WO2018103436A1

WO2018103436A1 - 3d display enabling case, display method and apparatus, and storage medium

Info

Publication number: WO2018103436A1
Application number: PCT/CN2017/104271
Authority: WO
Inventors: 高炜; 谭杰夫
Original assignee: 深圳全息信息科技发展有限公司
Priority date: 2016-12-08
Filing date: 2017-09-29
Publication date: 2018-06-14
Also published as: CN106526877A

Abstract

A 3D display enabling case, a display method and apparatus, and a storage medium, which aims to solve the problem that the current display product cannot achieve the compatibility of 2D and 3D display. A 3D display enabling case comprises a display enabling case body (11), the display enabling case body (11) being provided with a mold cavity for receiving a 2D display device, the shape of the inner surface thereof being adaptive to the shell of the 2D display device, a display enabling portion (12) of the display enabling case body (11) at least corresponding to the front-view surface or the rear-view surface of the 2D display device being made of a high light-transmittance material, the inner side (22) of the display enabling case body (11) being a microlens array. The function of glasses-free 3D can be achieved by fitting this kind of 3D display enabling case over the front surface of a 2D display device to cover the screen; the apertures on the 3D display enabling case are designed symmetrically, comprising the apertures (131, 132, 141, 142, 143) exposing the camera, home key, earphone hole, volume button and on/off button; the 3D display enabling case is a normal mobile phone case when it is fitted to the rear surface of the 2D display device, and has a protection function.

Description

3D display sleeve, display method, device and storage medium

Technical field

The invention belongs to the technical field of 3D display, and in particular relates to a 3D display sleeve, a display method, a device and a storage medium.

Background technique

In recent years, with the continuous maturity of 3D technology, the 3D display industry has developed rapidly, and various 3D display products have been introduced to the market, for example, naked-eye 3D mobile phones, naked-eye 3D tablet computers, naked-eye 3D displays, naked-eye 3D TVs, naked-eye 3D advertising machines, etc. Wait. At present, the naked eye 3D mainstream technology mainly includes the following types: liquid crystal switchable slit grating, reflective fixed slit grating, cylindrical lens optical film, rhomboid lens optical film, liquid crystal lenticular lens and the like. It is ubiquitously expensive, has a long cycle, is difficult to promote, and requires additional design at the product design stage, which is irrevocable once customized.

VR helmet display box, although it can display naked-eye 3D content in 2D equipment, it is cumbersome, which is not conducive to carrying, distortion, resolution and other defects. And the VR display helmet is only suitable for mobile phones, and there is no VR helmet suitable for display devices such as tablets, computers, and televisions. The 3D film of the mobile phone has the disadvantages of requiring the user to operate the alignment on its own and affecting the original 2D display effect.

On the other hand, most of the movie and TV content has been opened in 3D format production, 3D game development and rapid development, 3D content emerges endlessly. Existing 2D display smartphones, iPhones, iPads, tablets, smart TVs or other smart products have become popular in people's lives, but these products can only be displayed in 2D and cannot be displayed in 3D. It is meaningful if the 2D display device of the stock can display a high-quality naked-eye 3D effect without affecting the original 2D effect.

Summary of the invention

In view of the above problems to be solved. The invention provides a 3D display sleeve, a display method and a device thereof The storage medium is designed to solve the problem that the existing 2D display products cannot achieve 3D display.

In one aspect, a 3D display cover is provided for a 2D display device, the 3D display cover includes a display sleeve body, and the display sleeve body is provided with a cavity for accommodating a 2D display device, the shape of the inner surface thereof and the 2D display device The outer casing is adapted. At least the display portion of the display sleeve body corresponding to the front or rear viewing surface of the 2D display device is made of a high light transmissive material, and the inner side of the display sleeve body is a microlens array.

Preferably, the display sleeve has only a partial cover body corresponding to the screen as a high light transmissive material, and the high light transmissive material sleeve portion has a microlens array on the inner side, and the remaining part is made of a common material to save cost.

The microlens array is a columnar lens or a rhombohedral lens array arranged in parallel and arranged at a predetermined angle with respect to the screen. The width of a single lens in the microlens array is N times the pixel width of the display device, and the N is a value greater than or equal to 2 and less than or equal to 4.

Further, the display sleeve body is detachably connected to the 2D display device, and the display sleeve body is connected to the 2D display device by a structure of wrapping four corners, wrapping four sides or a combination of the two.

Preferably, the 3D display sleeve can also be sleeved on the back of the display device, like an ordinary mobile phone protective cover, which has the protection function against the mobile phone and the anti-scratch effect on the back.

Further, the front view surface of the display sleeve body is provided with a plurality of first vacancies, and the position and shape of the first vacancy position correspond to the position and shape of the rear device and the front device of the 2D display device, and multiple When the first vacancies overlap, they can be merged into one vacancy.

Further, the four side viewing surfaces of the display sleeve body are provided with a plurality of second vacancies, and the position and shape of the second vacancy position correspond to the position and shape of the protruding portion or the opening portion of the 2D display device. And when the plurality of second vacancies overlap, they can be merged into one vacancy.

Further, the second vacancies are symmetrically disposed on the left and right sides of the corresponding side view.

In another aspect, a 3D display method is provided for a 2D display device that is provided with a 3D display sleeve as described above, the method comprising:

Obtaining the position of the human eye through the front camera and calculating the display angle corresponding to the position of the human eye;

Querying a preset correction parameter table by using the display angle to obtain a pixel interleaving parameter matrix corresponding to the display angle;

Interleaving the 3D picture according to the pixel interleaving parameter matrix, and outputting the interleaved picture;

The interleaved picture is displayed.

Further, the step of acquiring the position of the human eye through the front camera and calculating the display angle corresponding to the position of the human eye includes:

The human eye image obtained by the front camera is divided into M equal parts horizontally, and is divided into N equal parts in the longitudinal direction to obtain M*N picture areas, and the M and N are positive integers;

The horizontal or vertical display angle is calculated for each screen area, and the display angle corresponding to the screen area where the human eye is located is used as the display angle corresponding to the position of the human eye.

Further, the number of elements of the pixel interleaving parameter matrix is equal to the number of screen pixels of the 2D display device, and is mapped one by one.

Further, the 3D picture is a left and right format or a top and bottom format picture.

In still another aspect, a 3D display device is provided for a 2D display device that is provided with a 3D display sleeve as described above, the 3D display device comprising:

An angle obtaining unit, configured to acquire a position of a human eye through a front camera, and calculate a display angle corresponding to a position of the human eye;

a parameter obtaining unit, configured to query a preset correction parameter table by using the display angle, and obtain a pixel interleaving parameter matrix corresponding to the display angle;

a picture interleaving unit, configured to interleave a 3D picture according to the pixel interleaving parameter matrix, and output the interleaved picture;

A picture display unit is configured to display the interleaved picture.

Further, the angle obtaining unit includes:

The screen dividing module is configured to divide the human eye image obtained by the front camera into M equal parts, and divide it into N equal parts in the longitudinal direction to obtain M*N picture areas, where the M and N are positive integers;

The angle obtaining module is configured to calculate a horizontal or vertical display angle corresponding to each screen area, and the display angle corresponding to the screen area where the human eye is located is used as the display angle corresponding to the position of the human eye.

Further, the number of elements of the pixel interleaving parameter matrix is compared with the number of screen pixels of the 2D display device Wait, and map them one by one.

In a fourth aspect, there is provided a storage medium suitable for use in a 2D display device incorporating a 3D display sleeve as described above, the storage medium comprising: a program, wherein the program causes the 2D display device to perform:

The interleaved picture is displayed.

Further, the program causes the 2D display device to further perform:

In the embodiment of the present invention, a naked-eye 3D mobile phone case is formed by a high light-transmissive material, and the inner side of the corresponding mobile phone screen is a microlens array, and the microlens array is at an angle with the mobile phone. Arranged in parallel. When the cover is overlaid on the front of the phone, the specified program can be run at this time to display the naked eye 3D effect. The preset space on the mobile phone case is: symmetrical design. Includes vacancies that expose the camera, home button, headphone jack, volume button, and power button. It protects the phone when it is placed on the back of the phone. At the same time, on the basis of the above protective cover, the human eye tracking is performed by the current camera, and the sub-pixel arrangement of the output screen is adjusted according to the position of the human eye, so that the continuous angle naked-eye 3D viewing effect can be realized. The viewing range is limited by the FOV field of view of the front camera.

DRAWINGS

1 is a schematic structural diagram of a 3D display sleeve of a mobile phone according to Embodiment 1 of the present invention;

2 is a schematic structural diagram of a display portion of a display sleeve body according to Embodiment 1 of the present invention;

3 is a schematic structural view of a 3D display cover of a mobile phone according to Embodiment 2 of the present invention;

4 is a schematic block diagram of a 3D display method according to Embodiment 3 of the present invention;

FIG. 5 is a schematic block diagram showing the structure of a 3D display device according to Embodiment 4 of the present invention.

detailed description

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that the 3D display sleeve of the embodiment of the present invention is applicable to a 2D display device, including but not limited to a 2D mobile phone, a 2D tablet computer, and an ipad. The following embodiments are only exemplified by a 2D mobile phone (hereinafter referred to as a mobile phone).

Embodiment 1

Referring to FIG. 1 together, the 3D display sleeve provided by the first embodiment of the present invention is a mobile phone case, which comprises a display sleeve body 11. The display sleeve body is provided with a cavity for accommodating the mobile phone, and the shape of the inner surface thereof and the outer casing of the mobile phone Suitably, at least the display portion 12 of the display sleeve body corresponding to the front or rear view of the mobile phone is made of a high light transmissive material, and the display portion 12 of the display sleeve body is a dotted line as shown in FIG. In the region, the inner side of the display sleeve body is a microlens array. The display portion 12 of the display sleeve body refers to a portion opposite to the screen when the front surface is sleeved on the mobile phone. The display portion 12 of the display sleeve body must be made of a high light transmissive material. When the front surface of the mobile phone is sleeved, the display portion 12 of the display sleeve body faces the screen; when the reverse side of the mobile phone is sleeved, the display sleeve body The display portion 12 faces the back of the mobile phone. The other parts of the display sleeve body may be made of a high light transmissive material or other materials. The display sleeve body may be a single layer, a multi-layer paste or a composite layer. The microlens array has the effect of changing the light path. Existing conventional transparent material mobile phone sets are only transmitted directly and do not change the light path.

As shown in FIG. 2, the display portion 12 of the display sleeve body has a high light transmissive material on the outer side 21 and a microlens array on the inner side 22. Different from the existing mobile phone case, it is made of transparent material and can only be placed on the back of the mobile phone to protect it.

Wherein, the microlens array is a columnar lens or a rhombohedral array arranged in parallel.

Further, the microlens array is arranged at a predetermined angle with respect to the screen.

Further, the width of the single lens in the microlens array is N times the pixel width of the display device, and the N is a value greater than or equal to 2 and less than or equal to 4.

The above 3D display sleeve wraps the mobile phone in a detachable manner, and has the following two types:

In one case, the display sleeve body is connected to the mobile phone by wrapping the four corners;

In another case, the display sleeve body is connected to the mobile phone by wrapping the four sides;

In another case, the display sleeve body is connected to the mobile phone by wrapping the four-corner and four-sided structures.

In this embodiment, the display portion of the display sleeve body is made of a high light transmissive material, and the inner side of the display sleeve body is a microlens array, which is sleeved on the front surface of the mobile phone to cover the screen, and can realize the naked eye 3D function.

Embodiment 2

As shown in FIG. 3, the 3D display cover provided by the second embodiment of the present invention is a mobile phone case. On the basis of the first embodiment, the display cover body is detachably connected to the mobile phone by wrapping the four sides.

Further, the front side of the display sleeve body is provided with two

first vacancies

131, 132, and the position and shape of the first vacancy correspond to the position and shape of the rear camera and the front camera of the mobile phone and the home button. And when the plurality of

first vacancies

131, 132 overlap, they may merge into one vacancy. The setting of the first vacancy takes into account both the front side and the back side.

Further, the four side viewing surfaces of the display sleeve body are provided with three

second vacancies

141, 142, 143, the position and shape of the

second vacancies

141, 142, 143 and the volume button and the switch of the mobile phone. The positions and shapes of the buttons correspond to each other, and when the plurality of

second vacancies

141, 142, and 143 overlap, they can be merged into one vacancy, so that the sleeves on the front side and the reverse side do not affect the use of the side switch button and the volume button on the side of the mobile phone.

Further, the second vacancies are symmetrically disposed on the left and right sides of the corresponding side view. The side view includes Left side view, right side view, bottom view face, and top view face. In FIG. 3, the

second vacancies

141, 143 are symmetrically arranged to facilitate the use of the cover when placed on the back of the mobile phone, and function as a protective cover.

In this embodiment, the display portion of the display sleeve body is made of a high light transmissive material, and the inner side of the display sleeve body is a microlens array, which covers the front surface of the mobile phone and can realize the naked eye 3D function, and the vacancy is symmetric. The design includes exposing the camera, home button, earphone jack, volume button and the button of the switch button, which is placed on the back of the mobile phone. At this time, it is an ordinary mobile phone case with protection function.

Embodiment 3

FIG. 4 is a flowchart showing an implementation of a 3D display method according to Embodiment 3 of the present invention. The method is applicable to a 2D display device that includes the 3D display sleeves described in Embodiments 1 and 2. The 2D display device includes but is not limited to Mobile phone, tablet, ipad. The following is a mobile phone as an example, as detailed below:

In step S401, the position of the human eye is acquired by the front camera of the mobile phone, and the display angle corresponding to the position of the human eye is calculated.

In this embodiment, on the mobile phone with the 3D display sleeve, the 3D playback APP is opened, and the APP obtains the current human eye position through the front camera of the mobile phone, and calculates the display angle corresponding to the position of the human eye. The specific steps are as follows:

Sub-step S11, the human eye image obtained by the front camera of the mobile phone is divided into M equal parts horizontally, and is divided into N equal parts in the longitudinal direction to obtain M*N picture areas, where M and N are positive integers;

Among them, the values of M and N are related to the optical angle design, assuming that the 3D visible area is 8 degrees, the camera lateral viewing angle FOV is 100 degrees, and the theoretical M value is greater than 13, preferably, M:N is 4:3 or 16 :9.

Sub-step S12, calculating a horizontal or vertical display angle corresponding to each screen area, and using the display angle corresponding to the screen area where the human eye is located as the display angle corresponding to the position of the human eye.

In step S402, the preset correction parameter table is queried by the display angle to obtain a pixel interleaving parameter matrix corresponding to the display angle.

In this embodiment, the number of elements of the pixel interleaving parameter matrix is equal to the number of screen pixels of the mobile phone, and is mapped one by one. Wherein, the matrix element is a 1-bit information quantity, and the pixel of the mapped mobile phone screen is the left eye or The right eye pixel; or its matrix element is a 3-bit information amount, and the RGB sub-pixel representing the mapped mobile phone screen pixel is a left eye or a right eye sub-pixel.

In step S403, the 3D picture is interleaved according to the pixel interleaving parameter matrix, and the interleaved picture is output.

In this embodiment, the 3D picture is a left and right format or a top and bottom format picture.

In step S404, the interleaved picture is displayed.

In this embodiment, based on the display sleeve in the first embodiment, the mobile phone performs human eye tracking through the current camera, and adjusts the sub-pixel arrangement of the output screen according to the position of the human eye, so that the multi-angle naked-eye 3D viewing effect can be realized.

Embodiment 4

FIG. 5 is a block diagram showing a specific structure of a 3D display device according to Embodiment 4 of the present invention. For convenience of description, only parts related to the embodiment of the present invention are shown. In this embodiment, the device is applicable to a 2D display device that is provided with the 3D display sleeve of the first embodiment and the second embodiment. The 3D display device includes: an angle acquisition unit 51, a parameter acquisition unit 52, a picture interleaving unit 53 and Screen display unit 54.

The angle obtaining unit 51 is configured to acquire a position of a human eye through a front camera, and calculate a display angle corresponding to a position of the human eye;

The parameter obtaining unit 52 is configured to query the preset correction parameter table by using the display angle to obtain a pixel interleaving parameter matrix corresponding to the display angle;

The picture interleaving unit 53 is configured to interleave the 3D picture according to the pixel interleaving parameter matrix, and output the interleaved picture;

The screen display unit 54 is configured to display the interleaved screen.

Further, the angle obtaining unit 51 includes:

The screen dividing module is configured to divide the human eye image obtained by the front camera of the mobile phone into M equal parts horizontally, and divide into two equal parts in the longitudinal direction to obtain M*N picture areas, where the M and N are positive integers;

Further, the number of elements of the pixel interleaving parameter matrix is equal to the number of screen pixels of the mobile phone, and is mapped one by one. The matrix element is a 1-bit information quantity, and the pixel of the mapped mobile phone screen is a left-eye or right-eye pixel; or the matrix element is a 3-bit information amount, and the RGB sub-pixel of the mapped mobile phone screen pixel is a left-eye or right-eye sub-pixel. .

In this embodiment, on the basis of the protective cover, the mobile phone performs human eye tracking through the current camera, and adjusts the sub-pixel arrangement of the output screen according to the position of the human eye, so that the multi-angle naked-eye 3D viewing effect can be realized.

The 3D display device provided by the embodiment of the present invention can be applied to the foregoing third embodiment of the method. For details, refer to the description of the third embodiment, and details are not described herein again.

Embodiment 5

The fifth embodiment of the present invention provides a storage medium, which is applicable to a 2D display device that is provided with the 3D display sleeve described in Embodiments 1 and 2. The storage medium includes: a program, wherein the program causes the 2D display device execution:

The interleaved picture is displayed.

Further, the program causes the 2D display device to further perform:

The above are only the preferred embodiments of the present invention, and are not intended to limit the present invention. Any modifications, equivalents, and improvements made within the spirit and scope of the present invention should be included in the scope of the present invention. Inside.

Claims

A 3D display sleeve suitable for a 2D display device, the 3D display sleeve comprising a display sleeve body, the display sleeve body being provided with a cavity for accommodating a 2D display device, the shape of the inner surface being adapted to the outer casing of the 2D display device The display portion of the display sleeve body corresponding to at least the front or rear view surface of the 2D display device is made of a high light transmissive material, and the inner side of the display sleeve body is a microlens array.
The 3D display sleeve according to claim 1, wherein the microlens array is a lenticular lens or a rhombohedral array arranged in parallel.
The 3D display sleeve according to claim 2, wherein the microlens array is arranged at a predetermined angle with respect to the screen.
The 3D display sleeve according to claim 2, wherein a width of a single lens in the microlens array is N times a pixel width of the display device, and the N is a value greater than or equal to 2 and less than or equal to 4.
The 3D display sleeve according to claim 1, wherein the display sleeve body is detachably connected to the 2D display device.
The 3D display sleeve according to claim 5, wherein the display sleeve body is connected to the 2D display device by a structure of wrapping four corners, wrapping four sides or a combination of the two.
The 3D display sleeve according to claim 6, wherein the front surface of the display sleeve body is provided with a plurality of first vacancies, the position and shape of the first vacancy and the rear device of the 2D display device and The position and shape of the front device correspond to each other, and when the plurality of first vacancies overlap, they can be merged into one vacancy.
The 3D display sleeve according to claim 6 or 7, wherein when the display sleeve body is a structure enclosing four sides, the four side viewing surfaces of the display sleeve body are provided with a plurality of second vacancies, The position and shape of the second vacancy correspond to the position and shape of the protruding portion or the opening portion of the 2D display device, and the plurality of second vacancies may merge into one vacancy when overlapping.
The 3D display sleeve according to claim 8, wherein the second vacancies are symmetrically disposed on the left and right sides of the respective side viewing surfaces.
A 3D display sleeve comprising a display sleeve body, the display sleeve body being provided with a cavity for accommodating a 2D display device, the shape of the inner surface being adapted to the outer casing of the 2D display device, characterized in that The display sleeve body includes a display portion made of a high light transmissive material, and an inner side of the display portion is provided with a microlens array.
The 3D display sleeve according to claim 10, wherein the microlens array is a lenticular lens or a rhombohedral array arranged in parallel.
The 3D display sleeve according to claim 11, wherein the microlens arrays are arranged at a predetermined angle.
The 3D display sleeve according to claim 11, wherein a width of a single lens in the microlens array is N times a pixel width of the display device, and the N is a value greater than or equal to 2 and less than or equal to 4.
The 3D display sleeve of claim 10, wherein the display sleeve body removably wraps the 2D display device.
The 3D display sleeve according to claim 14, wherein a plurality of first vacancies are disposed on a surface of the display sleeve body on which the display portion is located, and a position, a shape, and a 2D display device of the first vacancy The position and shape of the rear device and the front device correspond to each other, and the plurality of first vacancies overlap to form a vacancy.
The 3D display sleeve according to claim 15 or 14, wherein the display sleeve body further comprises four sides enclosing four sides of the 2D display device, and a plurality of second vacancies are disposed on the four sides, The position and shape of the second vacancy correspond to the position and shape of the protruding portion or the opening portion of the 2D display device, and the plurality of second vacancies are merged into one vacancy when overlapping.
The 3D display sleeve according to claim 16, wherein the second vacancies are symmetrically disposed on the left and right sides of the respective side viewing surfaces.
A 3D display device, which is suitable for a 2D display device, which is provided with the 3D display sleeve of any one of claims 1-9 or 10-17, wherein the method comprises:

Obtaining the position of the human eye through the front camera and calculating the display angle corresponding to the position of the human eye;

Querying a preset correction parameter table by using the display angle to obtain a pixel interleaving parameter matrix corresponding to the display angle;

Interleaving the 3D picture according to the pixel interleaving parameter matrix, and outputting the interleaved picture;

The interleaved picture is displayed.
The 3D display method according to claim 18, wherein the step of acquiring the position of the human eye through the front camera and calculating the display angle corresponding to the position of the human eye comprises:

The human eye image obtained by the front camera is divided into M equal parts horizontally, and is divided into N equal parts in the longitudinal direction to obtain M*N picture areas, and the M and N are positive integers;

The horizontal or vertical display angle is calculated for each screen area, and the display angle corresponding to the screen area where the human eye is located is used as the display angle corresponding to the position of the human eye.
The 3D display method according to claim 18, wherein the number of elements of the pixel interleaving parameter matrix is equal to the number of screen pixels of the 2D display device, and is mapped one by one.
The 3D display method according to claim 18, wherein the 3D picture is a left-right format or a top-and-bottom format picture.
A 3D display device, which is suitable for a 2D display device, which is provided with the 3D display sleeve of any one of claims 1-9 or 10-17, wherein the 3D display device comprises:

An angle obtaining unit, configured to acquire a position of a human eye through a front camera, and calculate a display angle corresponding to a position of the human eye;

a parameter obtaining unit, configured to query a preset correction parameter table by using the display angle, and obtain a pixel interleaving parameter matrix corresponding to the display angle;

a picture interleaving unit, configured to interleave a 3D picture according to the pixel interleaving parameter matrix, and output the interleaved picture;

A picture display unit is configured to display the interleaved picture.
The 3D display device according to claim 22, wherein the angle acquisition unit comprises:

The screen dividing module is configured to divide the human eye image obtained by the front camera into M equal parts, and vertically Dividing into N equal parts, obtaining M*N picture areas, where M and N are positive integers;

The angle obtaining module is configured to calculate a horizontal or vertical display angle corresponding to each screen area, and the display angle corresponding to the screen area where the human eye is located is used as the display angle corresponding to the position of the human eye.
The 3D display device according to claim 22, wherein the number of elements of the pixel interleaving parameter matrix is equal to the number of screen pixels of the 2D display device, and is mapped one by one.
The 3D display device according to claim 22, wherein the 3D picture is a left-right format or a top-and-bottom format picture.
A storage medium suitable for a 2D display device provided with the 3D display sleeve of any one of claims 1-9 or 10-17, characterized in that the storage medium comprises: a program, wherein the program The 2D display device executes:

Obtaining the position of the human eye through the front camera and calculating the display angle corresponding to the position of the human eye;

Querying a preset correction parameter table by using the display angle to obtain a pixel interleaving parameter matrix corresponding to the display angle;

Interleaving the 3D picture according to the pixel interleaving parameter matrix, and outputting the interleaved picture;

The interleaved picture is displayed.
The storage medium according to claim 26, wherein said program causes said 2D display device to further perform:

The screen dividing module is configured to divide the human eye image obtained by the front camera into M equal parts, and divide it into N equal parts in the longitudinal direction to obtain M*N picture areas, where the M and N are positive integers;

The angle obtaining module is configured to calculate a horizontal or vertical display angle corresponding to each screen area, and the display angle corresponding to the screen area where the human eye is located is used as the display angle corresponding to the position of the human eye.
The storage medium according to claim 26, wherein the number of elements of the pixel interleaving parameter matrix is equal to the number of screen pixels of the 2D display device, and is mapped one by one.
The storage medium according to claim 26, wherein the 3D picture is a left-right format or a top-and-bottom format picture.