KR102072491B1 - Device for measuring hologram reconstruction image by varying vergence of incident wave, method for measuring hologram reconstruction image using the device, computer readable medium for performing the method - Google Patents

Abstract

The holographic reproduction image measuring apparatus using a variable convergence degree of incident light waves according to the present invention photographs a light source array for outputting incident light waves at different output distances to the hologram film and photographs the reproduction light waves of the incident light waves passing through the hologram film. And a camera for measuring a hologram image for a specific focal length reproduced by the hologram film, and selectively illuminating a light source constituting the light source array to sequentially display a plurality of hologram images having different focal lengths at a fixed position. It can be measured.

Description

Hologram playback image measuring device using variable convergence degree of incident light, hologram playback image measuring method using same, recording medium for performing the method IMAGE BY VARYING VERGENCE OF INCIDENT WAVE IMAGE USING THE DEVICE, COMPUTER READABLE MEDIUM FOR PERFORMING THE METHOD}

The present invention relates to a holographic reproduction image measuring apparatus using a variable convergence degree of incident light waves, a holographic reproduction image measuring method using the same, and a recording medium for performing the method, and more particularly, to a multi-view image of a holographic film. A holographic reproduction image measuring apparatus using a variable convergence degree of incident light waves to be measured, a holographic reproduction image measuring method using the same, and a recording medium for performing the method.

Holography technology is an image recording method using interference of light, and it is used in various industrial fields because it can provide a continuous image of a subject or give a depth to the same subject depending on a viewpoint of an image.

The hologram film is a photosensitive material in which an interference fringe of a subject is recorded by using a holography technique. As a method for measuring whether a subject is accurately recorded on a hologram film, a hologram film is conventionally moved by moving a viewpoint of a camera according to each viewpoint. Techniques for acquiring images have been disclosed. In this regard, it will be described with reference to FIG.

1 is a diagram illustrating an example of a method for measuring a holographic playback image according to the related art.

In the holographic reproduction image measuring method according to the related art, a single light source is incident on a hologram film, and images of the reproduction light waves passing through the hologram film by the light source are measured at various points in time.

However, in the holographic reproduction image measuring technique according to the related art, the output position of the incident light wave is fixed, and thus, a plurality of focal lengths in which the hologram image is actually formed is fixed. In this case, in order to measure holographic images having different focal lengths, it is inconvenient to measure an image while adjusting a focusing lens provided in the camera for each focal length of the holographic image or moving the camera in a forward and backward direction.

Korean Patent Publication No. 10-2017-0011180 Korean Patent Registration No. 10-1669830

One aspect of the present invention allows a hologram image having different focal lengths to be photographed by a camera disposed at a fixed position so that the convergence degree of incident light waves for measuring the quality of the holographic reproduction image reproduced by the hologram film is variable. The present invention provides a holographic playback image measuring apparatus and a holographic playback image measuring method using the same.

The technical problem of the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

An apparatus for measuring a hologram reproduction image using a variable convergence degree of incident light waves according to an embodiment of the present invention includes a lens disposed at a position spaced apart from a hologram film in which different hologram images are reproduced according to a viewing distance, and the lens is disposed. A light source array including a plurality of light sources disposed along an optical axis of the light source and arranged to have different distances from the midpoint of the lens such that incident light waves having different output distances are output to the hologram film through the lens; Taking a reproduction light wave of the incident light passing through the hologram film to measure a hologram image for a specific focal length reproduced by the hologram film, and according to the focal length of the reproduction light wave that varies according to the output distance of the incident light wave Selective measurement of holographic images at fixed positions It includes a camera.

Each light source constituting the light source array may be disposed to have a different distance from the midpoint of the lens, and the distances between the light sources may be the same.

The plurality of light sources constituting the light source array are selectively turned on so that any kind of focal length formed at a reference position on the optical axis is changed among the plurality of focal lengths of the reproduction light waves in inverse proportion to the output distance of the incident light waves. Can be.

The camera may be fixedly disposed at the reference position to measure a hologram image having a specific focal length formed at the reference position among the holographic images for each focal length of the reproduction light wave.

The camera sequentially measures a hologram image for a specific focal length selectively formed at the reference position by incident light waves having different output distances as the light source is selectively turned on, and records the hologram recorded on the hologram film. Images for all focal lengths of the image may be acquired at a fixed position.

The lens may convert a spherical wave-type incident light wave output from any one light source into a plane wave-type incident light wave.

In addition, the hologram playback image measuring method using a hologram playback image measuring apparatus using a variable convergence degree of incident light waves according to the present invention, any one of a plurality of light sources arranged to output the incident light waves at different output distance to the hologram film Controlling the incident light wave to be output from a light source of the light source, measuring the hologram image for a specific focal length reproduced by the hologram film by photographing the reproduction light wave of the incident light wave that has passed through the hologram film, and along the optical axis Selectively illuminating the plurality of light sources such that the hologram images for all focal lengths of the holographic images having different focal lengths are sequentially measured by a camera disposed at a predetermined reference position on the optical axis.

The measuring hologram image for the specific focal length may include measuring a hologram image for a specific focal length formed at the reference position among a plurality of focal lengths of the reproduction light wave inversely proportional to the output distance of the incident light wave. can do.

Measuring a hologram image for a specific focal length formed at the reference position among a plurality of focal lengths of the reproduction light waves inversely proportional to the output distance of the incident light waves, all of the reproduction light waves formed at a specific position from the hologram film The reproduction of the first hologram image having a relatively short focal length among the focal lengths to selectively turn on the first light source located at a relatively close distance from the lens, and to form the first holographic image at a specific position from the hologram film A second hologram image having a relatively long focal length among all focal lengths of the light waves may be selectively turned on so that a second light source located at a relatively distance from the lens than the first light source may be formed at the reference position. Can be.

Selectively lighting the plurality of light sources may sequentially measure a hologram image for a specific focal length selectively reproduced at the reference position for each light source selectively lit, and thus all focal lengths of the hologram images recorded on the hologram film. It may be characterized in that for obtaining an image for the at the reference position.

After sequentially turning on all light sources constituting the light source array, the method may further include calculating a similarity by comparing the hologram image for a specific focal length measured by the camera with a previously stored reference image.

The calculating of the similarity may include searching for a light source operated in the process of generating the extracted holographic image when at least one holographic image determined to have a similarity less than a threshold is extracted.

The method may further include controlling the reproducing of the hologram image having the similarity less than the threshold by sequentially operating again one or more light sources found in the similarity calculation process among all the light sources of the light source array.

The method may further include collecting information about a position of a focal length of the hologram image recorded on the hologram film in advance, wherein selectively lighting the plurality of light sources comprises analyzing all the light sources to form a light source array. At least one light source to be selectively turned on may be extracted in advance to selectively light the previously extracted light source.

In addition, the computer-readable recording medium according to the present invention may be a computer program for performing the hologram playback image measuring method.

According to one aspect of the present invention, it is possible to measure images of different focal lengths in the hologram reproduction light waves at a predetermined position without the camera movement to simplify the measurement mechanism and shorten the measurement time.

1 is a conceptual diagram illustrating an example of a method for measuring a hologram playback image according to the related art.
2 is a conceptual diagram of a hologram reproducing image measuring apparatus using a variable convergence degree of incident light waves according to an exemplary embodiment of the present invention.
3 to 6 are conceptual views illustrating a specific example of measuring a holographic reproduction image using the measuring apparatus shown in FIG. 2.
7 is a flowchart illustrating a schematic flow of a method for measuring a holographic playback image using the holographic playback image measuring apparatus according to an exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION The following detailed description of the invention refers to the accompanying drawings that show, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It is to be understood that the various embodiments of the invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be embodied in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. In addition, it is to be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled. Like reference numerals in the drawings refer to the same or similar functions throughout the several aspects.

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

2 is a conceptual diagram illustrating a schematic configuration of a holographic image measuring apparatus using a variable convergence degree of incident light waves according to an embodiment of the present invention.

The hologram reproduction image measuring apparatus 1 using the variable convergence degree of incident light waves according to the present invention is a fixed time point of an image of a hologram image reproduced by a hologram film 50 in which an interference fringe of a subject is recorded. The photographing may generate a photographed image, and the quality of the holographic image recorded on the hologram film 50 may be measured using the photographed image. In this case, the hologram regenerated image measuring apparatus 1 using the variable convergence degree of incident light waves according to the present invention selectively outputs a plurality of incident light waves having different output distances to the hologram film 50, thereby providing a fixed position. Images of a particular focus of holographic images having different focal lengths may be selectively acquired from the arranged camera.

Specifically, the hologram playback image measuring device (hereinafter, referred to as a measuring device) using a variable convergence degree of incident light waves according to an embodiment of the present invention includes a light source array 100, a lens 200, and a camera 300. do.

The light source array 100 may be disposed on one side of the measuring device 1. For example, the light source array 100 may be disposed at the lower end of the measuring device 1 to irradiate the light source toward the hologram film 50 placed on the stop of the measuring device 1.

The light source array 100 includes a plurality of light sources 100_1, 100_2, and 100_3, and each light source 100_1, 100_2, and 100_3 is configured to output incident light waves having different output distances to the hologram film 50. The placement position can be determined. Specifically, each of the light sources 100_1, 100_2, and 100_3 constituting the light source array 100 may be spaced apart by a predetermined distance along the optical axis of the lens 200 to be described later.

In addition, each of the light sources 100_1, 100_2, and 100_3 constituting the light source array 100 may be disposed to have different distances from the midpoint of the lens 200. In the illustrated embodiment, the first light source 100_1 may be disposed at a position spaced apart from the midpoint of the lens 200 by a first distance d1 along the optical axis. The second light source 100_2 may be disposed at a position spaced apart from the midpoint of the lens 200 by a second distance d2 along the optical axis, and the third light source 100_3 is a midpoint of the lens 200. It may be disposed at a position spaced apart from the third axis (d3) along the optical axis from. Here, the first distance may be set smaller than the second distance, and the second distance may be set smaller than the third distance.

That is, each of the light sources 100_1, 100_2, and 100_3 constituting the light source array 100 may be spaced apart from the midpoint of the lens 200 by a predetermined interval along the optical axis. In this case, the intervals between the light sources of the light sources 100_1, 100_2, and 100_3 constituting the light source array 100 may be spaced apart at the same interval d along the optical axis. However, the disposition distance between the light sources is not limited to the above-described embodiment, and the disposition distance between the light sources becomes longer as the distance from the lens 200 increases, or the disposition distance between the light sources becomes shorter as the distance from the lens 200 increases. May be arranged in various ways. The number of light sources constituting the light source array 100 is not limited to the illustrated embodiment, and the number of light sources is not limited to two as long as the number of light sources is two or more.

The lens 200 is an optical system disposed between the light source array 100 and the hologram film 50, and changes the spherical wave type incident light output from any one of the light sources 100_1, 100_2, and 100_3 into incident light wave of the planar wave type. The incident light wave may be induced to enter the hologram film 50 at a predetermined angle.

The camera 300 may be a device for photographing incident light waves passing through the hologram film 50. That is, the camera 300 may be a device for photographing the regenerated light wave of the hologram film 50 with respect to the incident light wave to take a hologram image for a specific focal length reproduced by the hologram film 50.

At this time, the camera 300 is fixedly positioned at a position spaced apart from the hologram film 50 by a predetermined distance from the upper end of the measuring device 1, the measuring device 1 according to the present invention is a camera disposed at a fixed position As described above, the output position of the incident light wave may be changed so that the image of the focal length of the hologram reproduction image may be measured at 300.

In addition to this, the measuring device 1 according to an embodiment of the present invention may further include a control module (not shown).

The control module (not shown) can control the overall operation of the measuring device 1 according to the invention. For example, the control module (not shown) may transmit a control signal to any one of the light sources 100_1, 100_2, and 100_3 to control an incident light wave having a specific output distance. In addition, the control module (not shown) may control the camera (not shown) to photograph the reproduction light waves passing through the hologram film, thereby controlling to capture a reproduction image of a specific focal length of the hologram image recorded on the hologram film. have.

The control module (not shown) is provided inside the measuring device 1 to operate as a component of the measuring device 1, or is provided outside the measuring device 1 and connected to the measuring device 1 through wired or wireless communication. The operation of the measuring device 1 can be controlled. Hereinafter, for convenience of description, a control module (not shown) is provided inside the measuring device 1, and a series of holographic reproduction image measuring methods of the measuring device 1 performed by the control module (not shown) are performed. The process is assumed to be performed by the measuring device 1.

On the other hand, the measuring device 1 may be configured to selectively change the output position of the incident light wave incident on the hologram film, and control the camera 300 to generate captured images of the focal lengths of the reproduction light waves. In this regard, it will be described with reference to FIGS. 3 to 6 together.

First, FIG. 3 is a conceptual diagram illustrating a basic principle of determining a focal length of a reproduction light wave according to a convergence degree of an incident light wave that is changed according to an output position of a light source.

When the incident light wave is output at a position spaced apart from the midpoint of the lens 200 along the optical axis by a distance d ₁ , the incident light wave in the form of spherical waves may propagate by the distance d ₁ and enter the lens 200. In this case, the spherical wave with respect to the surface (U ₁ ) immediately before the incident to the lens 200 may be defined as follows.

Here, A ₁ is a variable representing the amplitude of the incident light wave, d ₁ is a variable representing the distance from the center of the spherical incident light wave located on the optical axis when the optical axis of the lens is called the z axis.

The transmittance t ₁ of the lens 200 is as follows.

Here, f is a focal length of the lens 200 and is a predetermined constant value.

The light wave on the surface U ₂ immediately after the incident light wave passes through the lens 200 may be defined according to the following equation.

Thereafter, the incident light wave passing through the lens 200 propagates by the distance d _{2 and the} light wave on the surface U ₃ immediately before being incident on the hologram film 50 may be represented by Equation 4 below.

C _in Equation 5 is the curvature of the incident light wave immediately before the incident on the hologram film 50, U ₃ , the curvature of the incident light wave according to the position of the light source to the hologram film 50 The focal position of the reproduction light wave that is the passed light wave may be determined. In this case, the transmittance t _H of the hologram film 50 may be designed to satisfy the following equation.

As shown in FIG. 3, the regenerated light waves may have three focal lengths from the hologram film 50, and different holographic images A, B, and C are formed according to the focal lengths. That is, the observer may look at the holographic film 50 in a position apart by d _A from the hologram film 50 watching a first holographic image (A), a position spaced d _B from the holographic film 50, the 2 enjoys a holographic image (B), and look at the holographic film 50 in a position spaced _C d from the hologram film 50, first it is possible to listen to three holographic image (B).

At this time, the regenerated light wave, which is the incident light wave passing through the hologram film 30, is determined by the incident light wave just before passing through the hologram film 50 and the transmittance of the hologram film 50, which is expressed as follows.

As such, the focal length of the reproduction light wave is determined according to the output distance of the light source, and specifically, the focal length of the reproduction light wave may be determined in inverse proportion to the output distance of the light source. That is, the closer the output distance of the incident light wave is, the farther the focal length of the reproduction light wave is from the hologram film 50. As a result, a hologram image having a relatively close focal length among the plurality of focal lengths at the reference position on the optical axis Can be formed in position. On the contrary, as the output distance of the incident light wave increases, the overall focal length of the reproduced light wave may be formed in a direction closer to the hologram film 50. At this time, the hologram image having a relatively far focal length among the plurality of focal lengths at the reference position. This may be formed at the corresponding reference position.

Therefore, when the camera 300 is fixedly disposed at the reference position, a plurality of hologram images A, B, and C having different focal lengths are fixed according to the output position of the incident light wave and the magnitude of curvature of the incident light wave. It is possible to measure from. In this regard, it will be described with reference to FIGS. 4 to 6 together.

4 to 6 are conceptual views illustrating an example in which the measuring device 1 of FIG. 2 selectively measures holographic images having different focal lengths at fixed positions.

First, as shown in FIG. 4, the measuring device 1 may transmit a control signal to the first light source element 200_1 to control the light source to be output from the first light source 100_1. As described above with reference to FIG. 2, the first light source 100_1 is a light source disposed at a position spaced apart from the midpoint of the lens 200 by the first distance d1, and the output distance of the incident light wave may also be determined as d1.

In this case, when the output distance d1 of the incident light wave is shorter than the focal length f of the lens (d1 <f), and the curvature of the incident light wave is larger than 0 (c _in > 0), the first focal length is set at the reference position. The first hologram image A may be observed. 3 and 5, the curvature of the incident light wave is a focal length f of the lens 200, and a separation distance d ₂ between the hologram film 50 and the lens 200. And the distance d ₁ between the light source and the lens 200, and the values of f and d ₂ are always fixed values, and as a result, are formed at the reference position by the output distance d ₁ of the incident light wave. The focal length of the reproduced light waves can be determined.

That is, when the first light source 100_1 at a relatively close distance from the lens 200 is selectively turned on, the entire focal length of the reproduction light wave may be formed at a position relatively far from the hologram film 50. In this case, the first hologram image A having a relatively short focal length among the hologram images A, B, and C having different focal lengths reproduced by the hologram film 50 may be reproduced at the reference position. Therefore, when the first light source 100_1 is turned on, the camera 300 fixedly disposed at the reference position may capture the first hologram image A. FIG.

When it is confirmed that the photographed image of the incident light wave output from the first light source 100_1 is generated, the measuring device 1 selectively operates the second light source 100_2 as shown in FIG. 5 to output the incident light wave. Can be controlled.

In this case, as described above, when the curvature of the incident light wave determined by the output distance d2 of the incident light wave is 0 (c _in = 0), the second hologram image B having the second focal length at the reference position is displayed. Can be observed.

That is, the third light source disposed to have a third output distance d3 from the lens 200 and the relative output distance is longer than the first light source 100_1 arranged to have the first separation distance d1 from the lens 200. When the second light source 100_2 having a relatively shorter output distance than 100_3 is selectively turned on, the overall focal length of the reproduction light wave may be formed at an average position from the hologram film 50. In this case, the second hologram image B of the hologram images A, B, and C having different focal lengths reproduced by the hologram film 50 may be reproduced at the reference position. Therefore, when the first light source 200_1 is turned on, the camera 300 fixedly disposed at the reference position may capture the first hologram image B. FIG.

In a similar manner, the measuring device 1 may turn on the third light source 100_3 to control the camera 300 disposed at the fixed position to capture the third hologram image C as shown in FIG. 6. Can be. Specifically, when the third light source 100_3 that is relatively far from the lens 200 is selectively turned on, the output distance d3 of the incident light wave is longer than the focal length f of the lens (d3> f), Since the curvature of the incident light wave is smaller than 0 (c _in <0), the overall focal length of the reproduction light wave may be formed at a relatively close position from the hologram film 50. In this case, the third hologram image C having a relatively long focal length among the hologram images A, B, and C having different focal lengths reproduced by the hologram film 50 may be reproduced at the reference position. Therefore, when the third light source 100_1 is turned on, the camera 300 fixedly disposed at the reference position may capture the third hologram image C. FIG.

In summary, when incident light waves are output from the first light source 100_1 located close to the midpoint of the lens 200, the camera 300 may observe a hologram image generated by the hologram film 50. When an image is obtained and incident light waves are output from the third light source 100_3 positioned far from the center of the lens 200, the camera 300 observes the hologram image generated by the hologram film 50 from a distance. An image of a viewpoint may be acquired.

That is, the measuring device 1 according to the present invention includes a plurality of light sources 100_1, 100_2, 100_3 constituting the light source array 100 to change the position of the overall focal length of the reproduction light wave according to the convergence degree of the incident light wave. By selectively turning on, the output position of the incident light wave can be varied. Therefore, unlike the playback image measuring method according to the related art shown in FIG. 1 described above, the measuring device 1 according to the present invention is a reference position on the optical axis by the light source (100_1, 100_2, 100_3) selectively lit By sequentially measuring the hologram image for a particular focal length that is selectively reproduced, all the focal length holographic images of the holographic image recorded on the holographic film 50 can be obtained at a fixed time point.

In this case, the measuring apparatus 1 may selectively light up the plurality of light sources 100_1, 100_2, and 100_3 constituting the light source array 100 in a predetermined order. For example, the measurement apparatus 1 sequentially turns on the first light source 100_1, the second light source 100_2, and the third light source 100_3, and then again the first light source 100_1 and the second light source 100_2. The third light source 100_3 can be turned on in the same order. As another example, the measurement apparatus 1 sequentially turns on the first light source 100_1, the second light source 100_2, and the third light source 100_3, and then the third light source 100_3, the second light source 100_2, The light source may be turned on in order of the first light source 100_1.

Alternatively, the measuring device 1 may light up the light sources selected one by one, not in a predetermined order.

Alternatively, the measuring apparatus 1 may preselect a light source to be sequentially turned on according to the characteristics of the image recorded on the hologram film 50 among all the light sources 100_1, 100_2, and 100_3 constituting the light source array 100, Only the light source can be turned on sequentially. For example, the measuring device 1 may collect information about a focal length of an image recorded on the hologram film 50 from an external device. The measuring device 1 analyzes the collected information and determines that the hologram film 50 provides only two hologram images for the first object having the first depth and the second object having the second depth. The first light source 100_1 capable of measuring the hologram image for the depth and the second light source 100_2 capable of measuring the hologram image for the second depth may be selected. Subsequently, the measuring device 1 may control only the selected first light source 100_1 and the second light source 100_2 to sequentially light up, not all the light sources included in the measuring device 1 in the hologram playback image measurement process. .

Meanwhile, in some other embodiments, the measuring device 1 analyzes the image photographed by the camera 300 and automatically determines whether the hologram image recorded on the hologram film 50 is normally recorded, thereby making it possible to obtain a hologram film ( The reliability of the interference fringe recorded in 50) can be measured.

In detail, the measurement device 1 may compare the pre-stored reference image with the image photographed by the camera 300 to determine whether the hologram image measured at a specific focal length is normally output. In this case, the measurement device 1 may calculate the similarity between the reference image and the captured image, and control to regenerate the captured image for the corresponding focal length when the calculated similarity is equal to or less than a predetermined threshold. For example, the measurement device 1 compares the photographed images of the first, second and third focal lengths of the hologram image with the reference image, and determines that the photographed images of the first and third focal lengths should be regenerated. can do.

In this case, the measuring apparatus 1 selectively turns on the other light sources 100_1 and 100_3 again except for the second light source 100_2 that outputs the incident light wave with respect to the second focal length of the reproduced image, thereby removing the first image of the hologram image. You can regenerate shots for 1 and 3 focal lengths.

In this process, when it is confirmed that the photographed image of the specific focal length is repeatedly generated more than the reference number of times, the measuring device 1 may generate a notification message for this and transmit the generated notification message to the terminal linked with the measuring device 1. Therefore, the user can automatically determine whether the interference fringe of the subject is normally recorded on the hologram film by using the measuring device 1 according to the present invention, and if it is determined that there is an abnormality in the hologram film, a notification message for this is given. Can be provided in real time.

7 is a flowchart illustrating a schematic flow of a method for measuring a holographic playback image according to an embodiment of the present invention.

The method for measuring a holographic reproduction image according to the present invention described below may be performed by the measuring device 1 having the configuration and function shown in FIG. 2.

The measuring device 1 may control the light source to be output from any one of the plurality of light source arrays according to a preset order (710).

The measuring device 1 specifies the hologram image generated by the hologram film 50 by photographing the reproduction light waves at a predetermined reference position on the optical axis among the reproduction light waves generated as the output incident light passes through the hologram film 50. An image viewed in depth may be measured (720). At this time, the measuring device 1 selectively turns on a plurality of light sources arranged to have different output distances and sequentially varies the focal lengths of the reproduction light waves formed at the reference positions, thereby fixing them at a fixed position (reference position) on the optical axis. The disposed camera 300 may control to generate a captured image of different focal lengths of the holographic image. Specific processes related to this have been described above with reference to FIGS. 3 to 6, and thus repeated descriptions thereof will be omitted.

If it is determined that the photographed images of all the light sources have been generated (YES of 730), the measuring device 1 ends the photographing process, but if it is confirmed that the photographed images of all the light sources have not been generated (NO of 730), the preset order is set. Reference to the search for the light source set in the following order (740), and returns to step 710 can be controlled to output the incident light wave from the searched light source.

In addition, the measuring device 1 operates the light source sequentially, and after the photographing process for all the focal lengths of the holographic image is finished, the photographed image generated by the camera 300 is compared with a pre-stored reference image to compare the holographic film ( The reliability of the interference fringe of the subject recorded in 50 can be measured.

Such a technology for providing a holographic reproduction image measuring method may be implemented in an application form or in the form of program instructions that may be executed through various computer components, and may be recorded in a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, etc. alone or in combination.

The program instructions recorded on the computer-readable recording medium are those specially designed and configured for the present invention, and may be known and available to those skilled in the computer software arts.

Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks and magnetic tape, optical recording media such as CD-ROMs, DVDs, and magneto-optical media such as floptical disks. media) and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like.

Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules to perform the process according to the invention, and vice versa.

Although described above with reference to the embodiments, those skilled in the art will understand that various modifications and changes can be made within the scope of the invention without departing from the spirit and scope of the invention as set forth in the claims below. Could be.

1: measuring device
50: hologram film
100: light source array
200: lens
300: camera

Claims (15)

A lens disposed at a position separated by a predetermined distance from the hologram film in which different hologram images are reproduced according to a viewing distance;
A light source array disposed along the optical axis of the lens and configured to have a different distance from the midpoint of the lens such that incident light waves having different output distances are output to the hologram film through the lens; ; And
Measuring a hologram image for a specific focal length reproduced by the hologram film by taking a reproduction light wave of the incident light passing through the hologram film, wherein the focal length of the reproduction light wave varies according to the output distance of the incident light wave A hologram playback image measuring apparatus using a variable convergence degree of incident light waves, including a camera for selectively measuring a star hologram image at a fixed position.
The method of claim 1,
Each light source constituting the light source array is arranged to have a different distance from the center of the lens, the interval between the light sources are arranged to be the same, the hologram playback image measuring apparatus using a method of varying the degree of convergence of incident light waves.
The method of claim 1,
A plurality of light sources constituting the light source array,
By using a method of varying the convergence degree of the incident light wave of the plurality of focal lengths of the reproduction light wave which is inversely proportional to the output distance of the incident light wave, the kind of focal length formed at the reference position on the optical axis is changed to be changed. Hologram playback image measuring device.
The method of claim 3,
The camera,
And a hologram image having a specific focal length formed at the reference position among the hologram images of the focal lengths of the reproduction light waves. The hologram image measuring apparatus using a variable convergence degree of incident light waves is fixed to the reference position.
The method of claim 4, wherein
The camera,
As the light source is selectively turned on, the hologram image for a specific focal length selectively formed at the reference position by incident light waves having different output distances is sequentially measured, and thus all focal points of the hologram image recorded on the holographic film are measured. A holographic reproduction image measuring apparatus using a sequential lighting method of a light source, which acquires an image of a distance from a fixed position.
The method of claim 1,
The lens is a hologram playback image measuring device using a variable convergence degree of incident light wave to change the incident light wave of the spherical wave form from the light source into a plane wave type incident light wave.
Controlling the incident light waves to be output from any one of a plurality of light sources arranged to output incident light waves at different output distances to the hologram film;
Measuring a hologram image for a specific focal length reproduced by the hologram film by photographing reproduction light waves of the incident light waves passing through the hologram film; And
Selectively lighting the plurality of light sources such that the hologram images for all focal lengths of the holographic images having different focal lengths along the optical axis are sequentially measured by a camera disposed at a predetermined reference position on the optical axis. Hologram playback image measuring method using a hologram playback image measuring apparatus.
The method of claim 7, wherein
Measuring the hologram image for the specific focal length,
Hologram playback image measurement using a hologram playback image measuring device, characterized in that for measuring a holographic image for a particular focal length formed at the reference position of the plurality of focal lengths of the reproduction light wave inversely proportional to the output distance of the incident light wave Way.
The method of claim 8,
Measuring a hologram image with respect to a specific focal length formed at the reference position among a plurality of focal lengths of the reproduction light waves in inverse proportion to the output distance of the incident light waves,
From a lens disposed at a position spaced apart from the hologram film by a predetermined distance so that a first hologram image having a relatively short focal length is formed at the reference position among all focal lengths of the reproduction light waves formed at a specific position from the hologram film. Selectively lighting the first light source located at a relatively close distance,
A second hologram image having a relatively long focal length among all focal lengths of the reproduction light waves formed at a specific position from the hologram film, is formed at the reference position so as to be relatively far from the lens than the first light source; A hologram playback image measuring method using a hologram playback video measuring device, characterized in that the light source is selectively lit.
The method of claim 7, wherein
Selectively lighting the plurality of light sources,
By sequentially measuring a hologram image for a specific focal length selectively reproduced at the reference position for each light source selectively lit, acquiring images of all the focal lengths of the hologram image recorded on the hologram film at the reference position. A holographic reproduction image measuring method using a holographic reproduction image measuring apparatus, characterized in that.
The method of claim 7, wherein
And sequentially illuminating all light sources constituting the light source array, and comparing the hologram image for a specific focal length measured by the camera with a pre-stored reference image to calculate a similarity. Hologram playback image measurement method using the.
The method of claim 11,
Calculating the similarity,
When at least one holographic image determined that the similarity is less than a threshold value is extracted, a light source operated in the process of generating the extracted holographic image is searched for a holographic reproduced image measuring method using a holographic reproduced image measuring device. .
The method of claim 12,
And sequentially operating the at least one light source found in the calculating of the similarity among all the light sources constituting the light source array, so that the hologram image determined to have the similarity less than the threshold value is reproduced. Hologram playback image measuring method using a hologram playback image measuring device.
delete A computer-readable recording medium having a computer program recorded thereon for performing a hologram playback image measuring method using the hologram playback image measuring apparatus according to any one of claims 7 to 13.

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