阅读说明：本技术 基于双偏振复合针孔阵列的高分辨率3d显示装置 (High-resolution 3D display device based on dual-polarization composite pinhole array ) 是由 吴非 樊为 高燕 范钧 陈章达 谢了尖 徐雯 任洪娇 曾星 于 2021-09-11 设计创作，主要内容包括：本发明公开了基于双偏振复合针孔阵列的高分辨率3D显示装置,包括显示屏、偏振复合针孔阵列I和偏振复合针孔阵列II；一维透光针孔I和一维透光针孔II与一维图像元对应；二维透光针孔I和二维透光针孔II与二维图像元对应；每个一维图像元发出的一部分光线经过偏振复合针孔阵列I,重建一维3D图像；每个一维图像元发出的一部分光线通过与该图像元对应的一维透光针孔I,重建一维3D图像；每个二维图像元发出的一部分光线经过偏振复合针孔阵列I,重建二维3D图像；每个二维图像元发出的一部分光线通过与该图像元对应的二维透光针孔I,重建二维3D图像；重建的一维3D图像和二维3D图像在观看区域合并成一个高分辨率3D图像。(The invention discloses a high-resolution 3D display device based on a dual-polarization composite pinhole array, which comprises a display screen, a polarization composite pinhole array I and a polarization composite pinhole array II, wherein the display screen is provided with a plurality of polarization composite pinholes; the one-dimensional light-transmitting pinhole I and the one-dimensional light-transmitting pinhole II correspond to the one-dimensional image element; the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II correspond to the two-dimensional image element; a part of light rays emitted by each one-dimensional image element pass through the polarization composite pinhole array I to reconstruct a one-dimensional 3D image; a part of light rays emitted by each one-dimensional image element pass through a one-dimensional light-transmitting pinhole I corresponding to the image element to reconstruct a one-dimensional 3D image; a part of light rays emitted by each two-dimensional image element pass through the polarization composite pinhole array I to reconstruct a two-dimensional 3D image; a part of light rays emitted by each two-dimensional image element pass through a two-dimensional light-transmitting pinhole I corresponding to the image element to reconstruct a two-dimensional 3D image; the reconstructed one-dimensional 3D image and the two-dimensional 3D image are combined into one high resolution 3D image at the viewing area.)

1. The high-resolution 3D display device based on the dual-polarization composite pinhole array is characterized by comprising a display screen, a polarization composite pinhole array I and a polarization composite pinhole array II; the display screen, the polarization composite pinhole array I and the polarization composite pinhole array II are sequentially arranged in parallel; the polarization composite pinhole array I is provided with a one-dimensional light-transmitting pinhole I and a two-dimensional light-transmitting pinhole I; the polarization composite pinhole array II is provided with a one-dimensional light-transmitting pinhole II and a two-dimensional light-transmitting pinhole II; the polarization direction of the polarization composite pinhole array I is orthogonal to that of the polarization composite pinhole array II; the display screen is used for displaying the composite image element array; the composite image element array comprises a one-dimensional image element and a two-dimensional image element; the one-dimensional image elements are positioned in odd columns of the composite image element array, and the two-dimensional image elements are positioned in even columns of the composite image element array; the pitches of the one-dimensional image elements and the two-dimensional image elements are the same; the one-dimensional light-transmitting pinhole I and the one-dimensional light-transmitting pinhole II correspond to the one-dimensional image element; the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II correspond to the two-dimensional image element, and the centers of the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II are aligned with the horizontal central axis of the corresponding two-dimensional image element; the interval width of the horizontally adjacent one-dimensional light-transmitting pinhole I corresponding to each one-dimensional image element is equal to the interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element; the number of the one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element and the number of the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element are the same; the number of the one-dimensional light-transmitting pinholes II corresponding to each one-dimensional image element and the number of the two-dimensional light-transmitting pinholes II corresponding to each two-dimensional image element are the same; the horizontal aperture width of the one-dimensional light-transmitting pinhole I is equal to that of the two-dimensional light-transmitting pinhole I; the horizontal aperture width of the one-dimensional light-transmitting pinhole II is equal to that of the two-dimensional light-transmitting pinhole II; the one-dimensional light-transmitting pinhole II corresponding to each one-dimensional image element is positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to the one-dimensional image element, and only one-dimensional light-transmitting pinhole II is arranged between the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element; the interval width of the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element is larger than the horizontal aperture width of the one-dimensional light-transmitting pinholes II positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I; two-dimensional light-transmitting pinholes II corresponding to each two-dimensional image element are positioned between horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to the two-dimensional image element, and only one two-dimensional light-transmitting pinhole II is arranged between the horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element; the interval width of the horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element is larger than the horizontal aperture width of the two-dimensional light-transmitting pinholes II positioned between the horizontally adjacent two-dimensional light-transmitting pinholes I; the one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element are symmetrically arranged by taking the center of the one-dimensional image element as a center; the centers of the one-dimensional light-transmitting pinholes II positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I are correspondingly aligned with the centers of the intervals of the horizontally adjacent one-dimensional light-transmitting pinholes I; the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element are symmetrically arranged by taking the center of the two-dimensional image element as a center; the centers of the two-dimensional light-transmitting pinholes II positioned between the horizontally adjacent two-dimensional light-transmitting pinholes I are correspondingly aligned with the centers of the intervals of the horizontally adjacent two-dimensional light-transmitting pinholes I; a part of light rays emitted by each one-dimensional image element pass through the polarization composite pinhole array I and are modulated into polarized light I with the same polarization direction by the polarization composite pinhole array I, and the polarized light I is projected to an imaging space through a one-dimensional light-transmitting pinhole II corresponding to the one-dimensional image element to reconstruct a one-dimensional 3D image; a part of light rays emitted by each one-dimensional image element pass through a one-dimensional light-transmitting pinhole I corresponding to the image element and are projected to an imaging space through a polarization composite pinhole array II, and a one-dimensional 3D image is reconstructed; a part of light rays emitted by each two-dimensional image element pass through the polarization composite pinhole array I and are modulated into polarized light II with the same polarization direction by the polarization composite pinhole array I, and the polarized light II is projected to an imaging space through the two-dimensional light-transmitting pinholes II corresponding to the two-dimensional image elements to reconstruct a two-dimensional 3D image; a part of light rays emitted by each two-dimensional image element pass through a two-dimensional light-transmitting pinhole I corresponding to the image element and are projected to an imaging space through a polarization composite pinhole array II, and a two-dimensional 3D image is reconstructed; the reconstructed one-dimensional 3D image and the two-dimensional 3D image are combined into one high resolution 3D image at the viewing area.

2. The high-resolution 3D display device based on the dual-polarization composite pinhole array according to claim 1, wherein the horizontal aperture width of the two-dimensional light-transmitting pinholes Iw ₁Horizontal aperture width of two-dimensional light-transmitting pinhole IIw ₂ 、The interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image elementaThickness of polarization composite pinhole array Is、Thickness of polarization composite pinhole array IItSatisfies the following formula

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,gis the distance between the display screen and the polarization composite pinhole array I,dis the distance between the polarization slit grating I and the polarization slit grating II.

3. The high-resolution 3D display device based on the dual-polarization composite pinhole array according to claim 2, wherein the horizontal aperture width of the two-dimensional light-transmitting pinholes Iw ₁Horizontal aperture width of two-dimensional light-transmitting pinhole IIw ₂Satisfies the following formula

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,ais the spacing width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element.

4. The high-resolution 3D display device based on the dual-polarization composite pinhole array according to claim 1, wherein the vertical aperture width of the two-dimensional light-transmitting pinholes Iv ₁And twoDimension the vertical aperture width of the light-transmitting pinhole IIv ₂Satisfies the following formula

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,gis the distance between the display screen and the polarization composite pinhole array I,sis the thickness of the polarization composite pinhole array I,tis the thickness of the polarization composite pinhole array II,dis the distance between the polarization slit grating I and the polarization slit grating II.

5. The dual-polarization composite pinhole array-based high-resolution 3D display device according to claim 1, wherein the horizontal resolution of the 3D image is

Wherein the content of the first and second substances,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,mis the number of picture elements in the horizontal direction of the composite picture element array.

Technical Field

The invention relates to 3D display, in particular to a high-resolution 3D display device based on a dual-polarization composite pinhole array.

Background

The integrated imaging records the information of the 3D scene to a photosensitive film, and projects the information on the photosensitive film to an imaging space by utilizing the principle of reversible light path, thereby reconstructing the 3D scene. Compared with other 3D displays, the integrated imaging 3D display has the advantages of continuous viewing viewpoints, no need of vision-aiding equipment and coherent light and the like. In the prior art, a composite rectangular multi-pinhole array is adopted to increase the resolution: the composite rectangular image element array comprises one-dimensional rectangular image elements and two-dimensional rectangular image elements, wherein the one-dimensional rectangular image elements and the two-dimensional rectangular image elements are alternately arranged in the horizontal direction and the vertical direction; the composite rectangular multi-pinhole array comprises a plurality of groups of one-dimensional rectangular pinholes and a plurality of groups of two-dimensional rectangular pinholes; the number of groups of the one-dimensional rectangular pinholes is equal to the number of groups of the two-dimensional rectangular pinholes; the number of each group of one-dimensional rectangular pinholes in the horizontal direction is equal to that of the one-dimensional rectangular image elements in the horizontal direction, and the number of each group of one-dimensional rectangular pinholes in the vertical direction is equal to that of the one-dimensional rectangular image elements in the vertical direction; the number of each group of two-dimensional rectangular pinholes in the horizontal direction is equal to that of the two-dimensional rectangular image elements in the horizontal direction, and the number of each group of two-dimensional rectangular pinholes in the vertical direction is equal to that of the two-dimensional rectangular image elements in the vertical direction; each one-dimensional rectangular image element corresponds to a plurality of one-dimensional rectangular pinholes, the number of the one-dimensional rectangular pinholes corresponding to each one-dimensional rectangular image element is equal to the number of the groups of the one-dimensional rectangular pinholes, and the plurality of one-dimensional rectangular pinholes are horizontally symmetrical by taking the center of the one-dimensional rectangular image element as a center; each two-dimensional rectangular image element corresponds to a plurality of two-dimensional rectangular pinholes, the number of the two-dimensional rectangular pinholes corresponding to each two-dimensional rectangular image element is equal to the group number of the two-dimensional rectangular pinholes, and the two-dimensional rectangular pinholes are horizontally symmetrical by taking the center of the two-dimensional rectangular image element as the center; the horizontal distance between the adjacent one-dimensional rectangular pinholes corresponding to the same one-dimensional rectangular image element is equal to the horizontal distance between the adjacent two-dimensional rectangular pinholes corresponding to the same two-dimensional rectangular image element; the horizontal pitches of the one-dimensional rectangular pinhole, the two-dimensional rectangular pinhole, the one-dimensional rectangular image element and the two-dimensional rectangular image element are the same; the vertical pitches of the one-dimensional rectangular pinhole, the two-dimensional rectangular pinhole, the one-dimensional rectangular image element and the two-dimensional rectangular image element are the same; the one-dimensional rectangular image elements reconstruct a plurality of one-dimensional 3D images through the corresponding one-dimensional rectangular pinholes, and the two-dimensional rectangular image elements reconstruct a plurality of two-dimensional 3D images through the corresponding two-dimensional rectangular pinholes; the plurality of one-dimensional 3D images and the plurality of two-dimensional 3D images are combined into one high resolution and crosstalk-free 3D image at the viewing area. However, the above-mentioned technical solutions still have the problem of insufficient horizontal resolution.

Disclosure of Invention

The invention provides a high-resolution 3D display device based on a dual-polarization composite pinhole array, which is characterized by comprising a display screen, a polarization composite pinhole array I and a polarization composite pinhole array II, wherein the display screen is as shown in figure 1; the display screen, the polarization composite pinhole array I and the polarization composite pinhole array II are sequentially arranged in parallel; the polarization composite pinhole array I is provided with a one-dimensional light-transmitting pinhole I and a two-dimensional light-transmitting pinhole I, as shown in figure 2; the polarization composite pinhole array II is provided with a one-dimensional light-transmitting pinhole II and a two-dimensional light-transmitting pinhole II, as shown in figure 3; the polarization direction of the polarization composite pinhole array I is orthogonal to that of the polarization composite pinhole array II; the display screen is used for displaying the composite image element array, as shown in FIG. 4; the composite image element array comprises a one-dimensional image element and a two-dimensional image element; the one-dimensional image elements are positioned in odd columns of the composite image element array, and the two-dimensional image elements are positioned in even columns of the composite image element array; the pitches of the one-dimensional image elements and the two-dimensional image elements are the same; the one-dimensional light-transmitting pinhole I and the one-dimensional light-transmitting pinhole II correspond to the one-dimensional image element; the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II correspond to the two-dimensional image element, and the centers of the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II are aligned with the horizontal central axis of the corresponding two-dimensional image element; the interval width of the horizontally adjacent one-dimensional light-transmitting pinhole I corresponding to each one-dimensional image element is equal to the interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element; the number of the one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element and the number of the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element are the same; the number of the one-dimensional light-transmitting pinholes II corresponding to each one-dimensional image element and the number of the two-dimensional light-transmitting pinholes II corresponding to each two-dimensional image element are the same; the horizontal aperture width of the one-dimensional light-transmitting pinhole I is equal to that of the two-dimensional light-transmitting pinhole I; the horizontal aperture width of the one-dimensional light-transmitting pinhole II is equal to that of the two-dimensional light-transmitting pinhole II; the one-dimensional light-transmitting pinhole II corresponding to each one-dimensional image element is positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to the one-dimensional image element, and only one-dimensional light-transmitting pinhole II is arranged between the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element; the interval width of the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element is larger than the horizontal aperture width of the one-dimensional light-transmitting pinholes II positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I; two-dimensional light-transmitting pinholes II corresponding to each two-dimensional image element are positioned between horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to the two-dimensional image element, and only one two-dimensional light-transmitting pinhole II is arranged between the horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element; the interval width of the horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element is larger than the horizontal aperture width of the two-dimensional light-transmitting pinholes II positioned between the horizontally adjacent two-dimensional light-transmitting pinholes I; the one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element are symmetrically arranged by taking the center of the one-dimensional image element as a center; the centers of the one-dimensional light-transmitting pinholes II positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I are correspondingly aligned with the centers of the intervals of the horizontally adjacent one-dimensional light-transmitting pinholes I; the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element are symmetrically arranged by taking the center of the two-dimensional image element as a center; the centers of the two-dimensional light-transmitting pinholes II positioned between the horizontally adjacent two-dimensional light-transmitting pinholes I are correspondingly aligned with the centers of the intervals of the horizontally adjacent two-dimensional light-transmitting pinholes I; a part of light rays emitted by each one-dimensional image element pass through the polarization composite pinhole array I and are modulated into polarized light I with the same polarization direction by the polarization composite pinhole array I, and the polarized light I is projected to an imaging space through a one-dimensional light-transmitting pinhole II corresponding to the one-dimensional image element to reconstruct a one-dimensional 3D image; a part of light rays emitted by each one-dimensional image element pass through a one-dimensional light-transmitting pinhole I corresponding to the image element and are projected to an imaging space through a polarization composite pinhole array II, and a one-dimensional 3D image is reconstructed; a part of light rays emitted by each two-dimensional image element pass through the polarization composite pinhole array I and are modulated into polarized light II with the same polarization direction by the polarization composite pinhole array I, and the polarized light II is projected to an imaging space through the two-dimensional light-transmitting pinholes II corresponding to the two-dimensional image elements to reconstruct a two-dimensional 3D image; a part of light rays emitted by each two-dimensional image element pass through a two-dimensional light-transmitting pinhole I corresponding to the image element and are projected to an imaging space through a polarization composite pinhole array II, and a two-dimensional 3D image is reconstructed; the reconstructed one-dimensional 3D image and the two-dimensional 3D image are combined into one high resolution 3D image at the viewing area.

Preferably, the horizontal aperture width of the two-dimensional light-transmitting pinhole Iw ₁Horizontal aperture width of two-dimensional light-transmitting pinhole IIw ₂ 、The interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image elementaThickness of polarization composite pinhole array Is、Thickness of polarization composite pinhole array IItSatisfies the following formula

（1）

（2）

（3）

（4）

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,gis the distance between the display screen and the polarization composite pinhole array I,dis the distance between the polarization slit grating I and the polarization slit grating II.

Preferably, the horizontal aperture width of the two-dimensional light-transmitting pinhole Iw ₁Horizontal aperture width of two-dimensional light-transmitting pinhole IIw ₂Satisfies the following formula

（5）

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,ais the spacing width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element.

Preferably, the vertical aperture width of the two-dimensional light-transmitting pinhole Iv ₁The width of the vertical aperture of the two-dimensional light-transmitting pinhole IIv ₂Satisfies the following formula

（6）

（7）

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,gis the distance between the display screen and the polarization composite pinhole array I,sis the thickness of the polarization composite pinhole array I,tis the thickness of the polarization composite pinhole array II,dis the distance between the polarization slit grating I and the polarization slit grating II.

Preferably, the 3D image has a horizontal resolution of

（8）

Wherein the content of the first and second substances,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,mis an image in the horizontal direction of the composite image element arrayThe number of elements.

Drawings

FIG. 1 is a schematic view of the structure and horizontal direction of the present invention

FIG. 2 is a schematic diagram of a polarization composite pinhole array I of the present invention

FIG. 3 is a schematic diagram of a polarization composite pinhole array II of the present invention

FIG. 4 is a schematic diagram of a composite image element array according to the present invention

The reference numbers in the figures are:

1. the display screen comprises a display screen, 2. a polarization composite pinhole array I, 3. a polarization composite pinhole array II, 4. a one-dimensional light-transmitting pinhole I, 5. a one-dimensional light-transmitting pinhole II, 6. a two-dimensional light-transmitting pinhole I, 7. a two-dimensional light-transmitting pinhole II, 8. a one-dimensional image element and 9. a two-dimensional image element.

It should be understood that the above-described figures are merely schematic and are not drawn to scale.

Detailed Description

The present invention will be described in further detail with reference to the following detailed description of an exemplary embodiment of the invention. It should be noted that the following examples are only for illustrative purposes and should not be construed as limiting the scope of the present invention, and that the skilled person in the art may make modifications and adaptations of the present invention without departing from the scope of the present invention.

The invention provides a high-resolution 3D display device based on a dual-polarization composite pinhole array, which is characterized by comprising a display screen, a polarization composite pinhole array I and a polarization composite pinhole array II, wherein the display screen is as shown in figure 1; the display screen, the polarization composite pinhole array I and the polarization composite pinhole array II are sequentially arranged in parallel; the polarization composite pinhole array I is provided with a one-dimensional light-transmitting pinhole I and a two-dimensional light-transmitting pinhole I, as shown in figure 2; the polarization composite pinhole array II is provided with a one-dimensional light-transmitting pinhole II and a two-dimensional light-transmitting pinhole II, as shown in figure 3; the polarization direction of the polarization composite pinhole array I is orthogonal to that of the polarization composite pinhole array II; the display screen is used for displaying the composite image element array, as shown in FIG. 4; the composite image element array comprises a one-dimensional image element and a two-dimensional image element; the one-dimensional image elements are positioned in odd columns of the composite image element array, and the two-dimensional image elements are positioned in even columns of the composite image element array; the pitches of the one-dimensional image elements and the two-dimensional image elements are the same; the one-dimensional light-transmitting pinhole I and the one-dimensional light-transmitting pinhole II correspond to the one-dimensional image element; the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II correspond to the two-dimensional image element, and the centers of the two-dimensional light-transmitting pinhole I and the two-dimensional light-transmitting pinhole II are aligned with the horizontal central axis of the corresponding two-dimensional image element; the interval width of the horizontally adjacent one-dimensional light-transmitting pinhole I corresponding to each one-dimensional image element is equal to the interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element; the number of the one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element and the number of the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element are the same; the number of the one-dimensional light-transmitting pinholes II corresponding to each one-dimensional image element and the number of the two-dimensional light-transmitting pinholes II corresponding to each two-dimensional image element are the same; the horizontal aperture width of the one-dimensional light-transmitting pinhole I is equal to that of the two-dimensional light-transmitting pinhole I; the horizontal aperture width of the one-dimensional light-transmitting pinhole II is equal to that of the two-dimensional light-transmitting pinhole II; the one-dimensional light-transmitting pinhole II corresponding to each one-dimensional image element is positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to the one-dimensional image element, and only one-dimensional light-transmitting pinhole II is arranged between the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element; the interval width of the horizontally adjacent one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element is larger than the horizontal aperture width of the one-dimensional light-transmitting pinholes II positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I; two-dimensional light-transmitting pinholes II corresponding to each two-dimensional image element are positioned between horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to the two-dimensional image element, and only one two-dimensional light-transmitting pinhole II is arranged between the horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element; the interval width of the horizontally adjacent two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element is larger than the horizontal aperture width of the two-dimensional light-transmitting pinholes II positioned between the horizontally adjacent two-dimensional light-transmitting pinholes I; the one-dimensional light-transmitting pinholes I corresponding to each one-dimensional image element are symmetrically arranged by taking the center of the one-dimensional image element as a center; the centers of the one-dimensional light-transmitting pinholes II positioned between the horizontally adjacent one-dimensional light-transmitting pinholes I are correspondingly aligned with the centers of the intervals of the horizontally adjacent one-dimensional light-transmitting pinholes I; the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element are symmetrically arranged by taking the center of the two-dimensional image element as a center; the centers of the two-dimensional light-transmitting pinholes II positioned between the horizontally adjacent two-dimensional light-transmitting pinholes I are correspondingly aligned with the centers of the intervals of the horizontally adjacent two-dimensional light-transmitting pinholes I; a part of light rays emitted by each one-dimensional image element pass through the polarization composite pinhole array I and are modulated into polarized light I with the same polarization direction by the polarization composite pinhole array I, and the polarized light I is projected to an imaging space through a one-dimensional light-transmitting pinhole II corresponding to the one-dimensional image element to reconstruct a one-dimensional 3D image; a part of light rays emitted by each one-dimensional image element pass through a one-dimensional light-transmitting pinhole I corresponding to the image element and are projected to an imaging space through a polarization composite pinhole array II, and a one-dimensional 3D image is reconstructed; a part of light rays emitted by each two-dimensional image element pass through the polarization composite pinhole array I and are modulated into polarized light II with the same polarization direction by the polarization composite pinhole array I, and the polarized light II is projected to an imaging space through the two-dimensional light-transmitting pinholes II corresponding to the two-dimensional image elements to reconstruct a two-dimensional 3D image; a part of light rays emitted by each two-dimensional image element pass through a two-dimensional light-transmitting pinhole I corresponding to the image element and are projected to an imaging space through a polarization composite pinhole array II, and a two-dimensional 3D image is reconstructed; the reconstructed one-dimensional 3D image and the two-dimensional 3D image are combined into one high resolution 3D image at the viewing area.

Preferably, the horizontal aperture width of the two-dimensional light-transmitting pinhole Iw ₁Horizontal aperture width of two-dimensional light-transmitting pinhole IIw ₂ 、The interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image elementaThickness of polarization composite pinhole array Is、Thickness of polarization composite pinhole array IItSatisfies the following formula

（1）

（2）

（3）

（4）

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,gis the distance between the display screen and the polarization composite pinhole array I,dis the distance between the polarization slit grating I and the polarization slit grating II.

Preferably, the horizontal aperture width of the two-dimensional light-transmitting pinhole Iw ₁Horizontal aperture width of two-dimensional light-transmitting pinhole IIw ₂Satisfies the following formula

（5）

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,ais the spacing width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element.

Preferably, the vertical aperture width of the two-dimensional light-transmitting pinhole Iv ₁The width of the vertical aperture of the two-dimensional light-transmitting pinhole IIv ₂Satisfies the following formula

（6）

（7）

Wherein the content of the first and second substances,pis the pitch of the two-dimensional picture elements,gis the distance between the display screen and the polarization composite pinhole array I,sis a polarization composite pinholeThe thickness of the array I is such that,tis the thickness of the polarization composite pinhole array II,dis the distance between the polarization slit grating I and the polarization slit grating II.

Preferably, the 3D image has a horizontal resolution of

（8）

Wherein the content of the first and second substances,nis the number of two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element,mis the number of picture elements in the horizontal direction of the composite picture element array.

The pitch of the two-dimensional image elements is 8mm, the distance between the display screen and the polarization composite pinhole array I is 2mm, the distance between the polarization composite pinhole array I and the polarization composite pinhole array II is 0.2mm, the horizontal aperture width of the two-dimensional light-transmitting pinholes I is 1mm, the number of the two-dimensional light-transmitting pinholes I corresponding to each two-dimensional image element is 2, the number of the image elements in the horizontal direction of the composite image element array is 10, and the horizontal aperture width of the two-dimensional light-transmitting pinholes II is obtained by calculating the formulas (1), (2), (3), (4) and (5)、The interval width of the horizontally adjacent two-dimensional light-transmitting pinhole I corresponding to each two-dimensional image element and the thickness of the polarization composite pinhole array I、The thicknesses of the polarization composite pinhole array II are 1.6mm, 2mm, 1mm and 1.6mm respectively; the vertical aperture width of the two-dimensional light-transmitting pinhole I is calculated by the formulas (6) and (7)、The vertical aperture widths of the two-dimensional light-transmitting pinhole II are 1.6mm and 1.6mm respectively; the horizontal resolution of the 3D image calculated by equation (8) is 30.