KR102110866B1 - Digital hologram image display device and method for displaying holorgram 3d image - Google Patents

Abstract

The present invention relates to an apparatus for reproducing / reproducing a digital hologram image and reproducing a 3D image and a method for reproducing a stereoscopic image by the apparatus. A digital hologram image reproducing apparatus according to the present invention includes a pattern generator for generating a screen pattern including an interference pattern corresponding to image data to be displayed and a prism pattern corresponding to background data; A spatial light modulator for receiving and displaying the screen pattern output from the pattern generator; And a light source disposed on one side of the spatial light modulator and irradiating reference light with the spatial light modulator.

Description

A digital hologram image playback device and a stereoscopic image playback method using the device {DIGITAL HOLOGRAM IMAGE DISPLAY DEVICE AND METHOD FOR DISPLAYING HOLORGRAM 3D IMAGE}

The present invention relates to an apparatus for reproducing / reproducing a digital hologram image and reproducing a 3D image and a method for reproducing a stereoscopic image by the apparatus. In particular, the present invention relates to a digital hologram image reproducing apparatus in which a zero-order diffraction component (DC component; non-diffracted term) is removed to optimize digital hologram image reconstruction and reproduction, and a stereoscopic image reproducing method using the apparatus.

Recently, studies on three-dimensional (3D) images and image reproduction technologies have been actively conducted. The 3D image-related media is expected to lead the next generation of imaging devices as a new concept of realistic image media that raises the level of visual information to a new level. The existing two-dimensional imaging system provides a flat image, but the three-dimensional imaging system can be said to be the ultimate image realization technology from the viewpoint of showing the actual image information of the object to the observer.

As a method for reproducing a 3D stereoscopic image, methods such as stereoscopy, holography, and integrated imaging have been researched and developed. Among them, the holography method is a method in which a stereoscopic image identical to a real object can be felt without wearing special glasses when observing the holography produced using a laser. Therefore, the holography method is known to be the most ideal way for the viewer to feel a three-dimensional image without feeling tired.

The holography method uses a principle of recording and reproducing an interference signal obtained by superimposing light (object wave) reflected from an object and light having interference (reference wave). A hologram is a method of recording an interference fringe formed on a scattering film by making an object wave scattered by striking an object with a coherent laser light to meet a reference wave incident in another direction. When the object wave and the reference wave meet, an interference fringe due to interference is formed, and the amplitude and phase information of the object are recorded in the interference fringe. Holography is a method of restoring a three-dimensional image recorded on a hologram to a three-dimensional image by irradiating reference light to the interference fringe recorded in this way.

A computer generated hologram (CGH) has been developed as a computer-generated method for storing, transmitting and processing holograms. This computer-generated hologram has been developed in various ways so far, and recently, with the development of the digital industry, a system for displaying a computer-generated hologram of a moving image has been developed without staying in the computer-generated hologram of a still image.

The computer generated hologram is to create an interference fringe that is directly stored in the hologram using a computer. After calculating and generating the interference fringe image by computer, it transmits it to a spatial light modulator such as Liquid Crystal-Spatial Light Modulator (LC-SLM), and irradiates the reference light to this SLM to restore a stereoscopic image. To play. 1 is a view showing the configuration of a digital hologram image reproducing apparatus implementing a computer-generated hologram method according to the prior art.

Referring to FIG. 1, an interference fringe image corresponding to a stereoscopic image to be implemented by the computer 10 is generated. The generated interference fringe is transmitted to the SLM 20. The SLM 20 may be formed of a transmissive liquid crystal display panel to display interference fringes. A laser light source 30 to be used as a reference light is located on one side of the SLM 20. The expander 40 and the lens 50 are sequentially arranged in order to uniformly project the reference light 90 irradiated from the laser light source 30 onto the front surface of the SLM 20. The reference light 90 emitted from the laser light source 30 is irradiated to one side of the SLM 20 via the expander 40 and the lens 50. When the SLM 20 is a transmissive liquid crystal display panel, the 3D stereoscopic image 80 is displayed on the other side of the SLM 20 by the interference fringe of the hologram implemented in the SLM 20.

At this time, all of the reference light 90 passing through the hologram pattern implemented in the SLM 20 does not diffract, and a component passing through the SLM 20 is generated. These components are called DC components (non-diffracted term) or zero-order diffraction components. The 0th-order diffracted light that has just passed through the SLM 20 without diffraction is caused to overlap with the restored image and degrade the quality of the restored image.

FIG. 2 is a diagram illustrating a case in which a digital hologram image is expressed without removing zero-order diffraction components in a computer-generated hologram method according to the related art. 3 is a graph showing the quality of an image when a digital hologram image is expressed without removing the zero-order diffraction component as shown in FIG. 2.

As shown in FIG. 2, when the hologram interference pattern 8 is displayed by the SLM 20 and the reference light 90 is irradiated, the interference pattern of the hologram implemented in the SLM 20 on the other side of the SLM 20 The stereoscopic image 80 corresponding to (8) is displayed in the output image area IA. At this time, the remaining area except the interference fringe 8 of the hologram on the display surface of the SLM 20 becomes a background area BA without any interference fringe.

The reference light 90 is irradiated to the entire surface of the SLM 20. The reference light 90 irradiated on the interference fringe 8 of the hologram displayed on the SLM 20 is diffracted and irradiated to the output image area IA. In addition, the reference light 90 irradiated on the background area BA, which is an area other than the interference fringe 8 of the hologram, is a DC component that is a peripheral portion of the stereoscopic image 80 in the output image area IA without diffraction. The area DA is irradiated.

Thus, the stereoscopic image 80 and the DC component region DA by diffraction are both irradiated to the output image region IA. Since the amount of light of the DC component is larger than the amount of light diffracted, as shown in FIG. 3, the stereoscopic image 80 is not normally recognized. Referring to FIG. 3, although the stereoscopic image 80 is displayed in the central portion, it overlaps with the DC component and no component of the stereoscopic image 80 is visible. Therefore, in order to obtain a high quality 3D image, the 0th order diffraction component must be removed. So far, there have been many studies related to removing zero-order diffracted light from a digital hologram.

For example, there is a method of dispersing and removing zero-order diffracted light using a concave lens in SLM (OpticsInfoBase '09, 7 "Experimental modules covering imaging, dffraction, Fourier optics and polarization based on a liquid-crystal cell SLM) However, in this case, there is a problem that the size of the reconstructed image is reduced, and a method of attenuating the 0th-order diffracted light using a polarizer (Otics Express '08, 9 "Hologram optimization for SLM-based reconstruction with regard to polarization effects ") has been proposed. However, in this case, a problem arises in that the intensity of the reconstructed image is lowered. In addition, although the 0th-order diffracted light can be removed by a mechanical method, it is reconstructed. There is a problem that an image cannot be lost or an effect cannot be obtained at all for a large image.

An object of the present invention is designed to overcome the limitations of the conventional digital hologram image reproducing apparatus, a digital hologram image reproducing apparatus for reproducing high-quality 3D images by removing zero-order diffraction components and a stereoscopic image reproducing method using the apparatus To provide. Another object of the present invention is to provide a digital hologram image reproducing apparatus and a stereoscopic image reproducing method using the apparatus by removing zero-order diffraction components without including separate optical equipment and components to reproduce high-quality 3D images. Having

In order to achieve the object of the present invention, the digital hologram image reproducing apparatus according to the present invention is a pattern generator for generating a screen pattern including an interference pattern corresponding to image data to be displayed and a prism pattern corresponding to background data ; A spatial light modulator for receiving and displaying the screen pattern output from the pattern generator; And a light source disposed on one side of the spatial light modulator and irradiating reference light with the spatial light modulator.

The pattern generator may include a data analyzer separating the image data and the background data from screen data constituting one screen; A background combiner to apply the prism pattern to the background data; And it characterized in that it comprises an output unit for transmitting a screen pattern combining the interference pattern and the prism pattern to the spatial light modulator.

The interference pattern corresponding to the image data includes at least one of two-dimensional image data and perspective data; The background data is characterized in that it does not include any of the two-dimensional image data and the perspective data.

The reference light entering the region where the interference pattern is displayed in the spatial light modulator displays the image data in the image region where the viewer is located; The reference light entering the area where the prism pattern is displayed in the spatial light modulator is refracted to an area far from the image area.

It characterized in that it further comprises an optical device for adjusting the cross-section of the reference light to irradiate the reference light emitted from the light source to the front surface of the spatial light modulator.

In addition, the method for reproducing a stereoscopic image according to the present invention includes separating image data and background data from screen data constituting one screen; Converting the image data into an interference pattern and converting the background data into a prism pattern; And outputting a screen pattern combining the interference pattern and the prism pattern to a spatial light modulator.

The interference pattern is characterized by including at least one of two-dimensional image data and perspective data.

By irradiating reference light from one side of the spatial light modulator on which the screen pattern is displayed, the reference light passing through the interference pattern irradiates a stereoscopic image to an image area, and the reference light passing through the prism pattern is far from the image area It characterized in that it further comprises the step of irradiating to the area.

The digital hologram image reproducing apparatus according to the present invention can selectively remove the zero-order diffraction component separately from image information. In particular, the digital hologram image reproducing apparatus according to the present invention selectively restores only a desired 3D image to a desired location by separating the 0th-order diffraction component into a location remote from the region where the image is displayed without additional optical equipment or components.

1 is a view showing the configuration of a digital hologram image reproducing apparatus implementing a computer generated hologram method according to the prior art.
FIG. 2 is a diagram illustrating a case in which a digital hologram image is expressed without removing a zero-order diffraction component in a computer-generated hologram method according to the related art.
3 is a graph showing the quality of an image when a digital hologram image is expressed without removing the zero-order diffraction component as shown in FIG. 2.
4 is a diagram showing the configuration of a digital hologram image reproducing apparatus embodying a computer-generated hologram method according to the present invention.
5 is a diagram showing an example of a digital hologram image displayed on a spatial light modulator screen to remove zero-order diffraction components in the computer-generated hologram method according to the present invention.
6 is a plan view showing the configuration of a screen showing a computer generated hologram in the liquid crystal spatial light modulator according to the present invention.
7 is a flowchart illustrating a stereoscopic image reproducing method of a digital holographic image reproducing apparatus implementing a computer generated hologram method according to the present invention.
8 is a graph showing the quality of a digital hologram image in which the 0th-order diffraction component is removed, as illustrated in FIG. 6.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Throughout the specification, the same reference numerals refer to substantially the same components. In the following description, when it is determined that a detailed description of a known function or configuration related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description is omitted. In addition, the component names used in the following description may be selected in consideration of the ease of writing the specification, and may be different from the actual product part names.

Hereinafter, a digital hologram image reproducing apparatus implementing the computer generated hologram method according to the present invention will be described with reference to FIGS. 4 and 5. 4 is a view showing the configuration of a digital hologram image reproducing apparatus implementing the computer generated hologram method according to the present invention. FIG. 5 is a diagram showing an example of a digital hologram image displayed on a spatial light modulator screen to remove zero-order diffraction components in the computer-generated hologram method according to the present invention.

Referring to FIG. 4, the digital hologram image reproducing apparatus according to the present invention generates an interference fringe image corresponding to a stereoscopic image to be implemented in the computer 100. The generated interference fringe is transmitted to the SLM 200. The SLM 200 may be formed of a transmissive liquid crystal display panel to display interference fringes. A light source 300 to be used as the reference light 900 is located on one side of the SLM 200. The light source 300 provides collimated light having excellent coherence such as a laser. If necessary, the expander 400 and the lens 500 may be sequentially disposed to uniformly project the reference light 900 irradiated from the light source 300 onto the entire surface of the SLM 200. The reference light 900 emitted from the light source 300 is irradiated to one side of the SLM 200 through the expander 400 and the lens 500. When the SLM 200 is a transmissive liquid crystal display panel, the 3D stereoscopic image 800 is displayed on the other side of the SLM 200 by the interference fringe of the hologram implemented in the SLM 200.

The digital hologram image reproducing apparatus according to the present invention shown in FIG. 4 is for showing the concept of configuration. Therefore, including such a concept, each component may be thinned to realize an ultra-thin film type digital holographic image reproducing apparatus. The present invention relates to a method for implementing a stereoscopic image pattern displayed on a spatial light modulator, and a description of a practical configuration is omitted.

The computer 100 according to the present invention includes a pattern generator 110 that generates an interference fringe (pattern) that removes DC components. Here, the interference fringe removing the DC component means a screen pattern displayed on the display area of the SLM 200. The screen pattern consists of an interference pattern corresponding to the image data to be displayed and a prism pattern corresponding to the background data.

The interference fringe is a hologram pattern corresponding to image data that is a specific stereoscopic image. The image data includes two-dimensional image data and depth map data. In some cases, both 2D image data and perspective data may be included, or only one data may be included.

On the other hand, the background data corresponding to the background BA has a value that does not have both data, that is, zero. That is, in the background data of the screen pattern according to the prior art, both the 2D image data and the perspective data are zero and there is no interference pattern. Therefore, in the prior art, the reference light 90 passing through the background without the interference pattern acted as a DC component, but in the present invention, a prism pattern is applied to the background data. As a result, the reference light 900 incident on the background BA has a DC component, but is refracted by a prism pattern and irradiated to an area far from the area where the stereoscopic image 800 is displayed (Out of Range).

The pattern generator 110 according to the present invention is a data analyzer 101 that separates the image data and the background data from screen data constituting one screen of the SLM 200, and a background separated from the data analyzer 101. It includes a background combiner 103 for applying a prism pattern to the data, and an outputter 105 for transmitting a new screen pattern combining the prism pattern and the interference pattern corresponding to the image data to the SLM 200.

The data analyzer 101 analyzes screen data constituting one screen of the SLM 200 to separate image data and background data. That is, the two-dimensional image data and the perspective data are both defined as background data, and any one data is not zero as image data.

The background combiner 103 replaces the data determined by the data analyzer 101 as background data with a prism pattern. The prism pattern may cause a plurality of prisms to be arranged in the horizontal direction, or a plurality of prisms may be arranged in the vertical direction. The prism pattern changes the arrangement of the liquid crystal layers constituting the SLM 200 to have the same optical effect as the prism.

The output device 105 transmits a new screen pattern generated by combining the interference pattern and the prism pattern to the SLM 200. Referring to FIG. 5, the interference pattern 808 and the background BA are displayed on the display area of the spatial light modulator according to the present invention, that is, the SLM 200. The interference pattern 808 is a hologram pattern corresponding to image data generated by the pattern generator 110. The background BA is a prism pattern applied to the background data by the pattern generator 110.

As a result, the reference light 900 irradiated to the region of the SLM 200 where the interference pattern 808 is displayed becomes light 910 diffracted by the interference pattern 808 and is irradiated to the image area. On the other hand, the reference light 900 irradiated to the region of the SLM 200 on which the prism pattern is displayed changes the path to the refracted reference light 900, so that the reference light 910 diffracted by the interference fringe 808 is irradiated. It is investigated in a completely different area away from the area.

6 is a plan view showing a configuration of a screen showing a computer generated hologram in the liquid crystal spatial light modulator according to the present invention. Referring to FIG. 6, a screen constituting the SLM 200 is composed of a background BA and an interference fringe 808. In particular, in the present invention, a prism pattern is applied to the background BA. 6 shows a case in which a prism is formed in a vertical direction. However, if necessary, a prism may be formed in the horizontal direction. As an example of the prism pattern, the prism pattern may be repeatedly formed so that a certain width generates a phase difference of 0π and its neighboring constant width generates a phase difference of 1π.

Hereinafter, a stereoscopic image reproduction method in which DC components are removed by the digital hologram image reproduction apparatus according to the present invention will be described with reference to FIG. 7. 7 is a flowchart illustrating a stereoscopic image reproducing method of a digital holographic image reproducing apparatus implementing a computer generated hologram method according to the present invention.

Input screen data constituting one screen of a stereoscopic image to be displayed in the image area. Here, the screen data may be screen data of a stereoscopic image to be ultimately provided to a viewer. (S1)

By analyzing screen data, image data and background data are separated. Data that is at least one of two-dimensional image data and perspective data that is not zero is defined as image data. On the other hand, background data defines that both 2D image data and perspective data are zero. (S2)

The image data is converted into a corresponding interference pattern. A prism pattern is applied to data determined as background data. That is, an area without any data is converted into a prism pattern. (S3)

A screen pattern is generated by combining the newly generated interference pattern and the prism pattern, and is output to the SLM 200 which is a spatial light modulator. (S4)

The spatial light modulator in which the screen pattern is displayed, that is, the reference light 900 is irradiated from one side of the SLM 200, and the reference light 900 passing through the interference pattern 808 transmits the stereoscopic image 800 to the image area IA. The reference light 900 that has passed through the prism pattern is irradiated with the DC area DA away from the image area. (S5)

In this way, in the interference fringe image in which the DC component is not removed, a new interference fringe image is generated by combining a prism pattern with background data in which the DC component is present. According to the present invention, the reference light 900 transmitted through the background BA where the DC component is not removed is refracted into the DC area DA, which is completely away from the image area IA viewed by the viewer. That is, although the DC component is not completely removed, the DC component is bypassed to the DC region DA which is a non-viewing region far from the image region IA where the interference fringe is irradiated so that the DC component does not act as noise in the stereoscopic image. . Here, the DC area DA is possible in any of the upper, lower, and side directions based on the video area IA, which is a viewing area.

FIG. 8 is a graph showing the quality of a digital hologram image in which the 0th-order diffraction component is removed, as illustrated in FIG. 5. As shown in FIG. 6, all DC components, that is, the 0th-order diffraction component, are refracted outside the viewer's viewing area, and only the desired 3D stereoscopic image 800 is irradiated to the viewer's viewing area. Accordingly, it can be seen from the viewer's viewing area that the stereoscopic image is observed with excellent quality without any DC component, as shown in FIG. 8.

Through the above description, those skilled in the art will appreciate that various changes and modifications are possible without departing from the spirit of the present invention. Therefore, the present invention should not be limited to the contents described in the detailed description, but should be defined by the claims.

10: computer 20, 200: spatial light modulator (SLM)
30: laser light source 40: expander
50: lens 80, 800: stereoscopic image
90: reference light 8, 808: interference fringe
BA: Back ground area
IA: (Output) video area DA: DC area
110: pattern generator 101: data analyzer
103: background combiner 105: writer

Claims (8)

A pattern generator for generating a screen pattern including an interference pattern corresponding to image data to be displayed and a prism pattern corresponding to background data;
A spatial light modulator for receiving and displaying the screen pattern output from the pattern generator; And
Is disposed on one side of the spatial light modulator includes a light source for irradiating the reference light with the spatial light modulator,
The reference light entering the region where the interference pattern is displayed in the spatial light modulator displays the image data in the image region where the viewer is located;
A digital hologram image reproducing apparatus characterized in that the reference light entering the region where the prism pattern is displayed in the spatial light modulator is refracted to a region far from the image region.
According to claim 1,
The pattern generator,
A data analyzer separating the image data and the background data from screen data constituting one screen;
A background combiner to apply the prism pattern to the background data; And
And an output unit that transmits a screen pattern combining the interference pattern and the prism pattern to the spatial light modulator.
According to claim 2,
The interference pattern corresponding to the image data includes at least one of two-dimensional image data and perspective data;
The background data does not include any one of the two-dimensional image data and the perspective data.
delete According to claim 1,
And an optical device that adjusts a cross-section of the reference light to irradiate the reference light emitted from the light source to the front surface of the spatial light modulator.
Separating image data and background data from screen data constituting one screen;
Converting the image data into an interference pattern and converting the background data into a prism pattern;
Outputting a screen pattern combining the interference pattern and the prism pattern to a spatial light modulator; And
By irradiating reference light from one side of the spatial light modulator on which the screen pattern is displayed, the reference light passing through the interference pattern irradiates a stereoscopic image to an image area, and the reference light passing through the prism pattern is far from the image area And irradiating the area.
The method of claim 6,
The interference pattern, the stereoscopic image reproduction method characterized in that it comprises at least one of two-dimensional image data and perspective data.
delete

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