JP2009104198A - Stereoscopic image display device and stereoscopic image display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stereoscopic image display method that ensures excellent visibility with less observer's fatigue and is suitable for stereoscopic moving image display. <P>SOLUTION: A display panel 6 is arranged in the stereoscopic image display device 2. A plurality of pixels for right and left eyes are arranged on the display panel 6. The device is constituted so that light emitted from the right eye pixel is made incident on observer's right eye, and also, light emitted from the left eye pixel is made incident on his/her left eye. In the display screen of the display panel 6, provided that a distance between the display panel 6 and the observer is expressed by D (mm), definition in a horizontal direction 12 is Y (dpi) and definition in a vertical direction 11 is X (dpi), the distance D, definition X, and definition Y are set so as to satisfy the expressions given below: X≥25.4/äD×tan(1')}, X≥175, X:Y=2:1. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a stereoscopic image display apparatus and a stereoscopic image display method that do not use special glasses, and particularly relates to a stereoscopic image display apparatus and a stereoscopic image display method that improve the visibility of a stereoscopic image and reduce observer fatigue. .

  Conventionally, a display device capable of displaying a stereoscopic image has been studied. As for stereoscopic vision, Greek mathematician Euclid in 280 B.C. thinks that "stereoscopic vision is the sense that the left and right eyes simultaneously see different images viewed from different directions of the same object." (For example, see Non-Patent Document 1 (by Chihiro Masuda, “Three-dimensional Display” Sangyo Tosho Co., Ltd.).) That is, as a function of the stereoscopic image display apparatus, it is necessary to present images with parallax to the left and right eyes of the observer independently.

  As a method for specifically realizing this function, many stereoscopic image display methods have been studied. These three-dimensional image display methods can be broadly classified into a method using glasses and a method not using glasses. Among these, there are anaglyph methods that use the difference in colors and polarized glasses methods that use polarized light, etc., but in recent years, the inconvenience of wearing glasses cannot be avoided. There have been many studies on a method without glasses without using glasses.

  Examples of the method without glasses include a lenticular lens method and a parallax barrier method. The lenticular lens system was invented around 1910 by Ives et al., For example, as described in Non-Patent Document 1 described above. FIG. 9 is a perspective view showing a lenticular lens, and FIG. 10 is an optical model diagram showing a stereoscopic display method using the lenticular lens. As shown in FIG. 9, the lenticular lens 21 has a flat surface on one surface, and a semi-cylindrical convex portion (cylindrical lens) 22 extending in one direction on the other surface, and the longitudinal directions thereof are parallel to each other. A plurality are formed so as to be.

  As shown in FIG. 10, the lenticular lens 21, the display panel 6, and the light source 8 are arranged in order from the observer side, and the pixels of the display panel 6 are located on the focal plane of the lenticular lens 21. In the display panel 6, pixels 23 that display an image for the right eye 41 and pixels 24 that display an image for the left eye 42 are alternately arranged. At this time, a group of pixels 23 and 24 adjacent to each other corresponds to each convex portion 22 of the lenticular lens 21. Thereby, the light emitted from the light source 8 and transmitted through each pixel is distributed by the convex portion 22 of the lenticular lens 21 in the direction toward the left and right eyes. As a result, it is possible to cause the left and right eyes to recognize different images, and to allow the observer to recognize a stereoscopic image.

  On the other hand, the parallax barrier method was conceived by Berthier in 1896 and proved by Ives in 1903. FIG. 11 is an optical model diagram showing a stereoscopic image display method using a parallax barrier. As shown in FIG. 11, the parallax barrier 5 is a barrier (light-shielding plate) in which a large number of thin vertical stripes, that is, slits 5a are formed. A display panel 6 is disposed in the vicinity of one surface of the parallax barrier 5. In the display panel 6, the right-eye pixels 23 and the left-eye pixels 24 are alternately arranged in a direction orthogonal to the longitudinal direction of the slit. Further, a light source 8 is disposed in the vicinity of the other surface of the parallax barrier 5, that is, on the opposite side of the display panel 6.

  Light that is emitted from the light source 8, passes through the opening (slit 5 a) of the parallax barrier 5, and passes through the right-eye pixel 23 becomes a light beam 81. Similarly, light emitted from the light source 8, passing through the slit 5 a, and passing through the left eye pixel 24 becomes a luminous flux 82. At this time, the position of the observer who can recognize the stereoscopic image is determined by the positional relationship between the parallax barrier 5 and the pixels. That is, the observer's right eye 41 is in the pass band of all the luminous fluxes 81 corresponding to the plurality of right eye pixels 23, and the observer's left eye 42 is in the pass band of all the luminous fluxes 82. Is required. This is the case in FIG. 11 where the midpoint 43 of the observer's right eye 41 and left eye 42 is located within the rectangular three-dimensional visible region 7 shown in FIG. Of the line segments extending in the arrangement direction of the right-eye pixel 23 and the left-eye pixel 24 in the stereoscopic visible region 7, the line segment passing through the diagonal intersection 7a in the stereoscopic visible region 7 is the longest line segment. For this reason, when the midpoint 43 is located at the intersection 7a, the tolerance when the position of the observer is shifted in the left-right direction is maximized, and thus the observation position is most preferable. Therefore, in this stereoscopic image display method, the distance between the intersection 7a and the display panel 6 is set as the optimum observation distance OD, and it is recommended to the observer to observe at this distance. A virtual plane in which the distance from the display panel 6 in the stereoscopic visible region 7 is the optimum observation distance OD is referred to as an optimum observation surface 7b. Thereby, the light from the right-eye pixel 23 and the left-eye pixel 24 reaches the observer's right eye 41 and left eye 42, respectively. For this reason, the observer can recognize the image displayed on the display panel 6 as a stereoscopic image.

  When the parallax barrier method was originally devised, the parallax barrier was disposed between the pixels and the eyes, which was problematic because it was unsightly and low in visibility. However, with the recent realization of liquid crystal display devices, the parallax barrier 5 can be disposed on the back side of the display panel 6 as shown in FIG. For this reason, a parallax barrier type stereoscopic image display device has been actively studied.

  An example of an actual product manufactured using the parallax barrier method is described in Non-Patent Document 2 (Nikkei Electronics No. 838, issued on January 6, 2003, pages 26 to 27, Table 1). This is a mobile phone equipped with a 3D-compatible liquid crystal display device, and the liquid crystal display device constituting the stereoscopic display device is a 2.2 inch diagonal size display with 176 dots in the horizontal direction and 220 dots in the vertical direction. Has the number of dots. A liquid crystal panel serving as a parallax barrier is provided. By turning this liquid crystal panel on and off, stereoscopic display and planar display can be switched and displayed. According to the product catalog and instruction manual of this product, the optimum observation distance during stereoscopic display is 400 mm. That is, a stereoscopic image can be viewed by observing from a location 40 cm away from the liquid crystal display device. In this conventional stereoscopic image display, the display definition during flat display is 128 dpi in both the vertical and horizontal directions, but as described above, the left-eye image and the right-eye image are alternately arranged in vertical stripes as described above. Therefore, the horizontal definition is 64 dpi, which is half of the vertical definition of 128 dpi.

Chihiro Masuda "3D Display" Sangyo Tosho Co., Ltd. Issued January 6, 2003 Nikkei Electronics No. 838 (pages 26-27, Table 1)

  However, the conventional techniques described above have the following problems. That is, as described in the above-mentioned product catalog and instruction manual of the conventional product, viewing a stereoscopic image has a problem of causing fatigue in the eyes of an observer. That is, the observer gets tired by observing a stereoscopic image for a long time.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a stereoscopic image display device and a stereoscopic image display method that are less fatigued by an observer and excellent in visibility.

  The stereoscopic image display device according to the present invention includes a display panel in which a plurality of display units including pixels for displaying a right-eye image and pixels for displaying a left-eye image are arranged in a matrix, and the right-eye display device. Optical means for emitting light emitted from the pixel displaying the image of the image and light emitted from the pixel displaying the image for the left eye in mutually different directions, and providing the stereoscopic visible range to the right of the observer When the midpoint between the eyes and the left eye is positioned within the stereoscopic visible range, light emitted from a pixel that displays the right-eye image is incident on the right eye and the left-eye is incident on the left eye. In the case where it is defined that the light emitted from the pixel displaying the image is incident, the distance between the point farthest from the display panel in the stereoscopic visible range and the display panel is D (mm), and The right-eye pixel in the display panel and the The definition of the display unit in one arrangement direction that is the arrangement direction with the ophthalmic pixels is Y (dpi), and the definition of the display unit in another arrangement direction that intersects the one arrangement direction is X (dpi). ), The distance D, the definition X, and the definition Y satisfy the following formula 1.

(Equation 1)
X ≧ 25.4 / {D × tan (1 ′)}
X ≧ 175
X: Y = 2: 1

  In the present invention, the definition (dpi) of a display unit including a plurality of pixels, that is, the definition of each of the right-eye pixel and the left-eye pixel, is a conversion constant of 25.4 (inch and millimeter). mm / inch) is equal to or greater than a value obtained by dividing the distance D (mm) by the product of the tangent (angle) of one minute angle, so that the pixel arrangement period is equal to or less than the minimum viewing angle of an observer with a visual acuity of 1.0. It can be. The definition means the number of dots per inch of length, and is a number proportional to the reciprocal of the arrangement period of the display units. As a result, it is possible to prevent the observer from recognizing the feature points of the stereoscopic image. Thereby, the visibility of a three-dimensional image improves and an observer's fatigue can be reduced. Further, the visibility of not only a stereoscopic still image but also a stereoscopic moving image can be improved.

  The inventors of the present invention conducted intensive experimental research to solve the above-described problems in the prior art, and found that there is a certain relationship between the definition of stereoscopic images and observer fatigue. And based on this knowledge, this invention was completed.

  Part of the indispensable processing that is performed when the observer recognizes a stereoscopic image is to find correspondences between feature points in the left and right images. As described in the document “Harashima Hiroshi supervision“ 3D image and human science ”Ohm company”, perception of depth, the observer finds the corresponding feature point in the left and right images, and from the parallax of this feature point It is thought to be done by calculating the depth. Then, the present inventors have repeatedly studied based on this fact, and for the observer, if the perception of the corresponding feature point in the left and right images is largely lost, the visibility of the stereoscopic image is significantly reduced and fatigued. I found out. That is, when the left and right eyes view images with different parallax, the observer searches for corresponding feature points. At this time, if feature points are largely missing in the image, correspondence between the left and right images cannot be obtained, and the viewer is confused. This confusion induces the binocular rivalry for the observer to prioritize which of the images observed with the left and right eyes. Since the binocular rivalry is in an unstable state in which binocular fusion is impossible, the visibility of the stereoscopic image is reduced and the observer becomes tired.

  Therefore, in order to facilitate stereoscopic viewing and reduce observer fatigue, it is only necessary to prevent missing corresponding feature points in the left and right images. Thus, the observer can easily find the feature points in the left and right images, can prevent binocular rivalry, and can easily perform binocular fusion.

  Therefore, the present inventors have examined to what extent the missing feature points can be tolerated. In order to completely prevent the loss of feature points, it is necessary to make the definition of the stereoscopic image more than the resolution based on the visual acuity of the observer. As a result, it is possible to avoid the phenomenon that the feature points that the observer should be able to see cannot be visually recognized due to the low definition of the image and the feature points are not recognized. The relationship between the visual acuity of the observer and the minimum viewing angle that can be identified by the observer is given by the following formula 2.

(Equation 2)
Visual acuity = 1 / minimum viewing angle (min)

  The general visual acuity of the eye is 1.0. From the above formula 2, the minimum visual angle of the observer whose visual acuity is 1.0 is 1 minute, that is, (1/60) degrees. In this case, the resolution of the observer at the observation distance D (mm) is D × tan (1 (minute)) (mm). Therefore, by setting the definition of the stereoscopic image to 25.4 / (D × tan (1 (minutes))) (dpi) or more, the basic period of the image becomes smaller than the resolution. For this reason, the observer can visually recognize the corresponding feature points that should be visible, and as a result, it becomes easy to recognize the feature points and prevent the feature points from being lost.

  In the stereoscopic image display method according to the present invention, one pixel included in a plurality of display units arranged in a matrix on the display panel displays an image for the right eye, and another pixel is an image for the left eye. The optical means emits the light emitted from the pixel displaying the right-eye image and the light emitted from the pixel displaying the left-eye image in different directions, and the observer By locating the midpoint between the eyes and the left eye in the stereoscopic visible range, light emitted from a pixel that displays the image for the right eye enters the right eye and the image for the left eye enters the left eye In a stereoscopic image display method in which light emitted from a pixel that displays a light is incident, a distance between the midpoint and the display panel is D (mm), and the right-eye pixel and the left-eye pixel in the display panel In one array direction which is the array direction of When the definition of the display unit is Y (dpi) and the definition of the display unit in the other arrangement direction crossing the one arrangement direction is X (dpi), the distance D, definition X and definition Degree Y satisfies Equation 1 above

  ADVANTAGE OF THE INVENTION According to this invention, the visibility of a three-dimensional image can be improved dramatically and an observer's fatigue can be reduced, and the visibility of a three-dimensional moving image can be improved especially.

It is a perspective view which shows the three-dimensional image display method in the 1st Embodiment of this invention. It is a figure which shows the optical model of the three-dimensional image display apparatus in this embodiment, and shows the case where the width | variety of a slit is so small that it can be disregarded. It is a figure which shows the optical model of the stereo image display apparatus in this embodiment, and shows the case where the width | variety of a slit is the finite value Q. It is a perspective view which shows the mobile telephone by which the three-dimensional image display apparatus which concerns on this embodiment is mounted. It is a perspective view which shows the three-dimensional image display method in the 2nd Embodiment of this invention. It is a figure which shows the optical model of the stereo image display apparatus in the 4th Embodiment of this invention, and shows the case where the width | variety of a slit is so small that it can be disregarded. It is a figure which shows the optical model of the stereo image display apparatus in this embodiment, and shows the case where the width | variety of a slit is the finite value Q. It is a figure which shows the optical model of the three-dimensional image display apparatus in the 5th Embodiment of this invention. It is a perspective view which shows a lenticular lens. It is a figure which shows the optical model of the three-dimensional display method which uses a lenticular lens. It is a figure which shows the optical model of the stereo image display method which uses a parallax barrier.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the accompanying drawings. First, a first embodiment of the present invention will be described. FIG. 1 is a perspective view illustrating a stereoscopic image display method according to the present embodiment, FIGS. 2 and 3 are diagrams illustrating an optical model of the stereoscopic image display apparatus according to the present embodiment, and FIG. 2 illustrates a slit of a parallax barrier. FIG. 3 shows a case where the width of the slit is a finite value Q. FIG. FIG. 4 is a perspective view showing a mobile phone equipped with the stereoscopic image display apparatus according to the present embodiment. In this embodiment, as shown in FIG.1 and FIG.2, the three-dimensional image display apparatus 2 is provided. The stereoscopic image display device 2 is provided with a parallax barrier 5, a display panel 6, and a light source 8 in order from the observer side.

  The light source 8 includes, for example, a sidelight (not shown) and a light guide plate (not shown), and emits light emitted from the sidelight toward the display panel 6 by the light guide plate.

  The display panel 6 is, for example, a transmissive liquid crystal display panel, and its display surface has a rectangular shape with one side extending in the vertical direction 11 and the other side extending in the horizontal direction 12. In the display panel 6, a plurality of pixels are arranged in a matrix along the vertical direction 11 and the horizontal direction 12. Among the plurality of pixels, some are right-eye pixels 23 that display an image for the right eye, and the remaining are left-eye pixels 24 that display an image for the left eye. In the display panel 6, a pixel group as a display unit including the right-eye pixels 23 and the left-eye pixels 24 is arranged in a matrix along the vertical direction 11 and the horizontal direction 12. That is, the right-eye pixels 23 and the left-eye pixels 24 are alternately arranged along the horizontal direction 12, the right-eye pixels 23 are arranged along the vertical direction 11, and the left-eye pixels 24 are also arranged in the vertical direction. 11 are arranged.

  Further, in the parallax barrier 5, one slit 5 a is formed corresponding to a pair of columns each including a column of right eye pixels 23 and a column of left eye pixels 24. That is, the longitudinal direction of the slits 5a extends in the longitudinal direction 11, and the number of slits 5a is the same as the number of pairs of the columns of the right-eye pixels 23 and the left-eye pixels 24 in each column, The slits 5a are parallel to each other, and are arranged in the lateral direction 12 at intervals. For example, the parallax barrier 5 is formed by forming a metal film on the surface of a glass plate, and the slit 5a is a portion where the metal film is patterned and removed in a linear shape.

  Next, the definition of the observation distance in this embodiment will be described. First, as shown in FIG. 2, the case where the width of the slit 5a is extremely small and can be ignored will be described. The arrangement pitch of the slits 5a of the parallax barrier 5 is L, and the interval between the display panel 6 and the parallax barrier 5 is H. Further, P is an arrangement pitch of pixels. As described above, in the display panel 6, two pixels, that is, each one of the right-eye pixel 23 and the left-eye pixel 24 are arranged as a set of pixel groups. The arrangement pitch of is 2P. Since the arrangement pitch L of the slits 5a and the arrangement pitch P of the pixel groups are related to each other, the other is determined in accordance with one, but normally, a parallax barrier may be designed in accordance with the display panel. Since there are many, the pixel arrangement pitch P is treated as a constant.

  Further, an area where light from all the right eye pixels 23 reaches is a right eye area 71, and an area where light from all the left eye pixels 24 reaches is a left eye area 72. The observer can recognize a stereoscopic image by positioning the right eye 41 in the right eye region 71 and the left eye 42 in the left eye region 72. However, since the distance between the eyes of the observer is constant, the right eye 41 and the left eye 42 cannot be arranged at arbitrary positions in the right eye area 71 and the left eye area 72, respectively, and the binocular distance is maintained at a constant value. It is limited to the area that can. That is, stereoscopic vision is possible only when the middle point 43 of the right eye 41 and the left eye 42 is located in the stereoscopic visibility range 7. At the position where the distance from the display panel 6 is the optimum observation distance OD, the length along the horizontal direction 12 in the stereoscopic visible range 7 is the longest, and thus the tolerance when the position of the observer is shifted in the horizontal direction 12. Is the maximum. For this reason, the position where the distance from the display panel 6 is the optimum observation distance OD is the most ideal observation position. Further, a virtual plane in which the distance from the display panel 6 in the stereoscopic visible range 7 is the optimum observation distance OD is defined as the optimum observation surface 7b. Further, an enlarged projection width of one pixel on the optimum observation surface 7b is, for example, an observer's binocular interval e. The average value of the observer's binocular distance is, for example, 65 mm.

  Next, the distance H between the parallax barrier 5 and the display panel 6 is determined using the above-described values. From the geometrical relationship shown in FIG. 2, the following formula 3 is established, and as a result, the interval H is obtained as shown in the following formula 4.

Furthermore, the center of the pixel group positioned at the center in the lateral direction 12 of the display panel 6, the distance between the center of the pixel group positioned at an end and W _P in the horizontal direction 12, corresponding respectively to these pixels When the distance between the centers of the slits 5a and W _L, a difference C between the distance W _P and the distance W _L is given by the following equation 5. Further, the number of pixels included in the distance W _P on the display panel 6 When the 2m, following Equation 6 is satisfied. Furthermore, since the following mathematical formula 7 holds from the geometrical relationship, the pitch L of the slits 5a of the parallax barrier 5 is given by the following mathematical formula 8.

  As described above, stereoscopic vision is possible if the midpoint 43 of both eyes is located in the stereoscopic visibility region 7. A distance between a point farthest from the display panel 6 in the stereoscopic visible region 7 and the display panel 6 is defined as a maximum observation distance D. In order to calculate the maximum observation distance D, as shown in FIG. 2, the light beam 25 emitted from the left end of the right-eye pixel 23 located on the rightmost side of the display panel 6 is illustrated from the optical system center line 26. What is necessary is just to obtain | require the distance between the point left | separated by the distance of (e / 2) leftward, and the display panel 6. FIG. From the geometric relationship shown in FIG. Further, the following formula 11 is calculated from the above formula 7 and the following formula 10.

  In the above description, the case where the width of the slit 5a is extremely small and can be ignored has been described. In this case, although the crosstalk between the image for the left eye and the image for the right eye is small, the width of the slit is small. There is a problem that the display becomes dark. Therefore, in practice, as shown in FIG. 3, the slit 5a has a finite width to brighten the display. Next, the observation distance when the width of the slit 5a is taken into account will be described.

  In FIG. 3, when an XY orthogonal coordinate system is set in which the surface of the display panel 6 is the X axis and the center line 26 of the optical system is the Y axis, A light beam 27 emitted from the light beam and passing through the right end of the slit 5a is given by the following equation (12).

  At this time, the maximum observation distance D is the value of the Y coordinate at the intersection of the light beam 27 and x = (− e / 2). Therefore, when x = (− e / 2) is substituted into the above equation 12, the maximum observation distance D is given by the following equation 13.

  Further, since the following formula 14 is established from the geometric relationship, the following formula 15 is derived from the above formula 13 and the following formula 14.

  In FIG. 3, the width Q of the slit 5a is set so that the enlarged projection width of one pixel on the optimum observation surface 7b is 2e, that is, twice the distance between the eyes of the observer. If the width Q of the slit 5a becomes larger than this, crosstalk between the left-eye image and the right-eye image occurs at all observation points on the optimum observation surface 7b, and there is an observation point where no crosstalk occurs. No longer. For this reason, normally, the width Q of the slit is not made larger than this. That is, it can be said that this condition is when the slit width Q takes the maximum value. From the geometrical relationship, the slit width Q can be expressed as in the following Equation 16 and Equation 17. The distance H between the parallax barrier 5 and the display panel 6 and the arrangement period L of the slits 5a of the parallax barrier 5 can be obtained in the same manner as in the above equations 4 and 8.

  Note that the size of the stereoscopic visible region 7 depends on the allowable amount of crosstalk and the aperture ratio of the pixel, but when the width Q of the slit 5a takes the maximum value as described above, as shown in FIG. Optical arrangement. At this time, the following formula 18 is derived from the above formula 14.

Assuming that the maximum observation distance D when the slit width Q is negligible is D _min and the maximum observation distance D when the slit width Q takes the maximum value is D _max , Is established. From this equation 19 and the above equation 11, the following equation 20 is derived.

  As described above, the maximum observation distance D is defined for the case where the width of the slit 5a is the smallest and the largest. Actually, the width of the slit is designed within the range between the minimum value and the maximum value according to the allowable amount of crosstalk between the left and right images, the aperture ratio of the pixels, the brightness of the display, and the like. In that case, the enlarged projection width of one pixel is in the range from the binocular interval (e) to twice the binocular interval (2e). The above description is for the case where the opening of the parallax barrier has a slit shape, but can also be applied to the case where the opening has a pinhole shape.

  As described above, the maximum observation distance D of the stereoscopic image display device 2 is defined based on the configuration of the stereoscopic image display device 2. With this maximum observation distance D, the definition X (dpi) in the vertical direction 11 of the display panel 6 is set so as to satisfy the following Expression 21. In other words, the definition in the vertical direction 11, that is, the number of right eye pixels 23 per inch, for example, is 25.4 (mm / inch) and the distance D (mm) and the tangent (angle) for one angle. It is more than the value divided by the product of. Table 1 shows typical values of the maximum observation distance D and the minimum value of the definition X.

(Equation 21)
X ≧ 25.4 / {D × tan (1 ′)}

  In the present embodiment, the maximum observation distance D is, for example, 500 mm, and the observer observes the stereoscopic image display device 2 from the display panel 6 at a distance of 500 mm or less, for example, a distance of 400 to 500 mm. At this time, for each of the right-eye image and the left-eye image in the stereoscopic image 1, the definition 11 in the vertical direction 11 is set to 175 dpi or more, for example, 230 dpi. Further, the definition in the horizontal direction 12 is, for example, 115 dpi. Further, the size of the display surface of the display panel 6 is, for example, a diagonal type 2.2, and the length of the vertical direction 11 on the display surface is 45 mm, for example, and the length of the horizontal direction 12 is 34 mm, for example. As shown in FIG. 4, the stereoscopic image display device 2 of the present embodiment is mounted on, for example, a mobile phone 9. Note that the stereoscopic image display device 2 may be mounted on a portable device such as a portable terminal, a PDA, a game machine, a digital camera, or a digital video.

  Next, the operation of the stereoscopic image display apparatus according to this embodiment, that is, the stereoscopic image display method will be described. As shown in FIGS. 1 and 2, first, the light source 8 is turned on and the display panel 6 displays the stereoscopic image 1. That is, the right eye pixel 23 of the display panel 6 displays the right eye image, and the left eye pixel 24 displays the left eye image. Next, the observer 4 positions the midpoint 43 of the right eye 41 and the left eye 42 at an observation point in the stereoscopic visible region 7, for example, an observation point 400 mm away from the display panel 6. At this time, the light source 8 outputs light toward the display panel 6, and the light incident on the right-eye pixel 23 of the display panel 6 is transmitted therethrough and passes through the slit 5 a of the parallax barrier 5. To the right eye 41. On the other hand, the light that has entered the pixel 24 for the left eye of the display panel 6 is transmitted through the slit 5 a of the parallax barrier 5 and enters the left eye 42 of the observer. Thereby, the observer can recognize the stereoscopic image 1. In practice, the observer 4 moves the position by holding the stereoscopic image display device 2 in his / her hand, or searches for a position where the observer can recognize the stereoscopic image, and observes the image. Become. Note that the stereoscopic image 1 displayed on the display panel 6 may be a still image or a moving image.

  As described above, in the present embodiment, the vertical definition X of the display panel 6 is set so as to satisfy the above formula 21, so that when the stereoscopic image is displayed, the definition of the image is determined by the observer. Less than the resolution of visual acuity. For this reason, it is possible to prevent the observer from overlooking feature points that should be visible, and to suppress the observer from feeling fatigued. In particular, this effect is great when a stereoscopic moving image is displayed. A moving image changes with time, but when it takes time to search for a feature point of an observer, binocular fusion cannot catch up with the change of the image. As a result, since binocular rivalry always occurs, the observer feels a great deal of fatigue. On the other hand, in the present embodiment, as described above, the feature points are searched for quickly and stereoscopic viewing is facilitated, so that a stereoscopic moving image can be easily recognized.

  In the present embodiment, the display panel 6 includes only the right-eye pixel 23 that displays the right-eye image and the left-eye pixel 24 that displays the left-eye image, but the display panel includes other images. One or more types of pixels for displaying the image may be provided. Thereby, multi-viewpoint display can be performed.

  In this embodiment, a transmissive liquid crystal display panel is used as a display panel. However, the present invention is not limited to this, and a reflective liquid crystal display panel or a half in which a transmissive region and a reflective region are provided in each pixel. A transmissive liquid crystal display panel may be used. The liquid crystal display panel may be driven by an active matrix method such as a TFT (Thin Film Transistor) method or a TFD (Thin Film Diode) method, or a passive method such as an STN (Super Twisted Nematic Liquid Crystal) method. A matrix system may be used. Further, the display panel is a display panel other than a liquid crystal display panel, for example, an organic electroluminescence display panel, a plasma display panel, a CRT (Cathode-Ray Tube) display panel, or an LED (Light Emitting Diode) display panel. A field emission display panel or PALC (Plasma Address Liquid Crystal) may be used.

  Next, a second embodiment of the present invention will be described. FIG. 5 is a perspective view showing another stereoscopic image display method in the present embodiment. In the present embodiment, the vertical definition of the display panel is 175 dpi, and the observation distance D is 500 mm. As a result, as shown in FIG. 5, the observer can hold the stereoscopic image display device 2 with the hand 44 and observe the stereoscopic image 1 while moving. Other configurations, operations, and effects of the present embodiment are the same as those of the first embodiment.

  Next, a third embodiment of the present invention will be described. In the present embodiment, unlike the first embodiment described above, the definition X in both the vertical direction 11 and the horizontal direction 12 of the display surface of the display device 6 is set so as to satisfy Equation 21 above. The definition in the vertical direction 11 is, for example, the number of right eye pixels 23 per inch. The definition in the horizontal direction 12 is the number per inch of a group of one right-eye pixel 23 and one left-eye pixel 24.

  In the present embodiment, by configuring as described above, it is possible to more reliably prevent the feature points from being lost, and to reduce the fatigue of the observer more effectively. Other configurations, operations, and effects of the present embodiment are the same as those of the first embodiment.

  Next, a fourth embodiment of the present invention will be described. 6 and 7 are diagrams illustrating an optical model of the stereoscopic image display apparatus according to the present embodiment. FIG. 6 illustrates a case where the width of the slit is small enough to be ignored. FIG. 7 illustrates a value Q having a finite slit width. The case is shown. As shown in FIG. 6, in the stereoscopic image display apparatus according to the present embodiment, a parallax barrier 5 is provided on the back side of the display panel 6. That is, the display panel 6, the parallax barrier 5, and the light source 8 are provided in order from the viewer side. Other configurations in the present embodiment are the same as those in the first embodiment.

  Next, the definition of the observation distance in this embodiment will be described. First, as shown in FIG. 6, the case where the width of the slit 5a is minimal and can be ignored will be described. Similar to the first embodiment, the arrangement pitch of the slits 5a of the parallax barrier 5 is L, the interval between the display panel 6 and the parallax barrier 5 is H, and the arrangement of the pixel groups of the display panel 6 is set. Let P be the pitch. In addition, the distance between the point farthest from the display panel 6 in the stereoscopic visible region 7 and the display panel 6 is the maximum observation distance D, and the distance between the intersection 7a of the stereoscopic visible region 7 and the display panel 6 is the optimum observation distance. OD. Further, an enlarged projection width of one pixel on the optimum observation surface 7b is, for example, an observer's binocular interval e. Thereby, the following formula 22 and formula 23 are established.

Furthermore, the center of the pixel group positioned at the center in the lateral direction 12 of the display panel 6, the distance between the center of the pixel group positioned at the end in the horizontal direction 12 and W _P, corresponding respectively to these pixels When the distance between the centers of the slits 5a to the W _L, a difference C between the distance W _P and the distance W _L is given by the following equation 24. Further, when the number of pixels included in the distance W _P in the display panel 6 and the 2m, Equation 6 is satisfied, so that the following expression 25) and (26 is established.

  On the other hand, in order to calculate the maximum observation distance D, as shown in FIG. 6, the light is emitted from the rightmost slit 5 a shown in the parallax barrier 5 and is located on the rightmost side of the display panel 6. What is necessary is just to obtain | require the distance between the point which left | separated only the distance of (e / 2) to the left direction of illustration in the light ray 25 which permeate | transmitted the right end of the pixel 23 in the illustration left direction. From the geometrical relationship shown in FIG. 6, the following formulas 27 and 28 hold. Further, the following formula 29 is calculated from the above formula 25 and the following formula 28.

  In the above description, the case where the width of the slit 5a is extremely small and can be ignored has been described. In this case, although the crosstalk between the image for the left eye and the image for the right eye is small, the width of the slit is small. There is a problem that the display becomes dark. Therefore, in practice, as shown in FIG. 7, the slit 5a has a finite width to brighten the display. Hereinafter, the case where the width of the slit 5a is considered will be described.

  In FIG. 7, when an XY orthogonal coordinate system is set with the surface of the display panel 6 as the X axis and the center line of the optical system as the Y axis, the parallax barrier 5 passes through the right end of the leftmost slit 5 a shown in the figure. The light beam 28 that passes through the left end of the left-eye pixel 24 located on the leftmost side of the display panel 6 is given by the following Equation 30.

  At this time, the maximum observation distance D is the value of the Y coordinate of the intersection of the light beam 28 and the straight line x = (e / 2). Therefore, when x = (e / 2) is substituted into the above equation 27, the maximum observation distance D is given by the following equation 31.

  In FIG. 7, the width Q of the slit 5a is set so that the enlarged projection width of one pixel on the optimum observation surface 7b is 2e, that is, twice the distance between the eyes of the observer. If the width Q of the slit 5a is larger than this, crosstalk between the left-eye image and the right-eye image occurs at all observation points on the optimum observation surface 7b, and there are observation points at which no crosstalk occurs. Usually, the width Q of the slit is not made larger than this. That is, this condition is when the slit width Q takes the maximum value. From the geometrical relationship, the slit width Q can be expressed as in the following Equation 32 and Equation 33. The distance H between the parallax barrier 5 and the display panel 6 and the arrangement period L of the slits 5a of the parallax barrier 5 are obtained by the above formulas 4 and 8, as in the first embodiment. be able to.

  Although the size of the stereoscopic visible region 7 depends on the allowable amount of crosstalk and the aperture ratio of the pixel, as described above, when the width Q of the slit 5a takes the maximum value, as shown in FIG. The optical arrangement is such that the enlarged projection width of each pixel is 2e. Accordingly, the following mathematical formula 34 is established from the geometrical relationship shown in FIG. 7, and the following mathematical formula 35 is derived from the following mathematical formula 34.

When the maximum observation distance D when the slit width Q is negligible is D _min , and the maximum observation distance D when the slit width Q takes the maximum value is D _max , the distance D _min is given by the above Equation 28. Since D _max is given by the above equation 35, the following equation 36 is established. From Equation 36 and Equation 29, the following Equation 37 is derived.

  As described above, the maximum observation distance D is defined for the case where the width of the slit 5a is the smallest and the largest. Actually, the width of the slit is designed within the range between the minimum value and the maximum value according to the allowable amount of crosstalk between the left and right images, the aperture ratio of the pixels, the brightness of the display, and the like. In that case, the enlarged projection width of one pixel is in the range from the binocular interval (e) to twice the binocular interval (2e). The above description is for the case where the opening of the parallax barrier has a slit shape, but can also be applied to the case where the opening has a pinhole shape.

  Next, the operation of the stereoscopic image display apparatus according to this embodiment, that is, the stereoscopic image display method will be described. As shown in FIGS. 1 and 6, first, the light source 8 is turned on and the display panel 6 displays the stereoscopic image 1. That is, the right eye pixel 23 of the display panel 6 displays the right eye image, and the left eye pixel 24 displays the left eye image. Next, the observer 4 positions the midpoint 43 of the right eye 41 and the left eye 42 at an observation point in the stereoscopic visible region 7, for example, an observation point 400 mm away from the display panel 6. At this time, the light source 8 outputs light toward the parallax barrier 5, and this light passes through the slit 5 a of the parallax barrier 5 and enters the right-eye pixel 23 and the left-eye pixel 24. The light that has entered the right-eye pixel 23 is transmitted therethrough and enters the right eye 41 of the observer. Further, the light incident on the left-eye pixel 24 is transmitted therethrough and is incident on the left eye 42 of the observer. Thereby, the observer can recognize the stereoscopic image 1. Operations other than those described above in the present embodiment are the same as those in the first embodiment described above.

  In the present embodiment, compared to the first embodiment described above, the parallax barrier is provided on the back side of the display panel. Therefore, when the observer observes the stereoscopic image 1, the parallax barrier is obstructive. The visibility is even better. The effects of the present embodiment other than those described above are the same as those of the first embodiment described above.

  Next, a fifth embodiment of the present invention will be described. FIG. 8 is a diagram illustrating an optical model of the stereoscopic image display apparatus according to the present embodiment. A stereoscopic image display method according to the present embodiment is as shown in FIG. As shown in FIG. 8, in the stereoscopic image display apparatus according to the present embodiment, a lenticular lens 21, a display panel 6, and a light source 8 are provided in this order from the observer side, and the lenticular lens 21 is in contact with the display panel 6. The pixels of the display panel 6 are located on the focal plane of the lenticular lens 21. The configurations of the display panel 6 and the light source 8 are the same as those in the first embodiment.

  In the lenticular lens 21, a plurality of cylindrical lenses (convex portions) 22 whose longitudinal direction is the longitudinal direction 11 (see FIG. 1) are arranged along the lateral direction 12. A group of pixels 23 and 24 adjacent to each other corresponds to each convex portion 22 of the lenticular lens 21.

  Next, the definition of the observation distance in this embodiment will be described. The arrangement pitch of the cylindrical lenses 22 of the lenticular lens 21 is L, and the thickness of the lenticular lens 21, that is, the distance between the display panel 6 and the top of the lenticular lens 21 is H. The refractive index of the lenticular lens 21 is n. Further, P is an arrangement pitch of pixels of the display panel 6. Since the arrangement pitch L of the cylindrical lenses 22 and the arrangement pitch P of the pixels are related to each other, the other is determined according to one, but usually the lenticular lens is often designed according to the display panel. Therefore, the pixel arrangement pitch P is treated as a constant. Further, the refractive index n can be determined by selecting the material of the lenticular lens 21.

The incident angle from the end of the pixel group located at the center in the horizontal direction 12 of the display panel 6 to the center of the cylindrical lens 22 located at the center in the horizontal direction 12 of the lenticular lens 21 is α, and the emission angle is β. The incident angle from the center of the pixel group located on the rightmost side of the display panel 6 in the horizontal direction 12 to the center of the cylindrical lens 22 located on the rightmost side of the lenticular lens 21 in the horizontal direction 12 is γ, and the emission angle is Let δ. Also, further, the center of the pixel group positioned at the center in the lateral direction 12 of the display panel 6, the distance between the center of the pixel group positioned at the end in the horizontal direction 12 and W _P, husband these pixels s the distance between the centers of the corresponding cylindrical lens 22 and W _L. Note that the definitions of the stereoscopic visible region 7, the optimum observation distance OD, the maximum observation distance D, the optimum observation surface 7b, and the binocular interval e shown in FIG. 8 are the same as those in the first embodiment (see FIG. 2). .

  Next, the distance H between the lenticular lens 21 and the display panel 6 is determined using the above-described values. From the Snell's law and the geometrical relationship shown in FIG.

The difference C between the distance _{W P} and the distance _{W L} is given by the following equation 44. Further, the number of pixels included in the distance W _P on the display panel 6 When the 2m, following equation 45 is established. Furthermore, since the above mathematical formula 43 is established from the geometric relationship, the pitch of the slits 5a of the parallax barrier 5 is given by the above mathematical formula 8.

  If the observer's right eye 41 is located in the right eye area 71 and the left eye 42 is located in the left eye area 72, the observer can recognize a stereoscopic image. However, since the distance between the eyes of the observer is constant, the right eye 41 and the left eye 42 cannot be arranged at arbitrary positions in the right eye area 71 and the left eye area 72, respectively, and the binocular distance is maintained at a constant value. It is limited to the area that can. That is, stereoscopic vision is possible only when the middle point 43 of the right eye 41 and the left eye 42 is located in the stereoscopic visibility range 7. At the position where the distance from the display panel 6 is the optimum observation distance OD, the length along the horizontal direction 12 in the stereoscopic visible range 7 is the longest, and thus the tolerance when the position of the observer is shifted in the horizontal direction 12. Is the maximum. For this reason, the position where the distance from the display panel 6 is the optimum observation distance OD is the most ideal observation position.

  On the other hand, in order to calculate the maximum observation distance D, as shown in FIG. 8, the light beam 29 emitted from the left end of the right-eye pixel 23 located on the rightmost side of the display panel 6 is shown from the optical system center line 26. What is necessary is just to obtain | require the distance between the point left | separated by the distance of (e / 2) to the left direction of illustration, and the display panel 6. FIG. From the geometric relationship shown in FIG. Further, the following formula 48 is calculated from the above formula 43 and the following formula 47.

  The above description is for the case where the lens is a lenticular lens, but it can also be applied to the case where the lens is a fly-eye lens.

  As described above, the maximum observation distance D of the stereoscopic image display device 2 is defined based on the configuration of the stereoscopic image display device 2. With this maximum observation distance D, the definition X (dpi) in the vertical direction 11 of the display panel 6 is set so as to satisfy the above formula 21. In other words, the definition in the vertical direction 11, that is, the number of right eye pixels 23 per inch, for example, is 25.4 (mm / inch) and the distance D (mm) and the tangent (angle) for one angle. It is more than the value divided by the product of. In the present embodiment, the maximum observation distance D is 500 mm, for example, and the definition 11 in the vertical direction 11 is 175 dpi or more, for example, 230 dpi.

  Next, the operation of the stereoscopic image display apparatus according to this embodiment, that is, the stereoscopic image display method will be described. As shown in FIG. 1 and FIG. 8, first, the observer 4 moves the midpoint between the right eye 41 and the left eye 42 to an observation point within the stereoscopic visible range 7, for example, an observation point 400 to 500 mm away from the display panel 6. 43 is positioned. Next, the display panel 6 displays the stereoscopic image 1. That is, the right eye pixel 23 of the display panel 6 displays the right eye image, and the left eye pixel 24 displays the left eye image. Then, the light source 8 outputs light toward the display panel 6. This light is incident on the right-eye pixel 23 and the left-eye pixel 24 of the display panel 6. The light that has entered the right-eye pixel 23 is transmitted therethrough, is refracted by each cylindrical lens 22 of the lenticular lens 21, and enters the right eye 41 of the observer. Further, the light that has entered the left-eye pixel 24 is transmitted therethrough, is refracted by the cylindrical lens 22, and is incident on the left eye 42 of the observer. Thereby, the observer can recognize the stereoscopic image 1.

  In this embodiment, compared to the first embodiment described above, a lenticular lens is used as an optical means instead of a parallax barrier, so that the light emitted from the light source 8 is not lost and the efficiency is improved. Good. The effects of the present embodiment other than those described above are the same as those of the first embodiment described above.

  Hereinafter, the effect of the embodiment of the present invention will be specifically described in comparison with a comparative example that deviates from the scope of the claims. In order to verify the effect of the present invention, two types of stereoscopic images were displayed on the stereoscopic image display device, and subjective evaluation by 10 subjects was performed. The stereoscopic image display device was arranged at a position where the observation distance, that is, the distance between the display panel and the observer was 500 mm. When the visual acuity of the observer is 1.0, the eye resolution at this observation distance is 175 dpi.

  In the embodiment of the present invention, the definition in the vertical direction of the image is 230 dpi, and the definition in the horizontal direction is 115 dpi. That is, only the resolution in the vertical direction is set to be equal to or higher than the eye resolution. On the other hand, in the comparative example, the definition in the vertical direction of the image was 128 dpi, and the definition in the horizontal direction was 64 dpi. That is, in both the vertical and horizontal directions, the definition is less than the eye resolution.

  Ten test subjects observed these two types of stereoscopic images, and evaluated the visibility using a five-level evaluation scale. The criteria for this evaluation scale are shown in Table 2, and the evaluation results are shown in Table 3.

  As shown in Table 3, in the examples of the present invention, the average score of the subjects was 4.3, and in the comparative example, the average score was 2.1. Therefore, from this result, it was found that the image of the example of the present invention was superior in visibility compared with the image of the comparative example. In other words, it has been experimentally verified that stereoscopic vision can be greatly facilitated even if the corresponding feature points are prevented from being lost in only one direction of the stereoscopic image. As described above, excellent visibility means that observer fatigue can be reduced as a result.

  In addition, as long as prevention of missing feature points in only one direction is effective for improving visibility, when preventing missing feature points in both vertical and horizontal directions, it has the effect of reducing observer fatigue. it is obvious.

DESCRIPTION OF SYMBOLS 1; Stereoscopic image 2; Stereoscopic image display apparatus 4; Observer 5; Parallax barrier 5a; Slit 6; Display panel 7; Stereoscopic visible region 7a; Intersection of diagonal line in stereoscopic visible region 7b: Optimal observation surface 8; Mobile phone 11; longitudinal direction 12; lateral direction 21; lenticular lens 22; convex portion (cylindrical lens)
23; right eye pixel 24; left eye pixel 25, 27, 28, 29; light beam 26; optical system center line 41; observer right eye 42; observer left eye 43; right eye 41 and left eye 42; observer hand 71; right eye area 72; left eye area 81, 82; luminous flux D; maximum observation distance OD; optimum observation distance

Claims (7)

A display panel in which a plurality of display units including pixels for displaying an image for the right eye and pixels for displaying an image for the left eye are arranged in a matrix;
Optical means for emitting light emitted from the pixel displaying the right-eye image and light emitted from the pixel displaying the left-eye image in mutually different directions;
When the midpoint between the right eye and the left eye of the observer is positioned within the stereoscopic visible range in the stereoscopic visible range, light emitted from the pixel displaying the right-eye image is incident on the right eye. When it is defined as an area where light emitted from a pixel that displays the image for the left eye is incident on the left eye, between the point farthest from the display panel in the stereoscopic visible range and the display panel The distance is D (mm), the definition of the display unit in one arrangement direction that is the arrangement direction of the right-eye pixels and the left-eye pixels in the display panel is Y (dpi), and the one A stereoscopic image display apparatus, wherein the distance D, the definition X, and the definition Y satisfy the following formula, where X (dpi) is the definition of the display unit in another arrangement direction that intersects the arrangement direction: .
X ≧ 25.4 / {D × tan (1 ′)}
X ≧ 175
X: Y = 2: 1   The stereoscopic image display apparatus according to claim 1, wherein loss of feature points in the stereoscopic image is prevented.   The three-dimensional image display device according to claim 1, wherein the display panel is a liquid crystal display panel.   4. The parallax barrier according to claim 1, wherein the optical unit is a parallax barrier in which a plurality of slits extending along a direction in which the display unit is arranged are arranged for each display unit. The three-dimensional image display apparatus described in 1.   The optical means is a lenticular lens provided on the observer side of the display panel and provided with a plurality of cylindrical lenses arranged for each column of the display units and extending along a direction in which the column extends. The three-dimensional image display device according to claim 1.   The stereoscopic image display apparatus according to claim 1, wherein a stereoscopic moving image is displayed. One pixel included in a plurality of display units arranged in a matrix on the display panel displays an image for the right eye and another pixel displays an image for the left eye, and an optical unit is used for the right eye. The light emitted from the pixel for displaying the image and the light emitted from the pixel for displaying the image for the left eye are emitted in different directions, and the observer can view the midpoint of the right eye and the left eye in the stereoscopic visible range. The light emitted from the pixel displaying the right-eye image is incident on the right eye and the light emitted from the pixel displaying the left-eye image is incident on the left eye. In the image display method,
The distance between the midpoint and the display panel is D (mm), and the definition of the display unit in one arrangement direction that is the arrangement direction of the right-eye pixels and the left-eye pixels on the display panel is Y (dpi), where X (dpi) is the definition of the display unit in the other arrangement direction that intersects the one arrangement direction, the distance D, definition X, and definition Y satisfy the following formulas A stereoscopic image display method characterized by the above.
X ≧ 25.4 / {D × tan (1 ′)}
X ≧ 175
X: Y = 2: 1

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