RU2472193C1 - Method of producing stereo images and device for realising said method - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method involves line by line synchronous projection of prepared plane images of an object using two projectors located at a known base, optical axes of which are directed towards a coinciding point on a screen, by model construction of projective pyramids passing through projection points and boundary points of the prepared plane images of the object to its image on the screen, paired triangular planes, which are connected to the projection points, of which are similar. Optical axes of the projectors are set in one direction and enable to obtain equal volumes of the projective pyramids which rest on the stereo image of the object on the screen. The device consists of two optical projectors spaced apart on a known base, which provide simultaneous line by line projection of plane images of the object from arrays with records of its prepared plane images, an information reading synchroniser with line and frame sweep generators, which is connected to arrays, the output of which is connected to the optical projectors through a signal analyser.

EFFECT: simple method of producing stereoscopic images and high consumer quality of stereoscopic displays by eliminating the effect of spatial factors on the position of the observer.

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Description

The invention relates to the field of constructing optical and television stereoscopic displays that can be used to create stereoscopic displays.

The essence of stereoscopy is to obtain images of objects similar to what we see. It is generally accepted that the stereoscopic effect is a binocular property of the observer’s visual apparatus, which is described on the basis of the means used for its technical implementation [1]. The stereoscopic effect is manifested when observing an object from two points in space, when each eye (camera) "observes" a separate planar image, and the angle at which the corresponding rays intersect does not exceed 16 ° [1]. Such a description of the stereoscopic effect is associated with the separation of the observation process into two parts: obtaining information about the object in the form of two planar mappings from two points in space and their inverse transformation into a spatial mapping. The indicated mappings at each stage must have the similarity property.

The information about the object is converted to planar displays using the central design method (which is the basis of projective geometry [2]) when using two devices based on it. The plane display of the object is located in the Euclidean plane - the measurement plane, orthogonal to the direction of the object in which the plane display is obtained on the basis of a model plotting the path of the rays in the projection plane (in the terminology of projective geometry), the movement of the rays in which is not observed. Then, the resulting mappings are “rotated”, if necessary, located in one plane. Their inverse transformation is performed by line-by-line synchronous design of plane displays on one screen.

The main part in the model description of the process of transforming a spatial object into planar displays and from planar displays to stereo imaging is played by the first part of the actions. The process of converting two planar mappings into a stereo image is model mirrored to the process of transforming a spatial object into planar mappings. Therefore, the first process will have to be considered to justify the actions in the second.

A known method for obtaining stereoscopic images of an object, selected as a prototype, including line-by-line synchronous design of prepared planar images of an object by two projectors located on a known base, the optical axes of which are directed to a coincident point on the screen, by model construction of projective pyramids passing through the design points and boundary points of prepared planar mappings of an object to its display on the screen, the paired triangular planes of which are connected data with design points are similar.

The methodological approach used determined the way to create stereoscopic displays on displays that are formed by separate displays for each eye, dividing them by spectrum or polarization. To view the displays use glasses with special filters (filters, polarizing, shutter filters) or other accessories, such as thin lenses on the front of the display. This significantly reduces the consumer qualities of stereoscopic displays due to the limited viewing angle: narrow viewing angle, safe viewing zone and others [3].

Also known is a stereoscopic device selected as a prototype, consisting of two optical projectors spaced on a known base, the optical axes of which are directed to a coincident point on the screen, providing simultaneous line-by-line design of plane displays of an object from matrices with records of its prepared plane displays, an information read synchronizer with line and frame scan generators, which is connected to the matrices, and the signals from them are fed to optical projectors.

However, the stereoscopic effect of objects is preserved for a person when observed with one eye, and in addition, artists in one picture achieve the effect of perspective or “movement” of the elements of the picture behind the movement of the observer. This indicates that the perspective of the displays is associated with both the stereoscopic effect and the inaccuracy of the model used to describe the stereoscopic effect.

The stereoscopic process is purely physical, in which information is transmitted by the central design method in the projective coordinate system, displayed on its Euclidean plane [2] - the measurement plane. Information processing must be performed by the same method of central design, only in this case they are adequately transformed, which has an equivalent direct and inverse solution. The practical implementation of the central design method is the physical and geometric basis of the proposed method for obtaining stereoscopic images.

The aim of the invention is to simplify the method of obtaining stereoscopic displays and improve consumer qualities of stereoscopic displays by eliminating the influence of spatial factors in the position of the observer.

This goal is achieved by the fact that in the known method of obtaining a stereo image of an object, which includes line-by-line synchronous design of prepared planar images of an object by two projectors located on a known base, the optical axes of which are directed to a coincident point on the screen, by model building projective pyramids passing through the design points and boundary points of prepared planar mappings of an object to its display on the screen, the paired triangular planes of which are connected with dots design similar, but it is set optical axes of the projectors in one direction and provide a projective equal volumes of pyramids based on stereootobrazhenie object on the screen.

This goal is also achieved by the fact that in the above method, when designing displays on the screen, a second planar display is obtained by transforming the first by a similarity coefficient of the triangular surfaces of the projective pyramids, depending on the size of the base and the distance of the projectors from the screen.

This goal is also achieved by the fact that in the device providing stereo images, consisting of two optical projectors spaced on a known base, the optical axes of which are directed to a coincident point on the screen, providing simultaneous line-by-line design of plane images of an object from matrices with records of its prepared plane images , synchronizer for reading information with line and frame scan generators, which is connected to the matrices, and the signals from the matrices are fed to opt optical projectors, while the optical axis of the projectors are directed in the same direction, and the matrix output is connected to the optical projectors through a signal analyzer.

The conversion of objects into planar displays, and their stereo imaging, is performed by the method of line-by-line design, in which any object, when sectioned by the observation plane ГY, is represented as line segments on the measurement plane ГΩ. Therefore, we consider the conversion of an object to planar displays and “back” to stereo display when representing an object in a straight line.

On figa shows the generally accepted planar process of line-by-line design by two optical converters S ₁ and S _{2 of the} object in the form of a line having optical axes directed to one point in space located in one plane GY, which we will call the design plane. The plane onto which the mappings of the object ΓΩ are projected will be called the measurement plane. Moreover, in a planar display in FIG. 1A, the axis Ω is orthogonal to the plane of the figure and is observed as a point. The object of observation, a straight line B, can be arbitrarily located in space, but its display on the plane GΩ will always be similar to its projection onto the plane parallel to GΩ. Therefore, in Fig. 1, the object and its display will be considered on parallel planes.

On figv shows the proposed method in which the optical converters S ₁ and S ₂ have optical axes directed in a straight line.

On figs shows the spatial process of obtaining planar images of the object when the transducers are located in the same direction.

Figure 2 shows a block diagram of a device for receiving stereo images.

Consider the generally accepted way to obtain stereo images of objects. To obtain planar stereo images, two optical transducers S ₁ and S _{2 are used} , having equal focal lengths f ₁ = f ₂ (distance from the lens to the screen) located on the same plane on a known base d _Г. In this case, the screen is parallel to the base, and the parallactic angle at which the corresponding rays intersect does not exceed 16 ⁰ , in accordance with [1].

From the design points that are combined with the transducers S ₁ and S ₂ , we construct two pairs of combined pyramids based on the object and its resulting mapping. In a planar representation, these are triangles. Each combined pair of pyramids consists of a pyramid based on the projection of the object onto a plane parallel to the measurement plane, and a pyramid based on the display of the object on the measurement plane ГΩ.

Pyramids based on an object or its stereo image will be called observation pyramids, and pyramids based on a plane display of an object are called measurement pyramids.

Let us compare the properties of the pairs of pyramids shown in FIG. 1A in their projections onto the observation plane ГY.

The observation pyramids have a common base and equal heights L ₁ = L ₂ , therefore, they have an equal volume (W)

On the GY plane, observation pyramids are displayed by triangles that have an equal surface area.

An articulated pair of pyramids of measurements - observations has the property of similarity

They are displayed on the ГY plane by paired similar triangles associated with the design point,

where W are the volumes of projective pyramids of observations;

w - volumes of projective pyramids of measurements;

L ₁ - the distance of the first design center from the object;

B _n - the length of the projection of the object along the axis G;

H _n - the height of the projection of the object along the axis Ω.

Plane displays of an object that have the indicated properties provide stereo images when designing from a given base if the volumes of their projective observation pyramids are equal and the triangles formed by the section of the pyramids by the projective planes are similar.

Plane displays of projective pyramids when the optical axes of the projectors are located in a straight line to the object shown in Fig. 1B, have the same properties. But given that the design points are located on one straight line, then from the equality of the volumes of the pyramids of observations it follows

From the similarity of the pyramids of measurements - observations follows

From the expressions (3) and (4) it follows that when the optical axes of the projectors are arranged in a straight line on the object, the planar displays of the projective pyramids shown in Figs. 1B and 1C have the property of linear size transformations in the pyramids, which the transformation does not have for any other arrangement of converters.

The considered properties when using optical converters located in the direction of the optical axes also apply when using similarly located optical projectors.

The device for obtaining stereo images and shown in figure 2, consists of a screen 1, two optical projectors S ₁ and S ₂ spaced on a known base d, the optical axes of which are directed at one coincident point on the screen, two matrices 2 and 3 with entries prepared planar displays of the object, information read synchronizer 4, including line 4a generators and personnel scans 4b, providing simultaneous line-by-line reading of plane displays of the object, which are received on the optical projectors S ₁ and S ₂ , while the projectors are located on the base that coincides with the direction of their optical axes, and the output of the matrices with recordings of plane images of the object is connected to the optical projectors through a signal analyzer 5.

The device operates as follows.

On matrices 2 and 3, planar displays of the object are recorded that satisfy the requirements for obtaining stereo images. In accordance with a given frequency, the information read synchronizer 4 provides synchronous line-by-line reading of plane images of an object from matrices 2 and 3. Information from matrices 2 and 3 is fed to analyzer 5, in which it is analyzed for compliance with a given base and the distance of the projectors from the screen. When the information corresponds to the expressions (3-4), it arrives at the projectors S ₁ and S ₂ . If information from one of the channels is missing or does not correspond to expressions (3-4), then analyzer 5 converts information or uses information from another channel to the set values of the base d and its distance from the screen L ₁ . The device allows you to turn planar displays into stereo images.

The proposed technical solution is new because it is not known from publicly available information.

A method for obtaining a stereo image of an object, including synchronous line-by-line design of prepared plane displays of an object by two projectors located on a known base, the optical axes of which are directed to a coincident point on the screen, by model building projective pyramids passing through the design points and boundary points of the prepared plane displays of the object to display on the screen, whose paired triangular planes associated with the design points are similar, characterized the fact that they establish the optical axis of the projectors in one direction and provide equal volumes of projective pyramids based on the stereo image of the object on the screen.

This goal is also achieved by the fact that in the above method, when designing displays on the screen, a second planar display is obtained by transforming the first by a similarity coefficient of the triangular surfaces of the projective pyramids, depending on the size of the base and the distance of the projectors from the screen.

A device for receiving stereo images, consisting of two optical projectors spaced on a known base, the optical axes of which are directed to a coincident point on the screen, providing simultaneous line-by-line design of plane displays of an object with matrices with records of its prepared plane displays, a synchronizer for reading information with line and frame generators scan, which is connected to the matrices, and the signals from them are fed to optical projectors, characterized in that the optical axes are The projectors are directed in the same direction, and the matrix output is connected to the optical projectors through a signal analyzer.

The proposed technical solutions have an inventive step, since it does not explicitly follow from published scientific data and known technical solutions that the claimed sequence of operations simplifies the task of obtaining stereo images.

The proposed technical solution is industrially applicable, since devices, equipment and devices widely used in practice can be used for its implementation.

The technical and economic effectiveness of the claimed method and its implementing device consists in a significant simplification of the method for obtaining stereo images, improving their quality, as well as receiving stereo images from one plane display.

Bibliography

1. Physical encyclopedic dictionary. - M .: Scientific publishing house "Soviet Encyclopedia". - 1983 .-- 928 s.

2. Mathematical Encyclopedic Dictionary. - M .: Scientific publishing house "Soviet Encyclopedia". - 1985 .-- 970 s.

3. Mukhin I.A. Autostereoscopic Displays - Broadcasting Television and Radio Broadcasting Magazine - 2004, No. 7, P.79-81

Claims (3)

1. A method of obtaining a stereo image of an object, including line-by-line synchronous design of prepared plane displays of an object by two projectors located on a known base, whose optical axes are directed to a coincident point on the screen, by model building projective pyramids passing through the design points and boundary points of the prepared plane displays of the object to its display on the screen, the paired triangular planes of which are associated with the design points are similar, distinguishing I in that the set of projectors optical axis in one direction and provide a projective equal volumes of pyramids based on stereootobrazhenie object on the screen. 2. The method according to claim 1, characterized in that when designing the displays on the screen, a second planar display is obtained by transforming the first by a similarity coefficient of the triangular surfaces of the projective pyramids, depending on the size of the base and the distance of the projectors from the screen. 3. A device for receiving stereo images, consisting of two optical projectors spaced on a known base, the optical axes of which are directed to a coincident point on the screen, providing simultaneous line-by-line design of planar images of an object from matrices with records of its prepared planar displays, a synchronizer for reading information with line generators and frame scan, which is connected to the matrices, and the signals from the matrices are fed to optical projectors, characterized in that the optical and projectors are directed in the same direction, and the matrix output is connected to the optical projectors through a signal analyzer.

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