KR20130030818A - Lens component and image display device - Google Patents

Abstract

The lens component of one embodiment includes K unit lenses. K (≧ 2) unit lenses extend in the first direction and have a common configuration, and are arranged in parallel with a minimum period P _L in a second direction perpendicular to the first direction. Each unit lens includes M (≧ 2) partial lenses that are divided within the minimum period P _{L in} the second direction. Each of the M partial lenses included in each unit lens has different optical axes parallel to the third direction perpendicular to both the first direction and the second direction, and has a common point on the object plane at different positions on the image plane. Make an image.

Description

Lens parts and image display device {LENS COMPONENT AND IMAGE DISPLAY DEVICE}

The present invention relates to an image display device capable of displaying an image toward each of a plurality of viewpoints, and a lens component included in the image display device.

An image display device capable of displaying an image toward each of a plurality of viewpoints, for example, displays a different image for a person sitting in a driver's seat and a passenger seat in a car navigation system, or in each of the right and left eyes of the same person. By displaying different images with respect to each other, a stereoscopic image can be recognized.

As such an image display device, it is known to include a display panel using a liquid crystal or the like and a lenticular lens in which a cylindrical lens is arranged in parallel. When a liquid crystal display panel is used as the display panel, individual pixels are surrounded by a shielding region called a black matrix. Since the shielding area | region exists between pixels in a display panel, the black area | region corresponding to a shielding area | region will generate | occur | produce on the image surface on which an image display apparatus displays an image.

Since this black area | region is recognized according to the position on an upper surface, and it is observed as black streaks in an image, image quality falls. Therefore, the invention disclosed in Patent Document 1 seeks to avoid deterioration in image quality caused by the shielding area between pixels by providing an anisotropic scattering sheet between the liquid crystal display panel and the lenticular lens.

(Prior art technical literature)

(Patent Literature)

(Patent Document 1) Japanese Unexamined Patent Publication No. 2008-134617

However, in the invention disclosed in Patent Document 1, the light necessary for forming an image is also scattered by the anisotropic scattering sheet, whereby the image quality is lowered.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an image display device capable of displaying a high quality image toward each of a plurality of viewpoints, and a lens component suitably used in the image display device. It is done.

A lens component according to one aspect of the present invention is a lens component for forming an image on an object surface on an image surface, and (1) are K unit lenses each extending in a first direction and having a common configuration, and in a first direction. The K unit lenses arranged in parallel at a minimum period P _L in a second vertical direction, and (2) each of the K unit lenses is divided into M partial lenses within the minimum period P _{L in} the second direction. And (3) each of the M partial lenses included in each unit lens has different optical axes parallel to the third direction perpendicular to both the first direction and the second direction, and has a common point on the object plane. It is characterized by imaging in different positions above. However, K and M are integers of 2 or more.

In the lens component of one embodiment, each of the M partial lenses included in each unit lens may have the same focal length. In the lens component of one embodiment, the ratio of each of the M partial lenses included in each unit lens to each other within the minimum period P _{L in} the second direction may be the same.

In the image display device according to another aspect of the present invention, (1) a plurality of unit pixel sets are two-dimensionally arranged on a plane parallel to both the first direction and the second direction perpendicular to each other, and each of the plurality of unit pixel sets A display panel including N partial pixels arranged along the second direction, and (2) an image on the object surface is formed on the image plane by using the display panel as an object surface, and a unit pixel set is set in the second direction. Correspondingly, the lens component is provided with a unit lens. However, N is an integer of 2 or more.

In the image display device of one embodiment, in each of a plurality of unit pixel sets of the display panel, shielding areas exist between each other of the N partial pixels along the second direction, and the width of the shielding area in the second direction is increased. May be equal to the interval in the second direction of the optical axis of each of the M partial lenses included in each unit lens of the lens component. In the image display device of one embodiment, in each of the plurality of unit pixel sets of the display panel, the widths of the N partial pixels in the second direction and the widths of the shielding areas may be the same.

In the image display device of one embodiment, the value of M is 2, and the optical axis of each of the two partial lenses included in any one unit lens near the center with respect to the second direction among the K unit lenses of the lens component is formed. The intermediate position in the two directions and the central position of any one unit pixel set near the center with respect to the second direction among the plurality of unit pixel sets of the display panel may be the same. In addition, in the image display apparatus of one embodiment, each of the lens component and the display panel may have a mark for positioning when both are assembled.

According to the present invention, an image can be displayed toward each of a plurality of viewpoints, and deterioration in image quality of the image can be suppressed.

FIG. 1: is a figure which shows typically the principle of image display by the image display apparatus 1 of a 1st comparative example.
FIG. 2 is a diagram illustrating a relationship between a pixel of the display panel 20 and an image on the upper surface A in the image display by the image display device 1 of the first comparative example.
3 is a diagram illustrating a relationship between a pixel of the display panel 20 and an image on the upper surface A in the image display by the image display device 1 of the first comparative example.
4 is a diagram for explaining the lens component 10 of the image display device of the present embodiment.
FIG. 5 is a diagram showing a trajectory of light rays from the partial pixel 22 _R when the lens shifts in the -Y direction with respect to the display panel 10 in the first comparative example.
FIG. 6 is a diagram showing the light intensity distribution on the image plane A when the lens is shifted in the -Y direction with respect to the display panel 10 in the first comparative example.
FIG. 7 is a diagram showing a trajectory of light rays from the partial pixel 22 _R when the lens shifts in the + Y direction with respect to the display panel 10 in the first comparative example.
FIG. 8 is a diagram showing the light intensity distribution on the image plane A when the lens is shifted in the + Y direction with respect to the display panel 10 in the first comparative example.
FIG. 9 is a diagram showing a trajectory of light rays from the partial pixel 22 _R in the present embodiment.
FIG. 10 is a diagram showing the light intensity distribution on the upper surface A in the present embodiment. FIG.
11 is a diagram illustrating calculation conditions of the first comparative example.
12 is a diagram illustrating a calculation result of the first comparative example.
Fig. 13 is a diagram showing calculation conditions in the first embodiment.
14 is a diagram showing a calculation result of the first embodiment.
Fig. 15 is a diagram showing the calculation conditions of the second embodiment.
Fig. 16 is a diagram showing the calculation result of the second embodiment.
Fig. 17 is a diagram showing calculation conditions in the third embodiment.
18 is a diagram showing a calculation result of the third embodiment.
19 is a diagram schematically showing the principle of image display by the image display device 2 of the second comparative example.
20 is a diagram illustrating calculation conditions of a second comparative example.
21 is a diagram illustrating a calculation result of a second comparative example.
Fig. 22 is a diagram showing calculation conditions in the fourth embodiment.
Fig. 23 is a diagram showing a calculation result of the fourth embodiment.
24 is a diagram illustrating a cross-sectional shape of an aspherical lens.
25 is a diagram illustrating optimization conditions of an aspherical lens.
Fig. 26 is a diagram showing calculation conditions in the fifth embodiment.
27 is a diagram showing a calculation result of the fifth embodiment.
28 is a diagram showing the positional relationship between a unit lens and a unit pixel set in the center of the image display device of this embodiment.
29 is a view for explaining marks for alignment of the lens component 10 and the display panel 20 at the time of assembly.

EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing this invention is demonstrated in detail with reference to an accompanying drawing. In addition, in description of drawing, the same code | symbol is attached | subjected to the same or equivalent element, and the overlapping description is abbreviate | omitted. First, the image display device of the comparative example will be described, and then the image display device of the embodiment will be described. In addition, for the convenience of explanation, the XYZ rectangular coordinate system is shown in the figure.

FIG. 1: is a figure which shows typically the principle of image display by the image display apparatus 1 of a 1st comparative example. The image display device 1 includes a lens component 10 and a display panel 20, and the image on the object surface is placed on the image surface A by the lens component 10 with the display panel 20 as the object surface. Make an image.

The lens component 10 is a lenticular lens in which cylindrical lenses 11 ₁ to 11 _K each extending in the X direction and having a common configuration are arranged in parallel in the Y direction at regular intervals as unit lenses. K is an integer of 2 or more. The optical axis of each of the cylindrical lenses 11 ₁ to 11 _K is parallel to the Z direction. The lens component 10 is roughly flat, and the surface facing the display panel 20 is flat, and the surface facing the upper surface A is a convex surface. In this figure, the shape of the convex surface of the lens component 10 is shown.

In the display panel 20, a plurality of unit pixel sets 21 are two-dimensionally arranged on the XY plane. Each unit pixel set 21 includes two partial pixels 22 _L and 22 _R arranged along the Y direction. The left eye partial pixel 22 _L and the right eye partial pixel 22 _R are alternately arranged in the Y direction. In addition, a shielding region 23 called a black matrix is present between the left eye partial pixel 22 _L and the right eye partial pixel 22 _R.

Assuming that a unit pixel set (21 _k) corresponds to a cylindrical lens (11 _k), the light takes place from the pixel (22 _L) portions for the left eye of a unit pixel set (21 _k) passing through the cylindrical lens (11 _k) The left eye image I _L is formed on the upper surface A, and light generated from the right eye partial pixel 22 _R of the unit pixel set 21 _k passes through the cylindrical lens 11 _k for the right eye surface. Phase I _R is formed. Then, a left eye image is formed in the retina of the left eye E _L in the formation range of the left eye phase I _L on the upper surface A, and the right eye in the retina of the right eye E _R in the formation range of the right eye phase I _R on the upper surface A. The dragon image is imaged. Therefore, by providing the appropriate image data to each of the left eye partial pixel 22 _L and the right eye partial pixel 22 _{R of} each unit pixel set 21, the stereoscopic image is visually recognized by the left eye E _L and the right eye E _R. do.

However, on the upper surface A, the black region I _B corresponding to the shielding region 23 is generated between the left eye phase I _L and the right eye phase I _R. This black region I _B is recognized depending on the position on the upper surface A, and is observed as black stripes in the three-dimensional image, so that the image quality deteriorates.

2 and 3 are diagrams illustrating the relationship between the pixel of the display panel 20 and the image on the upper surface A in the image display by the image display device 1 of the first comparative example. In the regions (b) of FIG. 2 and FIG. 3, the pixels of the image display apparatus 1 are schematically shown. In addition, the light intensity in the upper surface A is shown in the area | region (a) of FIG.2 and FIG.3, respectively. As it is shown in Fig. 2, and the width of each of the Y-direction section pixel (22 _L, 22 _R) included in a unit pixel set (21 _k) by W _P. And the width of the Y direction of the unit pixel section pixel set (22 _L) and the pixel portions _(R 22) shielding region 23 between which is contained in (21 _k) by W _B. The width of the unit pixel set _21k in the Y direction is set to P (= 2 (W _P + W _B )). The distance between the emission side main plane and the image plane A of the lens component 10 is L ₁ . The distance between the incident side main plane of the lens component 10 and the display panel 20 is L ₂ .

Section pixel (22 _L, 22 _R) Phase I _L, the width of the Y direction of the I _R a base line, and the distance L a in the width of the Y direction in a triangle and the upper surface A of a and the distance L ₂ to the base line to the height _The triangle whose height is ₁ is in a similar relationship. In addition, another member (glass, a polarizing plate, an adhesive agent, etc.) may exist between the lens component 10 and the display panel 20 exactly | strictly. In the paraxial calculation assuming that the lens thickness is uniformly to the tip of the lens irrespective of the position, the distance L ₂ is the sum of the thickness of each layer divided by the refractive index of each layer. L _1, L ₂ are, based on the position of the thickness and refractive index and set an upper surface of each member (observation position) to be calculated by solving the matrix light.

In the area (b) of FIG. 2, the Y-direction center of the unit pixel set 21 _k and the Y-direction center of the cylindrical lens 11 _k corresponding to the unit pixel set 21 _k are all set to Y = 0. It is located. At this time, as shown in the area (a) of FIG. 2, on the upper surface A, the left eye image I _L corresponding to the left eye partial pixel 22 _L is formed in the Y-direction range represented by the following formula (1), The right eye image I _R corresponding to the right eye partial pixel 22 _R is formed in the Y-direction range shown by the following formula (2). Also, black areas I _B corresponding to the shielding area 23 is formed in the Y direction to the range that appears in the expression (3).

In the area (b) of Figure 3, Y direction of the center of the unit pixel set (21 _k) Y direction, the center is a cylindrical lens (11 _k) corresponding to a unit pixel set (21 _k) as compared to that located at the Y = 0 of Is located at Y = -t. At this time, as shown in the region (a) of FIG. 3, on the upper surface A, the left eye image I _L corresponding to the left eye partial pixel 22 _L is formed in the Y-direction range represented by the following formula (4), The right eye image I _R corresponding to the right eye partial pixel 22 _R is formed in the Y-direction range shown by the following Equation (5). Also, black areas I _B corresponding to the shielding area 23 is formed in the Y direction, the range that appears in the following (6) formula.

That is, compared with the case of FIG. 2, in the case of FIG. 3, the cylindrical lens 11 _k is moved by -t in the Y direction with respect to the unit pixel set 21 _k , so that the left eye image is placed on the upper surface A. FIG. I _L , the right eye phase I _R and the black region I _B all shift in the Y direction by -t (1 + L ₁ / L ₂ ). That is, the light reaches the portion of the light intensity 0 in FIG. 2 above the upper surface A in FIG. 3.

4 is a diagram for explaining the lens component 10 of the image display device of the present embodiment. 4, the shape of the convex surface of the lens component is also shown. Regions (a) and (b) of FIG. 4 each show lenticular lenses 4A and 4B, each of which has a plurality of cylindrical lenses extending in the X direction and having a common configuration in parallel in the Y direction at a constant period P _L. . This lenticular lens is the same as what is contained in the image display apparatus 1 of a 1st comparative example. With respect to the lenticular lens of the region (a) of FIG. 4, the lenticular lens of the region (b) of FIG. 4 is shifted by t in the Y direction.

The lens components 10 of the present embodiment shown in the region (c) of FIG. 4 each have K unit lenses 11 extending in the X direction, having a common configuration, and arranged in parallel in the Y direction with a minimum period P _L. Equipped. Each unit lens 11 includes two partial lenses 12 ₁ and 12 ₂ which are divided within a minimum period P _{L in the} Y-direction. The partial lens 12 ₁ in the range of 0 to P _L ′ in the minimum period P _L corresponds to the solid line portion in the region (a) of FIG. 4. The partial lens 12 ₂ in the range of P _L 'to P _{L in} the minimum period P _L corresponds to the solid line portion in the region (b) of FIG. 4.

That is, each of the two partial lenses 12 ₁ and 12 ₂ included in each unit lens 11 has a different optical axis parallel to the Z direction (optical axis spaced apart from each other by t in the Y direction), and on the object plane. Can be formed at different positions on the upper surface A (positions shifted from each other by -t (1 + L ₁ / L ₂ ) in the Y direction). As a result, the black region I _B (the region which becomes black stripes when observing) corresponding to the shielding region 23 can be narrowed, or the black region I _B can be eliminated.

From the light intensity distribution shown in each of region (a) of FIG. 2 and region (a) of FIG. 3, when the condition represented by the following expression (7) is established, there is a region I _B on which light does not reach on the upper surface A. do. When the conditions shown in the following Equation (8) are established, crosstalk occurs when the left eye phase I _L and the right eye phase I _R partially overlap each other on the upper surface A. Therefore, when the conditions shown by following formula (9) are satisfied, the width of the Y direction of the area | region I _B will become zero, without a crosstalk occurring. In addition, in each of formulas (7) to (9), the left side represents the left boundary position of the black region I _B in FIG. 2, and the right side represents the right boundary position of the black region I _B in FIG. 3.

The following formula (10) can be obtained from the above formula (9). Usually, the distance L ₁ is sufficiently large at several hundred millimeters, while the distance L ₂ is several hundred micrometers to several millimeters. Therefore, equation (10) can be approximated by the following equation (11).

In addition, each of the partial lenses 12 ₁ and 12 ₂ included in each unit lens 11 of the lens component 10 may have a spherical lens shape or may have an aspheric lens shape in the YZ cross section. The lens shape of each of the partial lenses 12 ₁ and 12 ₂ can be obtained by solving the ray matrix. However, even if the lens shape of each of the partial lenses 12 ₁ and 12 ₂ differs by several% from the solution of the ray matrix, the viewpoint can be separated sufficiently, so there is no practical problem. However, from the viewpoint of the uniformity of the image quality in the Y direction on the image plane A, each of the partial lenses 12 ₁ and 12 ₂ included in each unit lens 11 may have the same focal length.

Next, the operation of each of the first comparative example and the image display apparatus of the present embodiment will be described with reference to FIGS. 5 to 10. Figure 5 is a a view showing a locus of the light beam from the portion of the pixel _(R 22) when the lens is shifted in the -Y direction with respect to the display panel 10 according to the first comparative example, FIG. 6, the first It is a figure which shows the light intensity distribution on the image surface A when a lens shifts to -Y direction with respect to the display panel 10 in a comparative example. 7 is a is a diagram showing the trajectory of the beam from the partial pixel (22 _R) when the lens is shifted in the + Y direction with respect to the display panel 10 according to the first comparative example, Figure 8, first It is a figure which shows the light intensity distribution on the image surface A when a lens shifts to + Y direction with respect to the display panel 10 in a comparative example. Further, Fig. 9 is a diagram showing the trajectory of the light beam from the portion of the pixel (22 _R) in the present embodiment, FIG. 10 is a diagram showing the light intensity distribution on the upper surface A of the first embodiment.

In the first comparative example, as shown in FIGS. 5 and 6, when the lens is shifted in the -Y direction with respect to the display panel 10 (in the case of the region (a) of FIG. 4), the right eye on the upper surface A Phase I _R1 and left eye phase I _L1 are also shifted in the -Y direction. On the other hand, as shown in FIGS. 7 and 8, when the lens is shifted in the + Y direction with respect to the display panel 10 (in the case of the region (b) of FIG. 4), the image I _R2 for the right eye on the upper surface A and The left eye phase I _{L2 is} also shifted in the + Y direction.

In contrast, in the present embodiment, as shown in FIGS. 9 and 10, the right eye image I _R1 and the left eye image I _L1 formed on the image surface A through the partial lens 12 ₁ of the unit lens 11; , The right eye image I _R2 and the left eye image I _L2 formed on the image surface A through the partial lens 12 ₂ of the unit lens 11 are formed in different regions on the image surface A (region (a in FIG. 10). )). Therefore, in this embodiment, is above the upper surface A, the right-eye phase I _R1 and the right eye image I _R2 is laid right-eye image I _R for for being formed, and the left eye the image I _L1 and the left eye I _L2 for the left eye overlap The phase I _L is formed (region (b) of FIG. 10).

Next, a calculation example of the light intensity distribution on the upper surface A in each of the first comparative example, the first embodiment, the second embodiment and the third embodiment will be described. The 1st Example, 2nd Example, and 3rd Example are the specific examples of said this embodiment. In the following calculation examples, the lens was assumed to be a spherical lens.

11 is a diagram illustrating calculation conditions of the first comparative example. 12 is a diagram illustrating a calculation result of the first comparative example. In the first comparative example, as shown in FIG. 11, the width P in the Y direction of the unit pixel set is 0.2 mm, and the width W _P in the Y direction of each partial pixel included in the unit pixel set is 0.08 mm. The width W _B in the Y direction of the shielding area between the partial pixels included in the unit pixel set was 0.02 mm.

The distance L ₁ between the emission side main plane and the image plane of the lens was 350 mm, and the distance L ₂ between the incident side main plane of the lens and the display panel was 0.52 mm. In addition, the thickness of the lens is 0.3 mm, the refractive index of the lens is 1.6, and there is a glass having a thickness of 0.5 mm and a refractive index of 1.5 between the lens and the display panel, so that the distance L ₂ is 0.52 mm (= 0.3 / 1.6). + 0.5 / 1.5). In addition, although a polarizing plate and an adhesive agent may exist actually between a lens and a display panel, these were ignored.

By solving the light ray matrix using the values of these parameters, the radius of curvature of the lens was calculated to be 0.31 mm. It was assumed that the display panel had a set of 161 unit pixels, with the width of the display panel in the Y direction being 32.2 mm.

In FIG. 11, the outermost unit pixel set located at Y = 80P = 16 mm is the 80th unit pixel set counting from the unit pixel set located at the center (Y = 0). In order to substantially overlap the image reached from each unit pixel set on the image plane A in the viewing range, the image of the center position of the 80th unit pixel set located at Y = 80P is placed at the 80th lens located at Y = 80P _L. After that, it was set as the position of Y = 0 on the upper surface A. The width P _L of the Y-direction of the unit lens was calculated to be 0.1997 mm from the similarity of the triangle as described above.

In the first comparative example, the light intensity distribution of the top face A on when shining the whole of the part pixel (22 _L, 22 _R) contained in 161 unit pixel set of the display panel, and as shown in Figure 12 . On the upper surface A, a region I _B to which light does not reach exists between the right eye phase I _R and the left eye phase I _L.

Fig. 13 is a diagram showing calculation conditions in the first embodiment. 14 is a diagram showing a calculation result of the first embodiment. In the first embodiment, as shown in Fig. 13, the calculation conditions for parameters other than the unit lens shape are the same as the calculation conditions of the first comparative example. In the lens component 10 of the first embodiment, the unit lens is a partial lens corresponding to a part of the lens 13B in which the lens 13A of the first comparative example is shifted by t / 2 in the -Y direction (left direction). and a (12 ₁₎ and a first comparative example, the lens lens portion (12 ₂₎ corresponding to the (13A) in a part of the + Y direction (right direction) in t / 2 the lens (13C) shifted by. t / 2 = W _B / 2 = 0.01 mm.

The optical axes of the partial lenses 12 ₁ and 12 ₂ are parallel to the Z direction and are separated from each other by a distance t. The Y-direction center position of the optical axis of each of the partial lenses 12 ₁ and 12 ₂ included in the unit lens positioned at the center of the lens component coincides with the Y-direction center position of the unit pixel set positioned at the center of the display panel. . In the width P _L (0.1997 mm) in the Y direction of each unit lens, the partial lens 12 ₁ is present in an area of 0.05 mm width on the side of the -Y direction, and a part in an area of 0.1497 mm width on the side of the + Y direction. There is a lens 12 ₂ .

In the first embodiment, the upper surface A light intensity distribution in the stomach when shining the whole of section pixel (22 _L, 22 _R) contained in 161 unit pixel set of the display panel, and as shown in Fig. 14 . On the upper surface A, between the right eye phase I _R and the left eye phase I _L, the area | region I _B which light does not reach disappears, and the black stripe when an image is observed disappears. In addition, in FIG. 14, although the light intensity changes in the step shape according to a position, and there exists an area | region where light intensity is low, it is hard to be recognized by the human eye much more than the area | region observed by becoming black at light intensity 0.

Fig. 15 is a diagram showing calculation conditions in the second embodiment. 16 is a diagram illustrating a calculation result of the second embodiment. In the second embodiment, as shown in Fig. 15, the calculation conditions for parameters other than the unit lens shape are the same as the calculation conditions of the first comparative example. That is, in the lens component 10 of the second embodiment, the unit lens corresponds to a part of the lens 15B in which the lens 15A of the first comparative example is shifted by t / 2 in the -Y direction (left direction). The lens 12 ₁ and the partial lens 12 ₂ corresponding to a part of the lens 15C in which the lens 15A of the first comparative example is shifted by t / 2 in the + Y direction (right direction) are included. In the first embodiment, the ratio of the widths of the partial lenses 12 ₁ and 12 ₂ in the Y direction was about 1: 3, whereas in the lens component 10 of the second embodiment, the partial lenses 12 ₁ and 12 ₂ The ratio of the width | variety of the Y direction of) was made into 1: 1.

In the second embodiment, the upper surface A light intensity distribution in the stomach when shining the whole of section pixel (22 _L, 22 _R) contained in 161 unit pixel set of the display panel, and as shown in Fig. 16 . On the upper surface A, between the right eye phase I _R and the left eye phase I _L, the area | region I _B which light does not reach disappears, and the black stripe when an image is observed disappears. In addition, in the second embodiment, since the light intensity distribution on the upper surface A is symmetric about the position of Y = 0, a more natural image can be obtained. In addition, unlike the first embodiment, the lens component of the second embodiment eliminates the discontinuous portion, which makes the manufacturing easier.

Fig. 17 is a diagram showing the calculation conditions of the third embodiment. 18 is a diagram illustrating a calculation result of the third embodiment. In the lens component 10 of the third embodiment, the unit lens is a partial lens corresponding to a part of the lens 17B in which the lens 17A of the first comparative example is shifted by t / 2 in the -Y direction (left direction) ( 12 ₁ ) and a partial lens 12 ₂ corresponding to a part of the lens 17C in which the lens 17A of the first comparative example is shifted by t / 2 in the + Y direction (right direction). In the third embodiment, as shown in FIG. 17, as in the first comparative example, the first embodiment, and the second embodiment, the width P in the Y direction of the unit pixel set is 0.2 mm, and the output side main of the lens The distance L ₁ between the plane and the image plane was 350 mm, the distance L ₂ between the incident side main plane of the lens and the display panel was 0.52 mm, and the width P _L in the Y direction of the unit lens was 0.1997 mm. .

In the third embodiment, the width W _P in the Y direction of each of the partial pixels included in the unit pixel set is 0.05 mm, and the width W _{B in} the Y direction of the shielding area between the respective partial pixels included in the unit pixel set. Was made 0.05 mm, and both were made the same. Further, the width of the ratio of the Y direction of the lens portion (12 _1, 12 ₂₎ 1: I to 1.

In the first comparative example, when the width W _{P in} the Y direction of each partial pixel included in the unit pixel set and the width W _B in the Y direction of the shielding region between each partial pixel are equal to each other, in the upper surface A, The widths in the Y-directions of the right eye phase I _R , the left eye phase I _L, and the black region I _B are equal to each other. In contrast, in the third embodiment, the upper surface A light intensity distribution in the stomach when shining the whole of section pixel (22 _L, 22 _R) contained in 161 unit pixel set of the display panel is shown in Fig. 18 Similarly, since the right eye image I _R and the left eye image I _L shifted by ± t / 2 by the partial lenses 12 ₁ and 12 ₂ are superimposed, an approximately uniform intensity distribution is obtained.

Therefore, in the third embodiment, in addition to the effects of the second embodiment, an effect of obtaining a more natural image with a uniform intensity distribution can be obtained. In addition, the substantial viewing range (that is, the range where the light intensity distribution is approximately uniform) on the upper surface A is Y = -55 mm to -13 mm for the right eye phase I _R in the first and second embodiments. On the left eye phase I _L , Y = + 13 mm to +55 mm, whereas in the third embodiment, the right eye phase I _R is Y = -65 mm to 0, and the left eye phase I _L is It is Y = 0 to +65 mm, and it can take a wide range of visual recognition, respectively.

Moreover, in the area (a) of FIG. 18, the part with large intensity | strength can be seen locally near the center of each of the right eye phase I _R and the left eye phase I _{L. In} FIG. This is because the light intensity distribution slightly pulls down due to the spherical aberration of the lens in the image switching portion of the partial lens shifted in the + Y direction and the image shifted in the partial lens shifted in the -Y direction. The part enclosed by the dotted line in the area | region (b) of is based on what generate | occur | produced. However, in the human eye, such local changes in intensity are difficult to recognize. This slight overlap can be improved by slightly modifying the width of the pixel and the amount of shift of the lens.

Although the number of viewpoints was 2 in the comparative example and embodiment demonstrated so far, this invention is generally applicable when the number of viewpoints is two or more. When the number of viewpoints is N, each unit pixel set of the display panel includes N partial pixels arranged in the Y direction. That is, N pictures are divided for each pixel, and partial pixels constituting the first picture, partial pixels constituting the second picture in the Y direction on the display panel; The images of the respective viewpoints are distributed by the lens, with the unit pixels arranged in order of the partial pixels constituting the Nth picture.

Next, the case where the number of viewpoints is three is demonstrated. 19 is a diagram schematically illustrating the principle of image display by the image display device 2 of the second comparative example. The image display device 2 includes a lens component 10 and a display panel 20, and uses the display panel 20 as an object surface to display an image on the object surface on the image surface A by the lens component 10. It is missing. The lens component 10 is as shown in FIG.

In the display panel 20, a plurality of unit pixel sets 21 are two-dimensionally arranged on the XY plane. When the number of the point in time of 3, each unit pixel set 21, the three first section pixel arrangement in the Y direction (22 _1), the second section pixel (22 ₂₎ and the third section pixel (22, ₃₎ It includes. The partial pixels 22 ₁ , 22 ₂ , 22 ₃ are arranged in this order in the Y direction. In addition, a black matrix that shielding area 23 is called a, exists between the section pixel (22 ₁₎ and the partial pixels (22 _2), the pixel (22, ₃₎ present in and part of the pixels (22 ₂₎ and the part between the .

If that corresponds to a unit pixel set (21 _k) is a cylindrical lens (11 _k), the light takes place from a first portion of pixels (22 ₁₎ of a unit pixel set (21 _k) passing through the cylindrical lens (11 _k) The first image I ₁ is formed on the image A, and the light generated from the second partial pixel 22 ₂ of the unit pixel set 21 _k passes through the cylindrical lens 11 _k , thereby causing the second image on the image A. An image I ₂ is formed, and a third image I ₃ is formed on the image surface A by the light generated from the third partial pixel 1 2 ₃ of the unit pixel set 21 _k passing through the cylindrical lens 11 _k . do. The stereoscopic image is visually recognized by the left eye and the right eye in the formation range of the first and second phases on the upper surface A, and the other stereoscopic image is determined by the left eye and the right eye in the formation range of the second and third phases on the upper surface A. It is admitted.

However, also in this case, on the upper surface A, black corresponding to the shielding area 23 between the first phase I ₁ and the second phase I ₂ , and between the second phase I ₂ and the third phase I ₃ . The area I _B is generated and discarded. This black region I _B is recognized depending on the position on the upper surface A, and is observed as black stripes in the three-dimensional image, so that the image quality deteriorates.

Also in the case of such a three time point, as in the case of the already described two time point, by using the lens component as shown in the area (c) of FIG. 4, the black area I _B corresponding to the shielding area 23 (when observing The black banded area) can be narrowed or the black area I _B can be eliminated.

Next, the calculation example of the light intensity distribution on the upper surface A in each of the 2nd comparative example and 4th Example at the time of 3 views is demonstrated. 4th Example is a specific example of embodiment at the said 3 time point. In the following calculation examples, the lens was assumed to be a spherical lens.

20 is a diagram illustrating calculation conditions of a second comparative example. 21 is a diagram illustrating a calculation result of the second comparative example. In the second comparative example, as shown in FIG. 20, the width P in the Y direction of the unit pixel set is 0.21 mm, and the width W _P in the Y direction of each partial pixel included in the unit pixel set is 0.056 mm. The width W _B in the Y direction of the shielding region between the partial pixels included in the unit pixel set was 0.014 mm.

The distance L ₁ between the emission side main plane and the image plane of the lens was 350 mm, and the distance L ₂ between the incident side main plane of the lens and the display panel was 0.39 mm. In addition, the thickness of the lens is 0.2 mm, the refractive index of the lens is 1.6, and there is a glass having a thickness of 0.4 mm and a refractive index of 1.5 between the lens and the display panel, so that the distance L ₂ is 0.39 mm (= 0.2 / 1.6). + 0.4 / 1.5). In addition, although a polarizing plate and an adhesive agent may exist actually between a lens and a display panel, these were ignored.

By solving the light ray matrix using the values of these parameters, the radius of curvature of the lens was calculated to be 0.235 mm. It was assumed that the display panel was provided with 161 unit pixel sets, with the width of the display panel in the Y direction being 33.81 mm.

In FIG. 20, the outermost unit pixel set located at Y = 80P = 16.8 mm is the 80th unit pixel set counting from the unit pixel set located at the center (Y = 0). In order to substantially overlap the image reached from each unit pixel set on the image plane A in the viewing range, the image of the center position of the 80th unit pixel set located at Y = 80P is placed at the 80th lens located at Y = 80P _L. After that, it was set as the position of Y = 0 on the upper surface A. The width P _L of the Y-direction of the unit lens was calculated to be 0.2098 mm from the similarity of triangles as described above.

In the second comparative example, the light intensity distribution on the upper surface A when all three partial pixels 22 ₁ to 22 ₃ included in the 161 unit pixel set of the display panel are made to shine is as shown in FIG. 21. Become together. On the upper surface A, a region I _B in which light does not reach exists between the phases I ₁ to I ₃ .

Fig. 22 is a diagram showing calculation conditions in the fourth embodiment. Fig. 23 is a diagram showing a calculation result of the fourth embodiment. In the fourth embodiment, as shown in Fig. 22, the calculation conditions for parameters other than the unit lens shape are the same as the calculation conditions of the second comparative example. In the lens component 10 of the fourth embodiment, the unit lens corresponds to a part of the lens (reference numeral 22B) in which the lens (reference numeral 22A) of the second comparative example is shifted by t / 2 in the -Y direction (left direction). and the partial lens (12 ₁₎ to the second comparative example the lens (see reference numeral 22A), the + Y direction (right direction) by t / 2 portion of the lens corresponding to a portion of the lens (see reference numeral 22C) shifted by (12: ₂ ). t / 2 = W _B / 2 = 0.007 mm.

The optical axes of the partial lenses 12 ₁ and 12 ₂ are parallel to the Z direction and are separated from each other by a distance t. The Y-direction center position of the optical axis of each of the partial lenses 12 ₁ and 12 ₂ included in the unit lens positioned at the center of the lens component coincides with the Y-direction center position of the unit pixel set positioned at the center of the display panel. . The ratio of the width | variety in the Y direction of the partial lenses 12 ₁ and 12 _{2 was set} to 1: 1.

In the fourth embodiment, the light intensity distribution on the upper surface A when all of the partial pixels 22 ₁ to 22 ₃ included in the 161 unit pixel set of the display panel is made to shine is as shown in FIG. 23. . It is above the top face A, between image I ₁ to image I _3, and I _B is the area that does not reach the light disappears, there is no black streaks when observing the image. In addition, although the light intensity changes in a step shape depending on the position, there are regions where the light intensity is low, but it is harder to be recognized by the human eye than the region observed by becoming black at light intensity 0.

In the comparative examples and the embodiments described so far, each partial lens included in the unit lens has a spherical lens shape, but the present invention is also applicable to the case of aspherical lens shape. By making each partial lens included in the unit lens into an aspherical lens shape, light emitted from one point on the pixel can be imaged at one point as small as possible on the image surface. In the present embodiment, since the lens extends in the X direction, the lens can be imaged as thin as possible on the image surface A.

Next, the case where each partial lens included in the unit lens has an aspherical lens shape will be described. 24 is a diagram illustrating a cross-sectional shape of an aspherical lens. When the optical axis coincides with the Z axis, the distance from the optical axis is r, and the difference from the lens height when r = 0 is Δz, the shape of the convex surface of the aspherical lens is expressed by the following equation (12). c is curvature, k is conic coefficient, and c _2m is aspherical coefficient.

These lens parameters c, k and c _2m can be optimized and determined using commercially available lens design software. As an optimization condition, the number from the center unit pixel set to the outermost unit pixel set is N, and the object height (the distance in the Y direction of the light emitting point farthest from the lens center) is, for example, N (PP _L ) + P / 2 and the lens magnification may be L ₁ / L ₂ .

Each of the partial lenses included in the unit lens in the present embodiment is a part of the lenses shifted from each other by the width t in the Y direction of the shielding area 23, even in the case of aspherical lens shapes. By combining, it is possible to eliminate the portion where the light does not reach on the upper surface A, and to eliminate the black streaks appearing on the screen while improving the image quality.

The parameters of the aspherical lens are calculated as follows. As shown in Fig. 25, a lens having a refractive index of 1.5 and a thickness of 0.5 mm and a flat plate having a refractive index of 1.6 and a thickness of 0.3 mm and having a cross-sectional aspherical surface convex-shaped lens is in close contact with the lens. The surface opposite to the surface of the glass is used as the light source surface. For the object height of 0, 0.124 mm (= 80 x (0.2-0.1997) + 0.2 / 2), the distance L ₁ between the output side main plane of the lens part 10 and the image surface A is 350 mm, and the lens part The distance L ₂ between the incident side main plane of (10) and the display panel 20 is 0.52 mm. By optimizing the conditions ^{under, c = 3.1 [㎜ -1]} , k = -0.76, c 4 = 3.9, c ₆ = -145.5 is obtained. In addition, c ₂ and c _2m ( _m ≧ 4) were set to zero.

Next, a calculation example of the light intensity distribution on the image plane A in the fifth embodiment in the case where each partial lens included in the unit lens is an aspherical lens will be described.

Fig. 26 is a diagram showing calculation conditions in the fifth embodiment. 27 is a diagram showing a calculation result of the fifth embodiment. In the fifth embodiment, as shown in Fig. 26, the calculation conditions for parameters other than the unit lens shape (including the partial lens of the aspherical lens shape) are the same as the calculation conditions of the second embodiment. In this fifth embodiment, each partial lens included in the unit lens has an aspherical lens shape as described above.

In the fifth embodiment, the upper surface A light intensity distribution in the stomach when shining the whole of section pixel (22 _L, 22 _R) contained in 161 unit pixel set of the display panel, and as shown in Fig. 27 . On the upper surface A, between the right eye phase I _R and the left eye phase I _L, the area | region I _B which light does not reach disappears, and the black stripe when an image is observed disappears. Further, in the fifth embodiment, since the light intensity distribution on the upper surface A is symmetric about the position of Y = 0, a more natural image can be obtained. In addition, since the lens component of the fifth embodiment is free of discontinuous portions, manufacturing becomes easier.

In the above embodiments, the case where the stereoscopic image is visually recognized has been mainly described. In an image display device that displays a stereoscopic image or an image display device that is not intended to distribute the viewpoint asymmetrically, as shown in FIG. 28, when viewed from the front center of the image display device, each viewpoint is equally right and left. Phase may be formed. 28 is a diagram showing the positional relationship between the unit lens and the unit pixel set in the center of the image display device of the present embodiment.

As shown in FIG. 28, on the upper surface A, when the negative direction is the right viewpoint and the positive direction is the left viewpoint with respect to the position of the center of the Y direction (Y = 0), the unit of the center in the display panel 20 is shown. The center of the pixel set 21 _k is located at Y = 0. Pixel and phase need to be reversed to each other, so, a pixel portion for the left eye (22 _L) is arranged on the side, the right-eye pixel section (22 _R) is arranged for the positive side. If this greatly deviates, the part of the virtual image outside of both points is visible. The virtual image is imaged on the image plane by the pixel set (21 _k) differs from the corresponding pixel set (21 _k) the unit lens (11 _k) the unit lenses (11 _k-1, or 11 _{k + 1)} in the neighborhood of that corresponding to the It is a prize. In addition, when the right eye partial pixel and the left eye partial pixel are completely replaced, the images are replaced at the right and left sides. Therefore, the intermediate position in the Y direction of the optical axis of each of the two partial lenses included in any one unit lens near the center with respect to the Y direction of the lens component 10 and the Y direction of the display panel 20. The center positions of any one of the unit pixel sets near the center may be equal to each other.

In order to obtain the positional relationship between the unit lens 11 and the unit pixel set 21 in the form shown in FIG. 28, the image is displayed by assembling the lens component 10 and the display panel 20. The method of assembling a lens component and a display panel can be employ | adopted while checking a position. Alternatively, as shown in FIG. 29, the lens component 10 has the mark 14 for alignment at the edge and the display panel 20 has the mark 24 for alignment at the edge. When assembling the 10 and the display panel 20, a method of matching the mark 14 and the mark 24 with each other can also be adopted.

1, 2: image display device 10: lens parts
11: unit lens 12: partial lens
20: display panel 21: unit pixel set
22: partial pixel 23: shielding area

Claims (8)

A lens component for forming an image on an object surface on an image surface,
Each having K unit lenses extending in a first direction and having a common configuration and arranged in parallel at a minimum period P _L in a second direction perpendicular to the first direction,
Each of the K unit lenses includes M partial lenses that are divided within the minimum period P _L of the second direction,
Each of the M partial lenses included in each unit lens has a different optical axis parallel to a third direction perpendicular to both the first direction and the second direction, and has a common point on the object plane on the image plane. Phased at different positions of
Lens parts (wherein K and M are integers of 2 or more).
The method of claim 1,
Each of the M partial lenses included in each unit lens has the same focal length.
The method of claim 1,
And each of the M partial lenses included in each unit lens has the same ratio in the minimum period P _{L in} the second direction.
A plurality of unit pixel sets are two-dimensionally arranged on surfaces parallel to both the first and second directions perpendicular to each other, and each of the plurality of unit pixel sets includes N partial pixels arranged along the second direction. With display panel to say,
The image on the object surface is formed on the image surface using the display panel as an object surface, and the unit lens is provided corresponding to the unit pixel set in the second direction, according to any one of claims 1 to 3. Lens parts
An image display device (wherein N is an integer of 2 or more).
The method of claim 4, wherein
In each of the plurality of unit pixel sets of the display panel, a shielding area exists between each of the N partial pixels along the second direction,
The width in the second direction of the shielding area is equal to the interval in the second direction of the optical axis of each of the M partial lenses included in each unit lens of the lens component.
An image display device, characterized by the above-mentioned.
The method of claim 5, wherein
Each of the plurality of unit pixel sets of the display panel, wherein the widths of the N partial pixels in the second direction and the widths of the shielding area are equal to each other.
The method of claim 4, wherein
M is 2,
An intermediate position in the second direction of the optical axis of each of the two partial lenses included in any one unit lens near the center with respect to the second direction among the K unit lenses of the lens component; The central positions of any one of the plurality of unit pixel sets near the center with respect to the second direction are equal to each other.
An image display device, characterized by the above-mentioned.
The method of claim 4, wherein
And each of the lens component and the display panel has a mark for aligning when both are assembled.

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