources 31 to 34. In addition, the angle adjustment mechanism 10 is controlled to give tilt angles θ1 to θ4 to the reflection surface of the total reflection mirror 8. When the signal switch 35 selectively outputs the first video signal, the reflection surface of the total reflection mirror 8 is tilted to the angle θ1, and when the second video signal is selectively output, the reflection surface of the total reflection mirror 8 is tilted to the angle θ2. When the three video signals are selectively output, the reflection surface of the total reflection mirror 8 is tilted to an angle θ3, and when the fourth video signal is selectively output, the reflection surface of the total reflection mirror 8 is tilted to an angle θ4.

  In the pseudo-stereoscopic display device of FIG. 5 configured as described above, when the first video signal output from the first video signal source 31 is selected by the signal switch 35, the total reflection mirror 8 is controlled to the angle θ1. As shown in FIG. 5, the first video portion, which is a display video of the display portion 7, is reflected by the total reflection mirror 5 and reaches the observer's eyes E, and the virtual image 7 a is visible to the viewer. Next, when the second video signal output from the second video signal source 32 is selected by the signal switch 35, the total reflection mirror 8 is controlled to the angle θ2. The second image portion, which is a display image of the display portion 7, is reflected by the total reflection mirror 5 and reaches the observer's eyes E, and the observer can see the virtual image 7 b. Next, when the third video signal output from the third video signal source 33 is selected by the signal switch 35, the total reflection mirror 8 is controlled to the angle θ3. The third video portion that is a display video of the display portion 7 is reflected by the total reflection mirror 5 and reaches the eyes E of the observer, and the virtual image 7c can be seen by the observer. Next, when the fourth video signal output from the fourth video signal source 34 is selected by the signal switch 35, the total reflection mirror 8 is controlled to the angle θ4. The fourth video portion, which is the display video of the display portion 7, is reflected by the total reflection mirror 5 and reaches the observer's eyes E, and the virtual image 7d is visible to the observer. The video signal supply switching and mirror angle switching operations are performed synchronously every 1/240 seconds, and when this operation is repeated, the virtual images 7a to 7d are temporally synthesized and the observer sees FIG. As shown, it appears as an image for one frame.

  As shown in FIG. 5, each of the virtual images 7a to 7d is formed obliquely so as to be farther away from the observer, so that the images of the virtual images 7a to 7d are displayed in a three-dimensional manner. If the first video part shows a distant view, the second video part shows a mid-scene, and the third and fourth video parts show a close-up view, the observer can feel more stereoscopic.

  FIG. 8 shows a pseudo stereoscopic display device to which the invention according to claim 4 is applied. This pseudo-stereoscopic display device includes four display units (first to fourth display units) 41 to 44 and a total reflection mirror 45 as in the pseudo-stereoscopic display device of FIG. Similar to the total reflection mirror 8 in the apparatus of FIG. 5, the total reflection mirror 45 is provided with an angle adjustment mechanism 46 so that the reflection surface is directed upward by four angles θ1 to θ4 with respect to the vertical direction. θ1 <θ2 <θ3 <θ4.

  As shown in FIG. 9, the video signal generation unit 49 of the pseudo stereoscopic display device of FIG. 8 includes first to fourth video circuits 51 to 54 for each of the display units 41 to 44 together with the display control unit 50. . The video circuits 51 to 54 include first to fourth video signal sources and a signal switcher, and are configured in the same manner as the first to fourth video signal sources 31 to 34 and the signal switcher 35 of FIG. ing.

  The display control unit 50 controls switching of the signal switch for each of the first to fourth video circuits 51 to 54 and controls the synchronization of the generation of the first to fourth video signals by the first to fourth video signal sources. To do. Further, the angle adjustment mechanism 46 is controlled to give the tilt angles θ1 to θ4 to the reflection surface of the total reflection mirror 45. As shown in FIG. 10, the tilt angle of the total reflection mirror 45 is changed in the order of θ1, θ2, θ3, and θ4 every 1/240 seconds (subfield period) within one field period (1/60 seconds). Further, as shown in FIG. 10, when the tilt angle of the total reflection mirror 45 is θ1, the first video signals a11, a12, a13, a14 from the first video signal source in each of the video circuits 51 to 54 pass through the signal switcher. Are supplied to the display units 41 to 44. When the tilt angle of the total reflection mirror 45 is θ2, the second video signals a21, a22, a23, a24 are supplied from the second video signal source to the display units 41-44 via the signal switcher in each of the video circuits 51-54. The When the tilt angle of the total reflection mirror 45 is θ3, the third video signals a31, a32, a33, a34 are supplied from the third video signal source to the display units 41-44 via the signal switch in each of the video circuits 51-54. The When the tilt angle of the total reflection mirror 45 is θ4, the fourth video signals a41, a42, a43, a44 are supplied from the fourth video signal source to the display units 41-44 via the signal switcher in each of the video circuits 51-54. The

  In the pseudo-stereoscopic display device of FIG. 8 having such a configuration, when a period of one field is started, first, the total reflection mirror 45 is controlled to the angle θ1, and at the same time, for each of the first to fourth video circuits 51 to 54. The first video signals a11, a12, a13, a14 output from the first video signal source are selected by the signal switcher. At this time, as shown in FIG. 8, the first video portion, which is a display image of each of the display portions 41 to 44, is reflected by the total reflection mirror 45 and reaches the observer's eye E. 60a is spatially synthesized and appears as one image. Next, the total reflection mirror 45 is controlled to the angle θ2, and the second video signals a21, a22, a23, and a24 output from the second video signal source for each of the first to fourth video circuits 51 to 54 are simultaneously switched. Selected by the vessel. At this time, as shown in FIG. 8, the second video part, which is a display picture of each of the display parts 41 to 44, is reflected by the total reflection mirror 45 and reaches the observer's eyes E, and the virtual image 57 b ~ 60b is spatially synthesized and appears as one image. Next, the total reflection mirror 45 is controlled to the angle θ3, and at the same time, the third video signals a31, a32, a33, a34 output from the third video signal source for each of the first to fourth video circuits 51 to 54 are switched. Selected by the vessel. At this time, as shown in FIG. 8, the third video part, which is a display picture of each of the display parts 41 to 44, is reflected by the total reflection mirror 45 and reaches the observer's eye E, and the virtual image 57 c ~ 60c is spatially synthesized and appears as one image. At the end of one field period, the total reflection mirror 45 is controlled to the angle θ4, and the fourth video signals a41, a42, output from the fourth video signal source for each of the first to fourth video circuits 51 to 54 at the same time. a43 and a44 are selected by the signal switcher. At this time, as shown in FIG. 8, the fourth video portion, which is a display image of each of the display portions 41 to 44, is reflected by the total reflection mirror 45 and reaches the observer's eye E, and the virtual image 57 d to the observer is displayed. 60d is spatially synthesized and appears as one image. Therefore, in one field, images in each subfield period are temporally combined, and as a result, the viewer can view a stereoscopic image.

  The operation in this one field period is repeated in each field as shown in FIG. 10, but as shown in FIG. 11, the tilt angle of the total reflection mirror 45 is changed in the order of θ1, θ2, θ3, and θ4 in one field period. Then, in the next one-field period, the tilt angle of the total reflection mirror 45 may be changed in the order of θ4, θ3, θ2, and θ1 to repeat the operation in units of two fields.

  FIG. 12 shows a pseudo 3D display device to which the invention according to claim 5 is applied. The pseudo stereoscopic display device includes six display units 61 to 66 and a total reflection mirror 67. The display units 61 to 66 are arranged in parallel and obliquely upward at a predetermined angle with respect to the horizontal direction in front of the reflection surface of the total reflection mirror 67. The screen sizes of the display units 61 to 66 are narrower as the vertical width is closer to the total reflection mirror 67 side than the standard sizes such as the display units 1 to 4 described above. Needless to say, the display units 61 to 66 may partially display images using a standard screen.

  The total reflection mirror 67 is provided with an angle adjustment mechanism 68 so that the reflection surface is directed upward by five angles θ1 to θ5 with respect to the vertical direction. θ1 <θ2 <θ3 <θ4 <θ5.

  As shown in FIG. 13, the video signal generation unit 69 of the pseudo-stereoscopic display device of FIG. 12 includes first to sixth video circuits 71 to 76 for each of the display units 61 to 66 together with the display control unit 70. . Each of the first to sixth video circuits 71 to 76 includes first to fifth video signal sources and a signal switch, and differs in that it includes a fifth video signal source. The four video signal sources 31 to 34 and the signal switching unit 35 are configured in the same manner.

  The display control unit 70 controls switching of the signal switch for each of the first to sixth video circuits 71 to 76 and controls the generation of the first to fifth video signals by the first to fifth video signal sources. To do. Further, the angle adjustment mechanism 68 is controlled to give tilt angles θ1 to θ5 to the reflection surface of the total reflection mirror 67. The tilt angle of the total reflection mirror 67 is changed in the order of θ1, θ2, θ3, θ4, and θ5 every 1/300 seconds within one field period (1/60 seconds). When the tilt angle of the total reflection mirror 67 is θ1, the first video signals a11, a12, a13, a14, a15, and a16 from the first video signal source in each of the video circuits 71 to 76 are displayed via the signal switch. 61-66. When the tilt angle of the total reflection mirror 67 is θ2, the second video signals a21, a22, a23, a24, a25, a26 from the second video signal source in each of the video circuits 71 to 76 are displayed via the signal switcher. 66. When the tilt angle of the total reflection mirror 67 is θ3, the third video signals a31, a32, a33, a34, a35, and a36 from the third video signal source in each of the video circuits 71 to 76 are displayed via the signal switcher. 66. When the tilt angle of the total reflection mirror 67 is θ4, the fourth video signals a41, a42, a43, a44, a45, and a46 from the fourth video signal source in each of the video circuits 71 to 76 are displayed via the signal switcher. 66. When the tilt angle of the total reflection mirror 67 is θ5, the fifth video signals a51, a52, a53, a54, a55, a56 from the fifth video signal source in each of the video circuits 71 to 76 are displayed via the signal switcher. 66.

  In the display units 61 to 66, the near view image is displayed on the display unit 61 closest to the total reflection mirror 67, and the far view image is displayed on the display unit 66 farthest from the total reflection mirror 67.

  In the pseudo-stereoscopic display device of FIG. 12 having such a configuration, when a period of one field is started, first, the total reflection mirror 67 is controlled to the angle θ1, and at the same time, for each of the first to sixth video circuits 71 to 76. The first video signals a11, a12, a13, a14, a15, and a16 output from the first video signal source are selected by the signal switcher. At this time, as shown in FIG. 12, the first video portion, which is a display image of each of the display portions 61 to 66, is reflected by the total reflection mirror 67 and reaches the observer's eye E, and the virtual image 81 a to the viewer is displayed. 86a is spatially synthesized and appears as one image. Next, the total reflection mirror 67 is controlled to the angle θ2, and the second video signals a21, a22, a23, a24, a25, which are output from the second video signal source for each of the first to sixth video circuits 71 to 76 at the same time. a26 is selected by the signal switch. At this time, as shown in FIG. 12, the second video part, which is a display picture of each of the display parts 61 to 66, is reflected by the total reflection mirror 67 and reaches the observer's eye E. 86b is spatially synthesized and appears as one image. Next, the total reflection mirror 67 is controlled to the angle θ3, and at the same time, the third video signals a31, a32, a33, a34, a35, which are output from the third video signal source for the first to sixth video circuits 71 to 76, respectively. a36 is selected by the signal switch. At this time, as shown in FIG. 12, the third video portion, which is a display image of each of the display portions 61 to 66, is reflected by the total reflection mirror 67 and reaches the observer's eye E, and the virtual image 81 c to the observer. 86c is spatially synthesized and appears as one image. Further, the total reflection mirror 67 is controlled to the angle θ4, and the fourth video signals a41, a42, a43, a44, a45, a46 output from the fourth video signal source for the first to sixth video circuits 71 to 76 at the same time. Is selected by the signal switch. At this time, as shown in FIG. 12, the fourth video portion, which is a display image of each of the display portions 61 to 66, is reflected by the total reflection mirror 67 and reaches the observer's eye E, and the virtual image 81 d to the observer is displayed. 86d is spatially synthesized and appears as one image. At the end of one field period, the total reflection mirror 67 is controlled to the angle θ5, and at the same time, the fifth video signal a51 output from the fifth video signal source for each of the first to sixth video circuits 71 to 76, a52, a53, a54, a55, a56 are selected by the signal switcher. At this time, as shown in FIG. 12, the fifth video portion, which is a display image of each of the display portions 61 to 66, is reflected by the total reflection mirror 67 and reaches the observer's eye E, and the virtual image 81 e to the viewer. 86e is spatially synthesized and appears as one image. Therefore, in one field, images in each subfield period are temporally combined, and as a result, the viewer can view a stereoscopic image.

  This operation in one field period is repeated in each field. After the tilt angle of the total reflection mirror 67 is changed in the order of θ1, θ2, θ3, θ4, and θ5 in one field period, The tilt angle of the reflection mirror 67 may be changed in the order of θ5, θ4, θ3, θ2, and θ1 to repeat the operation in units of two fields. Furthermore, the inclination angle of the total reflection mirror 67 may be changed in the order of θ1, θ3, θ5, θ4, and θ2 in one field period.

  In each of the embodiments described above, a total reflection mirror is used as a mirror, but a half mirror may be used. When a half mirror is used, a three-dimensional object is placed at a position where the virtual image on the opposite side of the observer can be seen with respect to the mirror, and the three-dimensional object and the display image (virtual image) are combined and displayed. The display which gives a stereoscopic effect can be performed. The half mirror can be composed of a transparent substrate on which a predetermined reflective film pattern is formed. The reflective film pattern has a stripe shape or a lattice shape. Further, the reflection film pattern may be formed of a pattern having a constant local reflection film ratio and a different repetition cycle.

It is a side view which shows the Example of this invention. It is a block diagram which shows the video signal generation part of the pseudo | stereoscopic display apparatus of FIG. It is a figure which shows the example of a display image of the pseudo-stereoscopic display apparatus of FIG. It is a block diagram which shows the other example of the video signal generation part of the pseudo | stereoscopic display apparatus of FIG. It is a side view which shows the Example of this invention. FIG. 6 is a block diagram illustrating a video signal generation unit of the pseudo 3D display device of FIG. 5. It is a figure which shows the example of a display image of the pseudo | stereoscopic display apparatus of FIG. It is a side view which shows the Example of this invention. It is a block diagram which shows the video signal generation | occurrence | production part of the pseudo | stereoscopic display apparatus of FIG. It is a table figure which shows the inclination angle of the mirror for every subfield, and the video signal supplied to each display part. As another example, it is a table figure which shows the inclination angle of the mirror for every subfield, and the video signal supplied to each display part. It is a side view which shows the Example of this invention. FIG. 13 is a block diagram illustrating a video signal generation unit of the pseudo stereoscopic display device of FIG. 12.

Explanation of main part codes

1-4, 7, 41-44, 61-66 Display unit 5, 8, 45, 67 Total reflection mirror 6, 9, 49, 69 Video signal generator

Claims (9)

A pseudo-stereoscopic display device comprising: a display unit; and a mirror that reflects an image displayed on the display unit toward an observation position,
A pseudo-stereoscopic display device comprising: a display unit configured by a plurality of display units, wherein video signals displayed on the plurality of display units are made different from each other and a display image is changed at a predetermined cycle.   3. The pseudo-stereoscopic display device according to claim 2, wherein a display period of one field of the video signal is composed of a plurality of subfields and is switched to a different video signal for each subfield. A pseudo-stereoscopic display device comprising: a display unit; a mirror that reflects an image displayed on the display unit toward an observation position; and an angle variable unit that changes an angle of the mirror.
A pseudo-stereoscopic display characterized in that a display period of one field of a video signal is constituted by a plurality of subfields, and each subfield is switched to a different video signal and the angle of the mirror is changed in synchronization with the subfield. apparatus.   4. The pseudo-stereoscopic display device according to claim 3, wherein the display unit includes a plurality of display units, and images displayed on the display units in one subfield are different from each other.   The display unit includes a plurality of display units, and the video signal displayed in each subfield is divided into a plurality of subfield display images so that a display image of the plurality of display units forms one subfield display image. The pseudo-stereoscopic display device according to claim 3, wherein:   4. The pseudo-stereoscopic display device according to claim 3, wherein the mirror is made of a transparent substrate on which a predetermined reflective film pattern is formed.   The pseudo-stereoscopic display device according to claim 6, wherein the reflective film pattern has a stripe shape or a lattice shape.   The pseudo-stereoscopic display device according to claim 6, wherein the reflective film pattern is formed of a pattern having a constant local reflective film ratio and a different repetition cycle.   4. The pseudostereoscopic display device according to claim 3, wherein the angle of the mirror changes in a stepwise manner within a predetermined angle range according to the number of subfields, and the direction of change for each field is reversed.

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