KR20190068059A - Methods of making auto-stereo images with reduced 3D dead zones - Google Patents

Abstract

In an autostereoscopic (glasses-free) three-dimensional (3D) image and a 3D image (contents) of a 3D monitor using a lenticular lens or a parallax barrier, a combination of images at different angles focused on each of left and right eyes, that is a 3D set, is limited due to a limited image source. In addition, a left-right reversal 3D phenomenon, by which images seem overlapped between an ending point and a restart point of the 3D set, occurs, and due to the left-right reversal 3D phenomenon, a 3D dead zone that is an area invisible in a 3D manner is generated. The generation of the 3D dead zone is an inevitable result of a conventional interlacing method. Therefore, the present invention relates to a new interlacing method which solves a problem of the conventional interlacing method of inducing the 3D dead zone due to left-right reversal so as to minimize fatigue of eyes, thereby realizing a comfortable 3D image.

Description

[TECHNICAL FIELD] The present invention relates to a method of making a stereoscopic image by minimizing a stereoscopic defect zone,

The technical field of the present invention relates to a method of manufacturing an auto-stereoscopic stereoscopic image using a lenticular lens and a parallax barrier, and a method of producing stereoscopic image contents for a stereoscopic monitor made of the material to be.

There are a lot of prior arts and related documents related to the production of stereoscopic images of a non-eyewear system manufactured using a lenticular lens or a parallax plate and stereoscopic contents for a non-eyewear system stereoscopic monitor made of the material. Most importantly, interlacing is performed in the process of producing a non-eyeglass stereoscopic image and a stereoscopic monitor image. This is accomplished by dividing an image source of a multi-camera angle into units of pixels, And then aligning the pitches to optically match the lenticular lens or the parallax plate to form a single image. This interlacing method is a technique directly related to the present invention.

U.S. Patent No. 7,457,038 B2

Parallax barrier from Wikipedia (URL: https://en.wikipedia.org/wiki/Parallax_barrier)

The non-eyeglass stereoscopic image is obtained by dividing the image sources of various angles into units of pixels and arranging them in a regular permutation on the back surface of the lenticular lens and the diagonal plate so that the observer (viewer) Since the number of image sources is limited, the number of stereo sets, which is a combination of images seen in the left and right eyes, can not but be limited. As a result, there is a phenomenon that a left-right reversal phenomenon occurs between a point at which the stereoscopic set ends and a point at which the stereoscopic set ends, and when the observer reaches the point, an image of the opposite angle reversed from left to right is generated. This is called a reversed stereo or a pseudo-scopic stereo. In addition to this, it is not possible to realize a normal stereoscopic image, and a stereoscopic image of an area (3D dead zone. The non-eyeglass stereoscopic image generated by the conventional stereoscopic stereoscopic image has become a serious obstacle to activation of the stereoscopic image due to such a problem. Accordingly, there is a need for a method of generating stereoscopic images for stereoscopic images and stereoscopic monitors for eliminating or minimizing the 3D dead zones, and the present invention has been made to solve the problems of the conventional interlacing, And a stereoscopic image for a stereoscopic monitor is generated.

As described above, in order to minimize the stereoscopic blind spot caused by the left-right reversal phenomenon occurring between the end point of the stereoscopic set and the resume point, a different type of inter-racing is required. For this purpose, Therefore, it is necessary to change the permutation of the image data suited thereto. Therefore, it is possible to solve these problems by eliminating or minimizing the stereoscopic blind spot by interlacing method appropriate to the composition of each source image.

The stereoscopic image and the stereoscopic image using stereoscopic image using the interlacing method of the present invention are applied to the fields of stereoscopic advertisement, advertisement, stereoscopic sign, and interior that are unspecified in many places in public places due to the stereoscopic blindness caused by the problem of the left- It was difficult to enter. However, it is possible to solve the cause of the entry barriers through the present invention, so that the effect of the present invention can be considered to be very significant since publicity, advertisement, signboard, and interior using the stereoscopic image and stereoscopic image without spectacles can be performed.

FIG. 1 illustrates an existing interlace method. Illustratively, when using an image source having eight camera angles, the left and right eyes of the image source are selected through lens lines or lenticules according to the permutation of the image source and the position of the observer. Fig. 8 is a view for explaining how the image shown in Fig.
2 is a diagram for explaining a parallax of an image source used for interlacing.
FIG. 3 is a diagram for explaining the three-dimensional relationship of the parallax of the image components on the stereoscopic image.
FIG. 4 is a diagram illustrating a modified sequential interlacing method according to the present invention. As shown in FIG. 1, an image source having eight camera angles is used.
FIG. 5 is a view for explaining a phenomenon in which a stereoscopic image using an existing interlace method is actually shown, as in the example of FIG.
FIG. 6 illustrates the stereoscopic effect obtained by interlacing of the first new permutation described in FIG.
7 illustrates a second novel interlacing method of the present invention that can be selectively applied according to the image composition of the source image.
8 is a three-dimensional view of a phenomenon actually appearing as a three-dimensional object when the interlacing described in FIG. 7 is applied.
9 is for explaining different compositions of the source image and the characteristics thereof.
FIG. 10 is a view for comparing the magnitudes of the left and right inverse time differences according to the conventional method and the second method of the present invention shown in FIG.

A fundamental object of the present invention is to eliminate the fundamental cause of a stereoscopic oblique zone, which is a problem that stereoscopic images for a stereoscopic monitor made of the above-mentioned materials and stereoscopic images produced by a lenticular lens and a parallax plate are used There is a need for a new way of interlacing. Therefore, the problems of the conventional method will be described first, and the means of implementing the present invention will be described. 1 is an example of an 8-view method using images of eight different camera angles, in which the leftmost image, the leftmost image, is used as the image # 1, When images are sequentially numbered with images # 2, # 3, # 4, # 5, # 6, # 7 and # 8, image # 8 is the rightmost image do. In this case, the image data of each lens line or lens that constitute the lenticular lens, that is, lens lines # 1, # 2, # 3, etc., It is divided into 8 pixels from each other and sequentially called and mixed. The first pixel in image # 1 and the second pixel in image # 2 are arranged in order of 8 pixels in the first lens line. After all, the image that enters the lens line # 2 at the next step will be interlaced in the form of the 9th pixel of image # 1, the 10th image of image # 2, and the 11th image of image # 3. Accordingly, when the observer is at the position of '9' as shown in the example of FIG. 1, pixels 1 and 1-1 come in as viewing lines 1 and 2 shown on the observer's left eye, and pixels 3 and 4 appear on the right eye, Image data of the left camera angle is input to the left eye and image data of the camera angle which is gradually shifted to the right is input to the right eye, so that a stereo set that provides normal stereoscopic data So there is no problem in implementing stereoscopic images. However, when the observer moves to reach the position of '10', the data of the rightmost image such as 8, 8-1 are displayed on the left eye as shown in 5 and 6, Since there is no image data, that is, the image # 9, the leftmost image data such as the leftmost image data such as 7 and 8 are entered in the right eye and the left and right images are changed A reversed stereo phenomenon occurs, resulting in an area in which the image is overlapped to become dizzy and unrealized, which is called 3D dead zones. What is important here is the problem caused by the reversal phenomenon, which is superimposed on the stereoscopic image. The reason why stereoscopic images can not be realized properly is that the image of the opposite angle of the left and right eyes forms inversely on each eye. This is because the parallax between the image # 8 and the leftmost image, that is, the image # 1, is so large that the human brain can not normally fuse. This is because the parallax of a stereoscopic image using an image source of a plurality of angles is more than three times the parallax of a binocular stereoscopic image. In the case of a binocular stereoscopic image, The stereoscopic image of the non-eyeglass system requires a large number of stereoscopic sets corresponding to the various positions of the observer, and therefore, the stereoscopic image stereoscopic image has only to have a large parallax . 1, 4, and 7, the image data hidden under the lens according to the position of the observer is abbreviated in order to explain the basic principle of the change of the data displayed on the left and right eyes when the position of the observer changes, 1, for example, when the observer is at the position of '9', the image data entering the left eye is denoted as 1, 1-1, but actually 1, 1-1, 1-2, 1-3. The right eye will see not only the data of 2, 2-1 but also 2, 2-1, 2-4. You will see all of the data for that angle on the right as. Of course, this is only possible if the observer is located at the 'optimal stereo viewing distance' that corresponds to the pitch value and the observer is not moving horizontally to the left or right, In the case of deviation from the appropriate stereoscopic viewing distance, 1,2-1, 3-2, etc. are entered in the left eye instead of simply 1, 1-1, 1-3, etc., and 2, 2-1, A stereoscopic set is generated in the form of a combination of images such as 2, 3-1, 4-2 and so forth. Therefore, when the distance from the red stellar gaze is out of the range, it is a principle that the data of the angles of the images are grouped together instead of only the data separated from the image of one angle. In order to understand the present invention, it is necessary to understand the composition of the image source and the parallax of each object constituting the image. Basically, a stereoscopic image is realized by parallax. In a case where a square, which is an object in 'a' in FIG. 2, is 21 in the image # 1, the position in the image # 8 is 23 The distance between the original position and the changed position is 25, which is called parallax. In this case, the parallax occurring when the position of the object moves to the left side as the camera angle of the image gradually moves to the right side in the original position is called negative parallax. In this case, So that it is protruded with respect to the screen. Assuming that the original position of the circle, which is the object, is 22 as shown in the figure 'b', the position in the image at the right angle moves to the right side, which is the same direction as the camera 24, It is called positive parallax, and the circle of the object is seen in a stereoscopic image based on the screen. Of course, unlike a and b, an object with no parallax between the left and right eyes is visible on the surface of the screen and is called zero parallax. If the positive parallax 35 of the triangle c-1 is larger than the parallax 32 between the circles of b-1 as in the example of FIG. 3, the triangle becomes more visible into the screen than the circle when viewed as a stereoscopic image Although not shown in this figure, if an arbitrary object has a greater negative parallax than a quadratic difference 31 of a-1, then the object is seen to be projected more than the rectangle of the figure when viewed as a stereoscopic image to be. Based on the above description, the problem of the conventional interlacing is described in more detail. Assuming that the image source used in the example of FIG. 1 is composed of objects having a time difference as illustrated in FIG. 3 When the position of the observer in FIG. 1 is at '9', the rectangular object 58 protrudes outward with respect to the surface 56 of the screen in the direction 57 viewed by the observer as in the case of 'f' And the circle (59) enters into the triangle (60), and a normal stereoscopic image is realized in a form in which the triangle (60) is viewed inwardly. This normal stereoscopic realization is performed when the data of the image # 7 on the left eye of the observer and the image # 8 on the right eye And when the position of the observer reaches '10', a left-right reversal phenomenon occurs. When the observer moves to the innermost position in the viewing direction (61) as shown in 'g' A quasi phenomenon occurs in which the triangle 64 to be seen most protrudes with respect to the surface 56 of the screen and then the circle 63 protrudes while the quadrangle 62 to be protruded into the inside . For example, if the triangles 60 and 64 of 'f' and 'g' in FIG. 5 are distant mountains with a circular arc and the circles 59 and 63 are buildings closer to the observer, In case of 'f', the normal three-dimensional structure will be implemented without any problem, but in case of 'g', the farthest mountain protrudes forward, and the building with the root is behind the mountain and the person with the closest root penetrates the building and the mountain. A stereoscopic composition is created which is totally opposite to the reality which is seen to be deeper into the image, and the data of this type of stereoscopic image is input to the human brain, resulting in a result of requiring synthesis. In this case, the parallax of the left and right reversal is so large that not only the synthesis of the parallax images in the human brain can be achieved, but also the stereoscopic composition that is contrary to the human experience is seen, so that the resulting phenomenon is merely superimposed and feels dizzy will be. In addition, the composition of the object, which is an element constituting the image of the stereoscopic image, and the positional relationship between the objects are also important. When the rectangle 76 and the circle 77 are separated from each other like 'k' And the two objects 78 and 79 are interlocked with each other like 'l'. In the human brain, the rectangle 78 is circled 79 as in the case of 'l' And that the rectangle is ahead of the circle based on the occlusion covering the left part of the circle. However, in the case of the composition of k, there is no basis for making such a judgment, so it is judged which one is behind and behind only by the disparity of visually provided objects. In the case of using an image source of eight angles as in the example of the upper part of FIG. 4, a conventional interlacing method of interlacing according to the present invention will be described with reference to FIGS. In the order of the lens lines # 1, # 2, # 3 ..., etc., the interlacing of the present invention starts from the image # 1 in the arrangement of the image source and reaches the image # 1, 2, 3, 4 and 5 are arranged below lens line # 1, and 4, 3 and 2 are arranged in reverse order by arranging images in reverse order. 1, 4-1, 5-1, and 4-1, 3-1, 2-1 in reverse order. Unlike the conventional method, the remaining images # 6 to # 8 are not used. If the permutation of the image data is changed as described above, a normal stereoscopic set is formed at the position 19 of the observer in FIG. 4, and a stereoscopic set is sequentially generated when the observer moves horizontally. In the process of moving, 2, 2-1, 2-3 are entered into the left eye, 3, 3-1, 3-2 are entered into the right eye, and 3, 3-1, 3 -2 in the left eye, and a solid set of 4, 4-1, 4-2, etc. in the right eye. However, when the observer reaches the position of '20', 5, 5-1, and 5-2 are entered in the left eye as 15 and 16 marks, and 4 and 4-1 , 4-2, and so on. However, the parallax of the left and right reversal phenomenon occurring at the position (10) of the observer in FIG. 1, that is, the parallaxes of the image data # 1 and # 8 is very large, On the other hand, since the parallax of the left-right reversal according to the present invention is not so large, the three-dimensional set is normally synthesized in the brain. As a result, you will see an inverted image of left and right, but you will see it in three dimensions. Therefore, by using this principle, it is impossible to recognize which one of the objects is in front of and behind each other as 'k' in FIG. 9, and objects such as a-1 and b-1 in FIG. 4, the observer's position 19, which is the position of the observer in FIG. 4, shows a rectangular shape protruding from the surface of the screen by the original parallax, After reaching '20', the stereoscopic effect is reversed. If the objects a-1 and b-1 are assumed to be water dams and fish in the above example, there is no problem because there is no basis for recognizing the depth of the two objects even if the water droplets are brought forward to the fish or vice versa Since stereoscopic images are implemented and do not cause overlapping problems, comfortable stereoscopic images without fatigue of eyes can be realized. The stereoscopic image of the composition, which is expressed only by the distance between the objects without the background, has no effect on the realization of the stereoscopic effect, and a comfortable stereoscopic image having no stereoscopic blind spot can be realized. However, if there is a background in the image source and the background and the object overlap each other, a problem arises. If c-1 in the drawing 3 is the underwater background, both the water drop and the fish overlap with the background Assuming that water droplets and fish have different cubicities, we can not tell the difference between them. On the other hand, in the case of c-1 under the sea, both water droplets and fish are overlapped with the background, do. Therefore, unlike the objects a-1 and b-1 for the background c-1, the permutation of the existing method must be maintained. More specifically, when preparing an image source, we need to separate the background and objects and perform stereoscopic conversion. In general, stereo conversion is performed by a program based on a depth map or a program of a horizontal movement method of a layer, which means that the stereoscopic conversion operation is carried out separately by separating the object and the background, The objects of a-1 and b-1 make a monochromatic color that does not mix with the colors of these objects as a temporary background, and after a stereoscopic conversion, a chromatic key effect that removes the background color is used to create a transparent background And the background c-1 is separately transformed to synthesize the backgrounds with the objects. At this time, if an editing program such as Adobe After-Effect or Premiere is used, can do. The images of the objects (images # 1 to # 4) can be copied from the time line to cause the copied source to be reversed in duration and the background can be used as the original permutation from images # 1 to # 8 will be. In other words, suppose that the images are 8-view images. The images of objects are transformed from # 1 to # 4, copied from the timeline, and inverted to obtain # 4 to # 1. 4 to # 1, and the image of c-1 in the background is generated from # 1 to # 8 through stereoscopic transformation and synthesized with the objects as they are in the original permutation. In this way, objects and backgrounds have different permutations, objects are ordered by permutation according to the present invention, and backgrounds are arranged by permutation of existing methods. 4 and # 1 unlike the example of FIG. 4 because the permutation is slightly different from the permutation described in FIG. 4 so that the permutation is the same as the images # 1, # 2, # 3, # 4, # 4, # 3, # 2, This sequence is followed by overlapping arrangement, but there is no big difference in three dimensions. This is because, as described above, when the distance from the proper stereoscopic viewing distance is not seen, the optical principle of the lens sees a bundle of separated pixels of images at various angles, The image of the end of the image permutation and the image of the start may be used in duplicate. The viewing angle of the lenticular lens and the parallax plate used for the stereoscopic image is less than 15 ° to 30 ° and there is a slight difference for each material. Even if using the same parallax image source, the size of the stereoscopic effect , The narrower the viewing angle, the larger the stereoscopic effect. The larger the viewing angle, the less the stereoscopic effect. Therefore, the appropriate number of images according to the viewing angle of the lens in the range of 50% to 70% of the number of image sources used in the conventional interlace You can use it. 1, in contrast to the objects a-1 and b-1 in the case of the background described above, there is no left-right reversal at the observer's position 20 in Fig. 4, A left-right reversal occurs in the display unit 10. Thus, there is a difference in the timing of the left and right reversal of the objects and the background. Since the background c-1 overlaps with the objects a-1, b-1 because it is the background as assumed above, the image of the background is clearly visible by giving a "blurring effect" before compositing with the objects So that the dead-zone is minimized during the left-right reversal. However, since the stereoscopic image according to the present invention is continuously realized without the three-dimensional dead zone, the objects a-1 and b-1 are continuously imaged If the background is blurred, it will hardly recognize the left-right reversal phenomenon occurring in the background. By applying the effect of blurring the focus on the background image, it is possible to recognize the depth perception of the background as a whole by eliminating the boundary line that can recognize the parallax between the sets of the background images, The problem of reversal can hardly be recognized. In order to describe the effect of the present invention as described above, a quadrangle 66 protrudes from the surface 75 of the screen as indicated by 'h' in FIG. 6 at a position 19 of the observer in FIG. And the background triangle (68) becomes visible more. After the position '20' of the observer shown in FIG. 4, a left-right reversal occurs as shown by 'j' in FIG. 6 to cause the circle 73 to protrude, the rectangle 72 to appear inward, Becomes visible in the dullest state. In FIG. 4, when the position of the observer reaches between '20' and '19', the objects a-1 and b-1 stay on the surface 75 of the screen for a while The interval is so short that it is only recognized as a process in which objects a-1 and b-1 come and go opposite each other. Unlike the design in which the composition of the image source is arbitrarily determined and the constituent elements are not overlapped as described above, in the case of using a design whose components have to be overlapped by a request of a consumer as an image source, There is still a problem in that the blurring effect on the three-dimensional blind spot can not be eliminated. In this case, therefore, another type of permutation must be used, which is another form of the present invention. As shown in the example of FIG. 7, after arranging half the images of the number of image sources used in the conventional method, they are repeatedly arranged in order of the center of the images used. More specifically, this means that the images # 1 to # 5 are arranged in the order as shown in FIG. 7, and then the intermediate rotation between # 1 and # 5, that is, the image # 3 is repeatedly arranged. By doing so, it is intended to solve the problem of dizziness caused by a too large parallax of the left-right reversal occurring at the position of the observer '10' in FIG. 1, and as an example of FIG. 10, the white square 46 of 'd' Assuming that the parallax occurring when assuming that the position of the object of # 1 and the black rectangle 48 is the position of the object of the image # 8 is equal to 48 and that this is a parallax value of the left and right inversions occurring in the conventional method, For example, suppose that the white rectangle 49 is the object of image # 1 and the black rectangle 50 is the object of image # 5. The parallax of the object is reduced to about 1/2 of '48' as in '51' because the total parallax is reduced by only half of the conventional image sources . In other words, the time difference 48 is the interval between the images # 1 and # 8, but the time difference 51 is the interval between the images # 1 and # 5. The white rectangle 54 shown at the lower end of the line e in FIG. 10 shows an intermediate sequence image # 3. The white rectangle 54 indicates the parallax 53 between the parallax 52 and the left upper edge 49 The left and right reversal does not occur at once such as 48 and the stereoscopic image is displayed between the images # 1 to # 5. However, when the time difference is shifted from the image # 5 to the intermediate image # 3, The left and right inversions are generated first, the image of the plane formed by the image # 3 continues in the next step, and when the image reaches the image # 1, the timing is divided into a form in which the second left / right inversion is caused by the time difference '52' The time difference is sharply reduced to '52' and '53' instead of '51'. 8, the quadrangle 66-1 is protruded from the surface 75-1 of the screen as 'h-1' in the stereoscopic set of the sections # 1 to # 5 A normal stereoscopic image in which the circle 67-1 enters into the triangle 68-1 and a triangle 681 enters into the inside of the stereoscopic image is realized and in the section of the stereoscopic set including only the image # 3, the time difference of the sets is '0' 1 ', everything looks like a flat image. However, in a stereoscopic set in which images # 5 and # 3 and image # 3 and image # 1 are formed in a stereoscopic set, even if a left / right reversal occurs like 'j-1', the stereoscopic image is weakly formed near the surface 75-1 of the screen. Therefore, although overlapping due to the left-right reversal is somewhat small, the recognition of the three-dimensional dead zone is extremely reduced as the degree thereof becomes very weak. As a matter of course, the number of image sources is determined in a range of 50 to 70% of the number of images used according to the angle of view of the lens, as in the first method. In addition, the additional gain obtained through the above-described two new interlacing methods is problematic in that stereoscopic images using a lenticular lens or stereoscopic images using a stereoscopic monitor are refracted in a side view, In the first aspect of the present invention, the three-dimensional image is slightly reduced in the overall image but looks clean. The second-type three-dimensional image is seen as a flat image from the side, but is clearly and clearly visible. In addition, Since the stereoscopic image is properly displayed, the problem of the side view angle can be solved at the same time. As a result, the new interlacing method of the present invention uses 50-70% of images according to the angle of view of the lens based on the image source used in the conventional method, and the images do not overlap each other even after three- In the case of arranging the images to be used in the order of the first original sequence and thereafter arranging the images in the reverse order from the middle sequence of the total number of the images and in the case where the objects and the background overlap each other, And then repeatedly arranging the intermediate sequential images of the images that are used afterwards. This means that selection according to the composition of the image source is sufficient to achieve the object of the invention. On the other hand, in the case of a stereoscopic monitor, since the boundaries of the sub-pixels (R, G, B) are clear and the images are clearly reproduced through the sub-pixels, (8) or 9 (9) views using the image source of the angle of view, the number of images of the image source is very small. In contrast, the stereoscopic image has the output resolution and the LPI Inch, more than 200 video sources are required. Of course, if the number of images is increased under the condition that the parallax between the leftmost image and the rightmost image of the image source is the same, the parallax between the respective images is relatively reduced, and a larger number of images can be used . In the case of stereoscopic images by the output, since the printer reproduces the image form and color by scattering dots of CMYK, it is necessary to reduce the parallax between the respective images so that stereoscopic quality is secured. Therefore, it is necessary to perform interlacing. However, the number of images required for each of the stereoscopic image and the stereoscopic monitor image is different, but it may be applied in the same ratio as the above-described image permutation. Finally, in describing the present invention, the sequence of the image source is numbered in the order of images of camera angles that are gradually moved to the right with respect to the left camera angle. Some interlacing programs number the images in reverse order In some programs, the permutation of the permutation is reversed, but the result is only the apparent permutation. The sequence in the actual interlacing is the same as that of the description of the present invention, so it does not need to be confused.

 In order to implement the present invention, there is no need to separately create a physical material, and therefore, no investment is required. If the present invention is applied using an existing interlacing program, the permutation of the image source may be changed The effect of blurring the background may be applied. Therefore, the practice of the present invention is practically realistic, and the stereoscopic image through the present invention eliminates the problems of the conventional method and can contribute to commercialization. Therefore, the industrial applicability of the present invention is very large.

Parallax barrier: Also referred to as a barrier-screen, the left and right parallaxes are separated by arranging alternating black strips and clear apertures, Which is the main material of the stereoscopic image.
Lines Per Inch: This is a unit of how many lenticular lenses are spaced one inch apart in a lenticular lens. The higher the athlete is, the lower the stereoscopic effect. The lower the athlete, the thicker the lens becomes, You can also see stereoscopic images.
Positive parallax: As the principle of stereoscopic images, the parallax interferences of objects that are viewed inward from the surface of the image, the image corresponding to the left eye is located on the left and the object on the right is located on the right. When viewed, both eyes will see the left and right eyes parallel to each other.
Negative parallax: Opposite to the positive parallax, the parallax applied to objects that project out from the image surface causes the left and right eyes to be seen diagonally, with two lines protruding from the intersection point . Therefore, the images corresponding to the left and right eyes on the stereoscopic interlaced image are positioned opposite each other.
Auto-stereoscopic image: In the sense that the image source is used at multiple angles, multi-view stereoscopic image or auto-stereoscopic image can be used in real- -stereo), and it is the cheapest and most common to make using a lenticular lens or a parallax plate.
Interlacing: In order to realize a stereoscopic image, it refers to a process of separating the binocular or multi-view image sources into pixels and mixing them in a certain sequence, which is generally executed by using a program, In the case of an image, it may be executed in a graphic editing program such as Photoshop.
Pitch: It is also used with LPI, which tells how many lenticular lenses are spaced one inch apart. It is called pitch value when discussing a value that optically agrees with the interval between the physical lens and the interlaced image based on a certain distance.
Stereo set: This is a combination of different images that are formed on left and right eyes in stereoscopic image. Although there is only one stereoscopic set in glasses system, in non-stereoscopic system, And a stereoscopic set corresponding to the change of the position of the observer is displayed so that the stereoscopic body can be continuously realized.
Optimal stereo viewing distance: The distance that determines the pitch in stereoscopic images without glasses. The image created by this pitch value is best stereoscopic at the distance determined by the pitch. As you go back and forth, you get a combination of images from different angles and you will build a stereoscopic set.
Stereoscopic Viewing Angle: A stereoscopic view angle is a stereoscopic view angle when a lenticular lens and a parallax plate are made. This stereoscopic viewing angle is used only for a stereoscopic body of less than 30 degrees. Lens. According to the stereoscopic viewing angle, the freedom of stereo viewing is determined so that the observer can move while viewing a normal stereoscopic image.
3D dead zone: A region that deviates from the stereoscopic viewing angle, that is, a region where a left-right reversal occurs. The segment exists between the stereoscopic viewing angle and another stereoscopic viewing angle. The larger the stereoscopic viewing angle, The blind spot is also increased at the same rate.
Reversed stereo: When a stereoscopic set is made, an image of the opposite angle to the left and right eyes is formed. As a result, the stereoscopic composition is opposite to the intended one. The left and right images can not be synthesized It causes dizziness and eye-sickness. In the end, the left-right reversal causes a blind spot of the stereoscopic image.

Claims (2)

The method comprising the steps of: firstly arranging, for each predetermined lens line, a plurality of image sources of the multi-view image sources of the image in which the background image and the object image do not overlap in one image; And
And arranging a part of the image sources arranged in a specific region of the preset lens line in a reverse order. A first step of arranging some image sources of the multi-view image sources of an image in which a background image and an object image overlap in one image to be permutated for every preset lens lines;
A second step of arranging the polygonal image sources corresponding to the background image in the extreme right order on the far right so as to be permuted for each of the preset lens lines;
A third step of first arranging the partial image source corresponding to the object image for each predetermined lens line and arranging some image sources arranged in a specific one of the preset lens lines in reverse order;
A fourth step of matching an image source of the background image arranged in the second step and an image source of the object image arranged in the third step; And
And a fifth step of arranging an image source matched in the fourth step for each of the preset lens lines and arranging an intermediate image source of the matched image sources in a specific area. Method of Making Stereoscopic Image.

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