KR101511227B1 - Method for generation 3D image based on Flash - Google Patents

Abstract

The present invention relates to a flash-based stereoscopic image generation method, and more particularly, to a method of generating a stereoscopic image using a flash based method, And a flash-based stereoscopic image generation method capable of driving a stereoscopic image on the web without converting the stereoscopic image into a 3D image player or a 3D mode.
The present invention provides a method of generating a flash based stereoscopic image, comprising: loading a left image and a right image for generating a stereoscopic image; Forming a line unit mask on the left image by alternately arranging the masks one row at a time in a line corresponding to the pixel row unit of the left image; Forming a line unit mask on the right image by alternately arranging the masks one row at a time in a row corresponding to the pixel row unit of the right image; Adjusting the parallax of the left image or the right image formed with the line unit mask to adjust the perspective of the displayed image; And generating a flash file in which the left image and the right image formed by the line unit mask are alternately displayed on a pixel line to form a stereoscopic frame.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a method for generating a flash-

The present invention relates to a flash-based stereoscopic image generation method, and more particularly, to a method of generating a stereoscopic image using a flash based method, And a flash-based stereoscopic image generation method capable of driving a stereoscopic image on the web without converting the stereoscopic image into a 3D image player or a 3D mode.

Since a person has a pair of eyes spaced at a certain distance from each other, when the object is viewed, both eyes look at the object in different directions. Thus, the image viewed from different directions is synthesized in the brain, And can be recognized as a stereoscopic image.

In recent years, various types of stereoscopic image display systems have been developed that enable stereoscopic images to be displayed using such a principle. Such a stereoscopic image display system is composed of a display device capable of displaying a stereoscopic image and stereoscopic image-dedicated glasses used by a user.

At this time, in the stereoscopic image display system, the image displayed by the display device is divided into a left visual field image such as a left eye and a right visual field image such as a right visual field, It can be obtained by using two cameras. Therefore, the left visual field image and the right visual field image are alternately displayed using the display device, and the left visual field image is transmitted to the left eye and the right visual field image to the right eye using the stereoscopic exclusive glasses, Allow stereoscopic images to be viewed.

Such a stereoscopic image technique firstly uses a liquid crystal shutter for periodically repeating a time-divided image on a display and using a pair of glasses provided with a liquid crystal shutter to synchronize the images with each other to distribute an image according to the time difference in a time- A polarizing spectacle system, that is, a passive system in which left and right images of a display are displayed using a polarizing filter and is distributed to left and right eyes by using polarized glasses is employed.

In recent years, various types of terminals having a screen capable of displaying images, such as a computer monitor device, a PMP, a portable game machine, a mobile phone, or a smart phone have been developed and widely used. Consumers who want to see are increasing.

On the other hand, in order to generate a stereoscopic image, it is inconvenient to use a complicated program used by specialized developers such as 3DMAX program of autodesk. In order to display the stereoscopic images generated through the 3D, There has been an inconvenience that a video player or 3D mode conversion must be performed.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art. That is, an object of the present invention is to provide a method and apparatus for generating a stereoscopic image on a flash basis rather than a complicated program used by stereoscopic image developers, And a stereoscopic image generation method.

According to an aspect of the present invention, there is provided a method of generating a flash based stereoscopic image, the method comprising: loading a left image and a right image for generating a stereoscopic image; Forming a line unit mask on the left image by alternately arranging the masks one row at a time in a line corresponding to the pixel row unit of the left image; Forming a line unit mask on the right image by alternately arranging the masks one row at a time in a row corresponding to the pixel row unit of the right image; Adjusting the parallax of the left image or the right image formed with the line unit mask to adjust the perspective of the displayed image; Generating a flash file in which the left image and the right image formed with the line unit mask are alternately displayed on a pixel line to form a stereoscopic frame; And adjusting the parallax so that the right image is positioned on the right side of the left image when the displayed image is to be viewed behind the screen in the step of adjusting the perspective of the displayed image. Based stereoscopic image generation method.

The flash based stereoscopic image generation method according to the present invention can easily generate a stereoscopic image based on flash rather than a complicated program used by stereoscopic image development developers. If the 3D stereoscopic display and the polarizing glasses are used, You will be able to view and control the stereoscopic screen in a normal internet window without converting the player or 3D mode.

1 is a flowchart of a stereoscopic image generation method according to an embodiment of the present invention;
FIG. 2 illustrates an example of applying a mask to a left image according to an embodiment of the present invention. FIG.
3 is an example of applying a mask to a right image according to an embodiment of the present invention.
4 is an example of a combination of a left image and a right image according to an embodiment of the present invention.
5 to 19 are examples of the time difference adjustment according to an embodiment of the present invention.

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

1 is a flowchart of a stereoscopic image generation method according to an embodiment of the present invention.

As shown in FIG. 1, a stereoscopic image generation method according to the present invention loads a left image and a right image for generating a stereoscopic image on a flash basis (S110). Subsequently, as shown in FIG. 2, a line unit mask is formed on the left image by alternately arranging the masks one row at a time in a row corresponding to the pixel row unit of the left image (S120). As shown in FIG. 3, , A line unit mask is formed on the right image by alternately arranging the masks one row at a time, corresponding to the pixel row units of the right image (S130).

At this time, if the left image mask is covered so as to correspond to the odd-numbered row units of the left image pixel, the right image mask is covered to correspond to the even-numbered row units of the right image pixel. On the contrary, if the left image mask is set to correspond to the even-numbered row units of the left image pixel, the right image mask is set to correspond to the odd-numbered row units of the right image pixel. Accordingly, as shown in FIG. 4, the left image mask and the right image mask are alternately arranged on the row of the image pixels so that the left image and the right image are not overlapped with each other.

Next, the parallax, which is the difference between the left image or the right image formed by the line unit mask, is adjusted to variously adjust the perspective and the solid of the displayed image (S140). At this time, the left image and the right image have the same size, and the position of the line 0 of the left image matches the position of the line 0 of the right projection, and the position of the line n of the left image and the line n of the right image are In the case of adjusting to match, the displayed image does not have perspective as shown in Fig.

Alternatively, as shown in FIG. 6, when the parallax is adjusted so that the right image is located on the right side of the left image, the displayed image has a perspective view in which the image is viewed behind the screen. As shown in FIG. 7, When the parallax is adjusted so as to be positioned on the right side of the right image, the displayed image has a perspective view that protrudes forward from the screen.

8, when the parallax is adjusted such that both ends of the right image are located behind both ends of the left image, the left side of the displayed image protrudes forward from the screen, and the right side of the image is moved backward 9, when the parallax is adjusted so that both ends of the left image are positioned behind both ends of the right image, the right side of the displayed image is seen to be forward, and the left side is seen to be backward I have perspective.

10, when the parallax is adjusted so that the right end of the right image is located behind the right end of the left image, only the right side of the displayed image has a perspective view that protrudes forward from the screen. In the case of adjusting the parallax so that the left end of the right image is positioned behind the left end of the left image as shown in the drawing, only the left side of the displayed image has a perspective that looks backward beyond the screen.

12, when the parallax is adjusted so that the left end of the left image is located behind the left end of the right image, only the left side of the displayed image has a perspective view that protrudes forward from the screen. As shown in the figure, when the parallax is adjusted so that the right edge of the right image is located behind the right edge of the left image, only the right edge of the displayed image has a perspective view that looks backward beyond the screen.

14, when the parallax is adjusted so that the upper end of the left image is tilted to the left of the right image and the lower end of the left image is tilted to the right than the right image, the top of the displayed image is seen to go backward 5, when the parallax is adjusted so that only the upper end of the left image is tilted to the left than the right image, only the upper end of the displayed image is moved toward the rear side, .

As shown in FIG. 16, when adjusting the parallax so that only the lower end of the left image tilts to the right than the right image, only the lower end of the displayed image is projected toward the front side. When the parallax is adjusted such that the top of the image is inclined to the right of the right image and the bottom of the left image is tilted to the left of the right image, the top of the displayed image protrudes toward the front of the screen, I have a perspective that looks inward.

As shown in FIG. 18, when the parallax is adjusted so that only the lower end of the left image is tilted to the right than the right image, only the upper end of the displayed image has a perspective view that protrudes forward from the screen. Likewise, if only the lower end of the left image is adjusted to be tilted to the left side than the right image, only the lower end of the displayed image has a perspective view that looks backward beyond the screen.

Then, the left image and the right image formed by the line unit mask are alternately displayed on the pixel line to generate a flash file to form a stereoscopic image (S150). At this time, the flash file is created as a shockwave file having an extension of * .swf.

As described above, the stereoscopic image generation method according to the present invention can easily generate a stereoscopic image having a variety of perspective and stereoscopic effect by merely adjusting the parallax, which is the difference in image interval between the left image and the right image, , A polarizing type 3D monitor and polarizing glasses can be used to view and control a stereoscopic screen in a general Internet window without a separate 3D video player or 3D mode conversion.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. It will be obvious to those of ordinary skill in the art.

Claims (17)

A method for generating a flash based stereoscopic image,
Loading a left image and a right image for generating a stereoscopic image;
Forming a line unit mask on the left image by alternately arranging the masks one row at a time in a line corresponding to the pixel row unit of the left image;
Forming a line unit mask on the right image by alternately arranging the masks one row at a time in a row corresponding to the pixel row unit of the right image;
Adjusting the parallax of the left image or the right image formed with the line unit mask to adjust the perspective of the displayed image;
Generating a flash file in which the left image and the right image formed with the line unit mask are alternately displayed on a pixel line to form a stereoscopic frame;
/ RTI >
In the step of adjusting the perspective of the displayed image,
Wherein if the displayed image is to be viewed behind the screen, the parallax is adjusted such that the right image is positioned to the right of the left image.
The method according to claim 1,
In the step of forming a line unit mask on the left image,
When a mask is applied so as to correspond to an odd-numbered row unit of the left image pixel,
Wherein a line unit mask is formed on the right image by covering a mask to correspond to an even-numbered row unit of the right image pixel.
The method according to claim 1,
In the step of forming a line unit mask on the left image,
When a mask is applied to correspond to an even-numbered row unit of the left image pixel,
Wherein a line unit mask is formed on the right image by covering a mask corresponding to an odd row unit of the right image pixel.
delete The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the displayed image is to be projected forward, the parallax is adjusted such that the left image is located on the right side of the right image.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the left side of the displayed image is viewed from the front and the right side is viewed from the rear side, the parallax is adjusted such that both ends of the right image are located behind both ends of the left image. Way.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the right side of the displayed image is viewed from the front side and the left side is viewed from the rear side, the parallax is adjusted such that both ends of the left side image are located behind both ends of the right side image, Way.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein the parallax is adjusted so that the right side of the right image is located behind the right side of the left image when the right side of the displayed image is to be viewed forward.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein the parallax is adjusted so that the left end of the right image is positioned behind the left end of the left image when the left side of the displayed image is to be viewed backward.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein the parallax is adjusted such that the left edge of the left image is positioned behind the left edge of the right image when the left side of the displayed image is to be viewed forward.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein the parallax adjustment unit adjusts the parallax so that the right edge of the right image is located behind the right edge of the left image when the right side of the displayed image is to be viewed backward.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
The upper end of the left image is inclined to the left side of the right image and the lower end of the left image is inclined to the right side than the right image, Wherein the step of generating the flash based stereoscopic image comprises:
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the upper end of the displayed image is to be viewed backward, the parallax is adjusted such that only the upper end of the left image is tilted to the left side of the right image.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the lower end of the displayed image is to be projected forward, the parallax is adjusted such that only the lower end of the left image is tilted to the right than the right image.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
The top of the left image is tilted to the right of the right image and the bottom of the left image is tilted to the left of the image of the right when the top of the displayed image is seen to protrude forward, And the parallax is adjusted.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the upper end of the displayed image is to be projected forward, the parallax is adjusted such that only the lower end of the left image is tilted to the right than the right image.
The method according to claim 1,
In the step of adjusting the perspective of the displayed image,
Wherein when the lower end of the displayed image is to be viewed backward, the parallax is adjusted such that only the lower end of the left image is tilted to the left than the right image.

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