KR20180029595A - Device for obtaining hologram image using lens assembly and apparatus for restructuring shape of object with the device - Google Patents

Abstract

The present invention suggests a device for obtaining a hologram image using a lens assembly and an apparatus for restructuring a shape of an object including the same, which convert spherical wave shaped object light into plane wave shaped light by using the lens assembly such as a tube lens to obtain a hologram image. According to the present invention, the device comprises: a lens assembly for converting spherical wave shaped object light into plane wave shaped light; a light dividing part for diving the plane wave shaped light into first light and second light to reflect the first light and transmit the second light; a light reflection part for reflecting the transmitted second light in the same direction as the first light; and a hologram image acquiring part for acquiring a hologram image on an object based on the combination of the first light and the second light.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hologram image acquiring apparatus using a lens assembly, and an apparatus for reconstructing a three-dimensional shape of an object having the hologram image acquiring apparatus.

The present invention relates to an apparatus for acquiring a hologram image. And more particularly, to an apparatus for acquiring a hologram image using a lens assembly. The present invention also relates to an apparatus for reconstructing the three-dimensional shape of an object based on the obtained hologram image.

Conventionally, in order to reconstruct the three-dimensional shape of an object, an object hologram having information on the object and a reference hologram having no information on the object are sequentially acquired, and then the phase difference between the object hologram and the reference hologram is used The three-dimensional shape of the object was restored.

However, such a method has a problem that the performance of the system is not constant due to an error that may occur due to time delay in acquiring the object hologram and the reference hologram. Also, there is a problem that the three-dimensional shape of the object is incompletely restored.

(Prior Art 1) Korean Patent No. 1,573,362 (entitled " High-speed Flexible Digital Hologram Generation Method and Apparatus "

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a hologram image acquiring apparatus for converting a spherical object light into a plane wave light by using a lens assembly such as a tube lens, Dimensional shape reconstruction apparatus of the present invention.

However, the objects of the present invention are not limited to those mentioned above, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention provides a lens assembly for converting an object beam of a spherical wave into light of a plane wave type; A light splitting unit splitting the plane wave light into first light and second light to reflect the first light and transmit the second light; A light reflection part for reflecting the transmitted second light in the same direction as the traveling direction of the first light; And a hologram image acquiring unit for acquiring a hologram image of an object based on the combination of the first light and the second light.

Preferably, the lens assembly includes: a first lens that converts the spherical-wave-shaped object light into convergent light; And a second lens for converting the converged light into parallel light.

Preferably, the lens assembly is formed of a tube lens.

Preferably, the hologram image acquiring device includes an interference fringe region associated with the hologram image, wherein the object region including information on the object is formed in an overlapping region between reference regions that do not include information on the object, And a light reflection part controller for controlling the light reflection part.

Preferably, the light reflector controller controls the light reflector by adjusting a tilt of the light reflector based on position information and size information of the object.

Preferably, the light reflection controller controls the light reflection unit to prevent the second light from combining with the first light, and when the size of the object is calculated on the basis of the first light, To adjust the inclination of the light reflection portion.

Preferably, the hologram image acquiring apparatus includes a first light converting unit for converting predetermined light into object light of the spherical wave type; And an object size calculating unit for calculating the size of the object, wherein the object size calculating unit calculates the object size based on the size of the pixels constituting the image obtained on the basis of the first light and the lens magnification of the first light converting unit, .

Preferably, the light reflection controller determines a measurable range of the object before controlling the light reflection to prevent the second light from combining with the first light.

Preferably, the light reflector controller determines a measurable range of the object based on a result obtained by comparing the distance between the centers of the reference areas and the radius of the reference area.

Preferably, when the distance between the centers of the reference regions is greater than the radius of the reference region, the light reflection unit controller multiplies the radius of the reference region by 2, minus the distance between the centers of the reference regions Determining a measurable range of the object on the basis of the distance between the centers of the reference regions and determining the distance between the centers of the reference regions is less than the radius of the reference region, .

Preferably, the light reflector controller controls the light reflector before acquiring the hologram image.

Preferably, the hologram image acquiring apparatus includes: a light generator for generating and outputting light; A noise removing unit for removing noise from the output light; And a first light converting unit for converting the light having passed through the object into the spherical object light when the noise-canceled light passes through the object.

Preferably, the noise removing portion is formed of a rotatable diffuser plate.

Preferably, the hologram image acquiring apparatus further includes a second light converting unit that converts the noise-removed light into parallel light before passing through the object.

Preferably, the second light converting part is formed as a collimator.

Preferably, the noise removing unit removes speckle noise with the noise.

Preferably, the hologram image acquiring apparatus includes: a light generator for generating and outputting light; A light size adjusting unit for adjusting the size of the output light; And a first light converting unit converting the light having passed through the object into the spherical object light when the size-adjusted light passes through the object.

Preferably, the hologram image acquiring apparatus includes: a noise removing unit that removes noise from the output light using a rotatable diffusion plate; And a second light converting unit for converting the noise-removed light into parallel light, and the light-size adjusting unit adjusts the size of the light converted into the parallel light when the output light is converted into the parallel light.

Preferably, the light-size adjusting unit adjusts the size of the output light based on the size of the hole formed in the first light-converting unit.

The present invention also relates to a lens assembly for converting an object light of a spherical wave type into light of a plane wave type; A light splitting unit splitting the plane wave light into first light and second light to reflect the first light and transmit the second light; A light reflection part for reflecting the transmitted second light in the same direction as the traveling direction of the first light; A hologram image acquiring unit acquiring a hologram image of an object based on the combination of the first light and the second light; And a three-dimensional reconstruction unit for reconstructing a three-dimensional shape of the object based on the hologram image.

The present invention can achieve the following effects through the above-described configurations.

First, the three-dimensional shape of the object can be restored by only the hologram of the object without the reference hologram.

Second, the three-dimensional shape of an object can be more completely restored than when using both an object hologram and a reference hologram.

FIG. 1 is a conceptual diagram of a single shot transmission single optical path demagnetizing digital holographic microscope system according to an embodiment of the present invention.
2 is a reference diagram for explaining the effective interference fringe region.
FIG. 3 is a conceptual view schematically showing an internal configuration of a tube lens constituting a single shot transmission type single optical path demagnetizing digital holographic microscope system.
4 is a reference diagram for explaining angle control of an optical mirror for obtaining an effective interference fringe.
5A is a reference diagram for explaining a method of calculating an effective interference fringe region.
5B is a reference diagram for explaining a method of calculating the maximum measurable object size range according to an embodiment of the present invention.
6 is a flow chart illustrating a procedure for determining the maximum measurable size of an object.
FIG. 7 is a flowchart schematically illustrating a method of restoring a three-dimensional shape of an object according to an embodiment of the present invention.
FIG. 8 is a block diagram schematically showing an internal configuration of a hologram image acquiring apparatus according to a preferred embodiment of the present invention.
9 is a block diagram illustrating an internal configuration that can be added to the hologram image acquisition apparatus of FIG.
FIG. 10 is a block diagram schematically showing an internal configuration of an apparatus for restoring a three-dimensional object according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

An interferometer is a mechanism that divides the light from the same light source into two or more beams to make a difference in the propagation path, and then observes the interference phenomenon that occurs when the light meets again. Mach-Zender interferometer, Michelson interferometer, etc., are complicated in system configuration and vulnerable to vibration. Therefore, in the past, a large number of lateral shearing interferometers were used to generate hologram images. However, in the hologram image acquired through the shear interferometer, the shape of the same object is doubly overlapped, and the phase information of the object is distorted at the overlapped portion.

On the other hand, conventionally, a three-dimensional shape of an object is restored by using a phase difference between an object hologram (i.e., a hologram having information on the object) and a reference hologram (i.e., a hologram having no information on the object). However, such a method has a problem in that the performance of the system is not constant due to an error that may occur according to the time delay in acquiring the object hologram and the reference hologram. As a result, the three-dimensional shape of the object is incompletely reconstructed There is also a problem.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to solve the problem that the shape of an object appears to be double and to recover a three-dimensional shape of an object with only one object hologram image, (Single-shot transmission-type one-arm off-axis digital holographic microscopy).

A digital holographic microscope is a microscope that acquires hologram information (interference fringes) through a digital imaging device based on a holography technique and measures three-dimensional shape information of the object through the holographic information.

If a general microscope is a device that measures the shape of an object by measuring the intensity distribution of light reflected or transmitted from an object by irradiating the ordinary light source to the object, the digital holographic microscope can detect the interference of light that occurs when a plurality of lights meet Dimensional shape information of the target object by using the interference fringe information in the form of interference fringes, extracting the phase information from the acquired interference fringe information, and using the extracted phase information.

In other words, digital holography technology generates light of a single wavelength such as a laser, divides it into two lights using a light splitter, and directs one light (reference light) directly to the image sensor, ), When the light reflected by the object to be measured is reflected on the image sensor, (4) the reference light and the object light cause interference in the image sensor, (5) the interference fringe information of such light is recorded by the digital image sensor, This is a technique for restoring the shape of an object to be measured by using a computer with interference fringe information. At this time, the interference fringe information recorded according to (5) above is referred to as a normal hologram.

On the other hand, in the case of the conventional optical holography technology, which is not digital holography, the procedure from ① to ④ is the same, but in order to record the interference fringe information of light in ⑤ and restore the shape of the object in ⑥ When the reference light is projected on a special film on which interference fringes are recorded, the shape of the virtual object to be measured is restored to the position where the original object is located.

The digital holographic microscope measures the interference fringe information of the light with the digital image sensor, digitally encodes it, and stores the stored interference fringe information in a computer device There is a difference in that the shape of the object to be measured is restored by processing by an arithmetic method.

The present invention restores the three-dimensional shape of an object using only the object hologram using a digital holographic microscope. To this end, the present invention proceeds in the following order.

First, the light from the laser passes through the object and passes through the objective lens. The tilt angle of the optical mirror is adjusted according to the position and the size of the object, thereby dividing the object area into the object area and the object-free reference area. The light passing through the objective lens is transformed into a plane wave shape after passing through the tube lens, and is divided into light reflected by the optical splitter and light transmitted through the objective lens. The transmitted light is reflected by the optical mirror, . The interference fringes formed at this time are acquired through the CCD.

The system proposed in the present invention can be restored by using only one object hologram. That is, the light after the tube lens has passed through the objective lens is changed from the spherical wave to the plane wave, so that the reconstruction is possible without the reference hologram. The detailed reconstruction process extracts the phase information from the object hologram acquired through the system proposed in the present invention, and then calculates the phase information as the three-dimensional shape information of the measurement object.

FIG. 1 is a conceptual diagram of a single shot transmission single optical path demagnetizing digital holographic microscope system according to an embodiment of the present invention.

The system 100 proposed in FIG. 1 is a single shot transmission type single optical path demultiplexing digital holographic microscope system, in which a shape of an object is not duplicated and a three-dimensional shape information can be restored with only a single object hologram System.

The light source unit 111 performs a function of generating and outputting light (light). In the present invention, the light source unit 111 may be formed of a laser.

When the light output from the light source unit 111 is input, the rotation diffusion plate 112 performs a function of removing speckle noise from the light. Speckle noise is one of the characteristics of a laser light source. Such speckle noise acts as noise in measuring the shape of an object, which can have a considerable adverse effect on accurately restoring the three-dimensional shape of the object. Therefore, in the present invention, the speckle noise is removed from the light output by the light source unit 111 using the rotation diffusion plate 112.

The collimator 113 performs a function of deforming the light of the form of diverging when the speckle-free light is input by the rotation diffuser plate 112 into a parallel beam shape.

The beam cutter 114 functions to adjust the size of the parallel beam deformed by the collimator 113. The beam cutter 114 adjusts the size of the beam to be incident on the objective lens 116 in accordance with the aperture of the objective lens 116.

The objective lens 116 performs a function of converting a beam whose size has been adjusted by the beam cutter 114 through the object 115 into an object beam having a spherical wave form.

The tube lens 117 functions to convert spherical-shaped object light having passed through the objective lens 116 into plane-wave-shaped light. As shown in FIG. 3, the tube lens 117 may have a structure in which the first lens 310 and the second lens 320 are combined. FIG. 3 is a conceptual view schematically showing an internal configuration of a tube lens constituting a single shot transmission type single optical path demagnetizing digital holographic microscope system.

The object light having passed through the objective lens 116 travels in the form of light to be emitted. The first lens 310 functions to focus the object light. The first lens 310 may be embodied as a condensing lens, for example.

The second lens 320 functions to convert the object light having passed through the first lens 310 into a parallel beam. In the present invention, such a second lens 320 may be embodied as a convex lens.

Referring back to FIG.

The tube lens 117 has the effect of reducing the distortion of the two-dimensional image in terms of geometrical optics. In addition, the tube lens 117 can obtain the following effects on the hologram side.

The object light having passed through the objective lens 116 is a spherical wave type light including a phase error or a phase aberration. Conventionally, a hologram image (reference hologram) was obtained in the absence of an object, and the phase error was canceled through the phase difference between the reference hologram and the object hologram. However, this method has the disadvantage that the performance of the system is not constant due to the errors that can be caused by the time delay in acquiring the object hologram and the reference hologram.

On the other hand, in the present invention, the potential problem is solved by converting the spherical object light into the plane wave light by using the tube lens 117, and at the same time, the three-dimensional shape of the object without the reference hologram It is possible to restore it accurately.

The light splitter 118 functions to divide the light that has passed through the tube lens 117. The first one of the lights split by the optical splitter 118 is reflected from the optical splitter 118 and is incident on a CCD (Charge Coupled Device) 121, and the second light is transmitted through the optical splitter 118 to form an optical mirror 119).

The optical mirror 119 reflects the second light and makes it incident on the CCD 121. The second light is combined with the first light in front of the CCD 121 by being reflected from the optical mirror 119 to generate the interference fringe 124.

The CCD 121 performs the function of acquiring the generated interference fringe 124. [

The computer 123 performs a function of restoring the three-dimensional shape of the object 115 based on the interference fringe 124. [ The computer 123 calculates the quantitative size information of the object 115 based on the hologram image (object hologram) acquired by the CCD 121, and then restores the three-dimensional shape of the object 115. [

The controller 122 functions to adjust the tilted angle of the optical mirror 119 to set an effective reference area according to the position and size of the object 115 to be measured. The controller 122 may be connected to the computer 123 and may perform the above-described functions under the control of the computer 123.

By minimizing the phase error included in the object hologram using the tube lens 117, the present invention eliminates the need for a reference hologram unlike the existing system. The object beam passing through the tube lens 117 is divided into light reflected by the surface of the light splitter 118 and light transmitted by the light splitter 118. At this time, the transmitted light is reflected by the optical mirror 119 and overlapped in front of the CCD 121 with the light reflected by the optical splitter 118 to form an interference fringe. At this time, the controller 122 adjusts the angle of the optical mirror 119 located on the rear surface of the light splitter 118 to adjust the effective interference fringe region generated by the object region and the reference region.

The area of the effective interference fringe will be described with reference to Fig. 2 is a reference diagram for explaining the effective interference fringe region.

The object light that has passed through the tube lens 117 is reflected by the light splitter 118 and travels to the CCD 121 or is transmitted through the optical splitter 118 and then reflected by the optical mirror 119, . Referring to FIG. 2, the first light reflected by the light splitter 118 includes a region R1 (Reference 1) and a region O1 (Object 1). Also, the second light reflected by the optical mirror 119 includes an R2 (Reference 2) region and an O2 (Object 2) region. In the above, the R1 area and the R2 area refer to a reference area that does not include information on an object, and the O1 area and the O2 area refer to an object area including information about the object (210, 220).

The first light and the second light are combined in front of the CCD 121 to form an interference fringe. However, in the case where the overlap region 230 is generated by the O1 region of the first light and the R2 region of the second light, in order to form a desired interference fringe in the present invention, the information 210 about the object included in the O1 region is divided into the overlap region 230). That is, in the present invention, the effective interference fringe refers to an interference fringe in which information 210 about an object is contained in the overlapping region 230, and the interference fringe region is defined as an effective fringe region. In addition, the controller 122 controls the angle of the optical mirror 119 so that the information about the object 210 can be included in the overlapping area 230.

4 is a reference diagram for explaining angle control of an optical mirror for obtaining an effective interference fringe.

The position of the CCD 121 for obtaining the effective interference fringe can be defined as shown in Equation (1).

In the above, 1 denotes the position of the CCD 121 for obtaining the effective interference fringe. r denotes the radius of object light incident on the optical splitter 118, and t denotes the distance between the optical splitter 118 and the optical mirror 119. t is a value considered by the object light that is reflected by the optical mirror 119 after passing through the light splitter 118. [ ? ₁ denotes the incident angle of the object light when the object light is reflected by the optical splitter 118 and? ₂ denotes the incident angle of the object light passing through the optical splitter 118 when the object light transmitted through the optical splitter 118 is reflected by the optical mirror 119 Means the incident angle of light.

The interference angle formed by each light reflected by the optical splitter 118 and the optical mirror 119 can be defined as shown in Equation (2).

In the above,? _{1 -} ? ₂ denotes an interference angle between the object light reflected by the optical splitter 118 and the object light reflected by the optical mirror 119. d denotes the distance between the center point of the object light reflected by the light splitter 118 and the center point reflected by the optical mirror 119. [ T ₁ means the distance between the optical splitter 118 and the optical mirror 119.

As described above, in the present invention, the object region (O1 region) reflected by the light splitter 118 and the reference region (R2 region) reflected by the optical mirror 119 are formed according to the interference angle obtained in Equation The area of the interference fringe can be adjusted, which is called the effective fringe area. The effective interference fringe region can be defined as shown in Equation (3).

5A is a reference diagram for explaining a method of calculating an effective interference fringe region. The following description refers to Figure 5A.

In the above, S _eff means an effective interference fringe region. Further,? _T denotes an angle formed by the first line (the line connecting the point A and the point B) and the second line (the line connecting the point A and the point C). The point A represents a center point of the object light reflected by the optical splitter 118 and the point C represents an interference phenomenon between the object light reflected by the optical splitter 118 and the object light reflected by the optical mirror 119 And the center point of the object formed in the overlap area. The point B represents the intersection of two object light beams when an interference phenomenon occurs between the object light reflected by the light splitter 118 and the object light reflected by the optical mirror 119.

In the present invention, the optimum object hologram can be obtained by adjusting the inclination of the optical mirror 119 based on the effective interference fringe region obtained through Equation (3). Also, in the present invention, the obtained object hologram is transmitted to the computer 123, and the three-dimensional shape (three-dimensional shape) of the object can be accurately restored by using only one object hologram without the reference hologram. The tilt adjustment of the optical mirror 119 can be performed by the controller 122, at which time the controller 122 can adjust the tilt of the optical mirror 119 according to the size of the object to be measured.

In the present invention, before acquiring the object hologram using the digital holographic microscope, the inclination angle of the optical mirror 119 may be adjusted according to the size and position of the object in order to secure the effective reference area. This will be described below.

In the present invention, the diameter of the effective reference area should be larger than the diameter of the object for securing the effective interference area. In the present invention, the following pre-processing is performed to make the diameter of the effective reference area larger than the diameter of the object to be measured.

First, the diameter of the object light passing through the object 115, the objective lens 116, and the tube lens 117 in turn is measured in the system 100.

Then, the maximum measurable object size range according to the diameter of the object light is calculated according to the following formula.

If the distance d between the centers of object light is larger than the radius r of object light (d> r): Maximum measurable object size range = 2r-d

Ⓑ When the distance (d) between the centers of object light is less than or equal to the radius (r) of the object light (O ≤ d ≤ r): Maximum measurable object size range = d

Where r is the radius of the object light and d is the diameter of the area where the object light overlaps.

The formulas for determining the maximum measurable object size range can be divided into two cases as follows. 5B is a reference diagram for explaining a method of calculating the maximum measurable object size range according to an embodiment of the present invention.

First, when the distance between the centers of the object light beams is larger than the radius of the object light beam (d> r) as shown in FIG. 5B, the diameter of the interference region can be defined as 2r-d. However, as shown in (c) of FIG. 5 (b), the size of the object to be measured can not exceed 2r-d in diameter, so the maximum measurable object size is 2r-d.

Second, as shown in FIG. 5B, when the distance between the centers of the object light beams becomes equal to the radius of the object light beam from 0 (when the two object light beams are exactly matched) (0? D? R) , And the diameter of the interference region can be similarly defined as 2r-d. However, in this case, when the size of the object is set to be the same as the case of the preceding case, the objects are overlapped as shown in (d) of FIG. Therefore, to solve the double-phase problem, the maximum measurable object size is defined as d.

6 is a flow chart illustrating a procedure for determining the maximum measurable size of an object. The following description refers to Fig.

The slope of the optical mirror 119 is adjusted so that only the object light reflected by the optical splitter 118 is incident on the CCD camera 121 (S410). Specifically, after the object light reflected by the optical mirror 119 is adjusted so as not to be incident on the CCD 121, only the object light reflected by the optical splitter 118 is incident on the CCD 121.

Thereafter, an image of the object is acquired based on the object light incident on the CCD 121 (S420).

Then, the object size in the two-dimensional plane direction is calculated in consideration of the pixel size of the CCD 121 and the magnification of the objective lens 116 through the image of the object incident on the CCD 121 (S430).

Then, the angle of the optical mirror 119 is adjusted in consideration of the measured diameter of the object (S440). That is, the distance between the centers of object light is adjusted according to the size of the object, and at the same time, the effective interference region is adjusted.

The structure and operation method of the digital holographic microscope system according to an embodiment of the present invention has been described with reference to FIGS. 1 to 6. FIG. Hereinafter, a method for reconstructing a three-dimensional shape of an object using a digital holographic microscope system according to an embodiment of the present invention will be described.

FIG. 7 is a flowchart schematically illustrating a method of restoring a three-dimensional shape of an object according to an embodiment of the present invention. The following description refers to Fig.

First, the system 100 controls the angle of the optical mirror 119 to set an effective reference area (S510).

Then, the system 100 obtains the object hologram (S520).

Then, the system 100 acquires the phase information of the object hologram (S530).

Then, the system 100 obtains the quantitative size information of the object based on the phase information of the object hologram, and restores the three-dimensional shape of the object based on the quantitative size information (S540).

The computer 123 may operate in the following order when restoring the three-dimensional shape of the object. Please refer to Fig. 7 below.

First, the computer 123 obtains the object hologram including the measurement object from the CCD 121 (S520). The obtained object hologram can be expressed as a complex conjugate hologram as follows.

U (x, y, 0)

In the above, U (x, y, 0) denotes the three-dimensional spatial coordinate of the object hologram.

Then, the computer 123 acquires information on the object to be measured through the two-dimensional Fourier transform and filtering using the object hologram, and extracts the phase information of the object through each spectral method and two-dimensional inverse Fourier transform (S530 ). This can be expressed by the following equation (4).

In the above,? (X, y) denotes the phase information of the object hologram. Re [φ (x, y)] and Im [φ (x, y)] represent the real and imaginary parts of the object hologram, respectively.

Since the distortion information by the objective lens 116 is minimized in the phase information of the object extracted in the step S530, it is possible to reconstruct the three-dimensional shape of the object using only the object hologram.

The computer 123 then applies a phase spreading algorithm to compensate for phase discontinuity or phase ambiguity that occurs during the measurement of the size of the object beyond the wavelength of the light source used in the system 100. Thereafter, the computer 123 converts the compensated phase information into quantitative thickness information of an object to be measured (S540). The converted thickness information is expressed by the following equation (5).

In the above,? L means thickness information of an object. ? denotes the wavelength of the laser, and? n (x, y) denotes the refractive index difference.

Thereafter, the computer 123 restores the three-dimensional shape of the object using the converted size information (S540).

According to the method described with reference to FIG. 7, the following effects can be obtained.

First, it is possible to construct a system which is robust and simpler than the digital holographic microscope proposed in the past.

Second, it is possible to extract the phase information of an object with a single object hologram, and to accurately reconstruct the three-dimensional shape of the object.

Third, it is possible to solve the problem that the shape of the same object appears double by adjusting the position of the object and the effective interference region.

1 to 7, an embodiment of the present invention has been described. Best Mode for Carrying Out the Invention Hereinafter, preferred forms of the present invention that can be inferred from the above embodiment will be described.

FIG. 8 is a block diagram schematically showing an internal configuration of a hologram image acquiring apparatus according to a preferred embodiment of the present invention. And FIG. 9 is a block diagram illustrating an internal configuration that can be added to the hologram image acquisition apparatus of FIG.

8, the hologram image acquisition apparatus 600 includes a lens assembly 610, a light splitting unit 620, a light reflection unit 630, and a hologram image acquisition unit 650.

The lens assembly 610 performs a function of converting an object beam of a spherical wave form into light of a plane wave type. In this embodiment, the lens assembly 610 corresponds to the tube lens 117 of FIG. That is, the lens assembly 610 may be formed of a tube lens.

The lens assembly 610 may include a first lens 611 and a second lens 612. The first lens 611 functions to convert object light of a spherical wave form into converged light. The second lens 612 functions to convert the converged light converted by the first lens 611 into parallel light.

The light splitter 620 divides the plane-wave-shaped light into the first light and the second light, and reflects the first light and transmits the second light. In this embodiment, the light splitter 620 corresponds to the light splitter 118 of FIG.

The light reflecting portion 630 reflects the transmitted second light in the same direction as the traveling direction of the first light. In this embodiment, the light reflecting portion 630 corresponds to the optical mirror 119 in Fig.

The hologram image acquisition unit 650 acquires a hologram image of an object based on the combination of the first light and the second light reflected in the same direction. The hologram image acquiring unit 650 in this embodiment is a concept corresponding to the CCD 121 in Fig.

The hologram image acquiring apparatus 600 may further include a light reflector controller 640 as shown in FIG.

The light reflector controller 640 controls the light reflector 630 such that an object region including information on the object is formed in an overlapping area between the reference areas that do not include information on the object in the interference fringe area related to the hologram image, As shown in FIG. In this embodiment, the light reflector controller 640 corresponds to the controller 122 of FIG.

The light reflector controller 640 can control the light reflector 630 by adjusting the inclination of the light reflector 630 based on the position information and size information of the object.

The light reflector controller 640 controls the light reflector 630 to prevent the second light from coupling with the first light. When the size of the object is calculated based on the first light, It is possible to adjust the inclination of the slider 630.

The light reflector controller 640 can determine the measurable range of the object before controlling the light reflector 630 to prevent the second light from combining with the first light.

The light reflector controller 640 can determine the measurable range of the object based on the result obtained by comparing the distance between the centers of the reference areas and the radius of the reference area.

If it is determined that the distance between the centers of the reference regions is larger than the radius of the reference region, the light reflection unit controller 640 calculates the distance between the centers of the reference regions by subtracting the distance between the centers of the reference regions from the value obtained by multiplying the radius of the reference region by 2, Can be determined. On the other hand, if it is determined that the distance between the centers of the reference areas is smaller than the radius of the reference area, the light reflector controller 640 can determine the measurable range of the object based on the distances between the centers of the reference areas.

The light reflector controller 640 may control the light reflector 630 before acquiring the hologram image.

The hologram image acquiring apparatus 600 may further include a first light converting unit 750 and an object size calculating unit 660 as shown in FIGS.

The first light converting unit 750 performs a function of converting predetermined light into spherical object light. The predetermined light is generated and outputted by the light generating unit 710 and then transmitted through the noise removing unit 720, the second light converting unit 730, the light size adjusting unit 740, . In this embodiment, the first light converting portion 750 corresponds to the objective lens 116 in Fig.

The object size calculating unit 660 calculates the size of the object. The object size calculating unit 660 calculates the size of the object based on the size of the pixels constituting the image obtained based on the first light and the lens magnification of the first light converting unit 750. In this embodiment, the object size calculating unit 660 corresponds to the CCD 121 of FIG.

The hologram image acquiring apparatus 600 may further include a light generating unit 710, a noise removing unit 720, and a first light converting unit 750 as shown in FIG.

The light generating unit 710 performs a function of generating and outputting light. In this embodiment, the light generating unit 710 corresponds to the light source unit 111 of FIG.

The noise removing unit 720 performs a function of removing noise from the light output by the light generating unit 710. In this embodiment, the noise remover 720 corresponds to the rotation diffuser plate 112 of FIG. That is, the noise removing unit 730 may be formed as a rotatable diffuser plate (plate that functions to diffuse light).

The noise removing unit 720 can remove speckle noise with noise.

The first light converting unit 750 converts the light passing through the object into the spherical object light when the noise-canceled light passes through the object. In this embodiment, the first light converting portion 750 corresponds to the objective lens 116 in Fig.

In the case where the hologram image acquiring apparatus 600 further includes a light generating unit 710, a noise removing unit 720 and a first light converting unit 750, And may further include a second light converting portion 730 as well.

The second light converting unit 730 performs a function of converting the noise-removed light into parallel light before passing through the object. In this embodiment, the second light converting unit 730 is a concept corresponding to the collimator 113 of FIG. That is, the second light converting part 730 may be formed as a collimator.

The hologram image acquisition apparatus 600 may further include a light generating unit 710, a light size adjusting unit 740, and a first light converting unit 750 as shown in FIG.

The light size adjuster 740 adjusts the size of the light output by the light generator 710. In this embodiment, the optical size adjuster 740 corresponds to the beam cutter 114 of FIG.

The first light converting unit 750 converts light having passed through the object into spherical-shaped object light when the size-adjusted light passes through the object.

In the case where the hologram image acquiring apparatus 600 further includes a light generating unit 710, a light size adjusting unit 740 and a first light converting unit 750, And may further include a noise removing unit 720 and a second light converting unit 730 as shown in FIG.

The noise removing unit 720 performs a function of removing noise from the light output by the light generating unit 710 using a rotatable diffuser plate.

The second light converting unit 730 performs a function of converting the noise-removed light into parallel light.

The hologram image obtaining apparatus 600 further includes a noise removing unit 720 and a second light converting unit 730 in addition to the light generating unit 710, the light size adjusting unit 740 and the first light converting unit 750 The light size adjuster 740 can adjust the size of the light converted into the parallel light when the light output by the light generator 710 is converted into parallel light.

The light-size adjusting unit 740 may adjust the size of the output light based on the size of the hole formed in the first light-converting unit 750.

FIG. 10 is a block diagram schematically showing an internal configuration of an apparatus for restoring a three-dimensional object according to a preferred embodiment of the present invention.

Referring to FIG. 10, an object reconstruction apparatus 800 includes a hologram image acquisition apparatus 600 and a three-dimensional reconstruction unit 810.

Since the hologram image acquiring device 600 has been described above with reference to Figs. 8 and 9, a detailed description thereof will be omitted here.

The three-dimensional shape restoring unit 810 restores the three-dimensional shape of the object based on the hologram image obtained by the hologram image obtaining unit 650. [ In this embodiment, the three-dimensional shape restoring unit 810 corresponds to the computer 123 of FIG.

The three-dimensional shape restoration unit 810 extracts the phase information of the object from the hologram image, and reconstructs the three-dimensional shape of the object based on the phase information of the object.

It is to be understood that the present invention is not limited to these embodiments, and all elements constituting the embodiment of the present invention described above are described as being combined or operated in one operation. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. In addition, although all of the components may be implemented as one independent hardware, some or all of the components may be selectively combined to perform a part or all of the functions in one or a plurality of hardware. As shown in FIG. In addition, such a computer program may be stored in a computer readable medium such as a USB memory, a CD disk, a flash memory, etc., and read and executed by a computer to implement an embodiment of the present invention. As the recording medium of the computer program, a magnetic recording medium, an optical recording medium, a carrier wave medium, and the like can be included.

Furthermore, all terms including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined in the Detailed Description. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

It will be apparent to those skilled in the art that various modifications, changes, and substitutions are possible, without departing from the essential characteristics and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (20)

A lens assembly for converting an object beam of a spherical wave form into light of a plane wave type;
A light splitting unit splitting the plane wave light into first light and second light to reflect the first light and transmit the second light;
A light reflection part for reflecting the transmitted second light in the same direction as the traveling direction of the first light; And
A hologram image acquiring unit for acquiring a hologram image for an object based on the coupling of the first light and the second light,
And a hologram image acquiring unit for acquiring hologram image information. The method according to claim 1,
The lens assembly includes:
A first lens for converting the spherical-wave-shaped object light into convergent light; And
A second lens for converting the converged light into parallel light,
And a hologram image acquiring unit for acquiring hologram image information. The method according to claim 1,
Wherein the lens assembly is formed of a tube lens. The method according to claim 1,
And a light reflection unit controller for controlling the light reflection unit such that an object region including information on the object is formed in an overlap area between reference areas that do not include information on the object in an interference fringe area associated with the hologram image,
Further comprising: a light source for generating a holographic image; 5. The method of claim 4,
Wherein the light reflector controller controls the light reflector by adjusting a tilt of the light reflector based on position information and size information of the object. 6. The method of claim 5,
Wherein the light reflection controller controls the light reflection unit to prevent the second light from combining with the first light and, when the size of the object is calculated on the basis of the first light, And the inclination of the negative portion is adjusted. The method according to claim 6,
A first light converting unit for converting predetermined light into object light of the spherical wave type; And
An object size calculating unit for calculating the size of the object,
Further comprising:
Wherein the object size calculating unit calculates the size of the object based on a size of a pixel constituting an image obtained based on the first light and a lens magnification of the first light converting unit. The method according to claim 6,
Wherein the light reflector controller determines a measurable range of the object before controlling the light reflector so that the second light does not combine with the first light. 9. The method of claim 8,
Wherein the light reflector controller determines a measurable range of the object based on a result obtained by comparing the distance between the centers of the reference areas and the radius of the reference area. 10. The method of claim 9,
Wherein the light reflector controller determines that the distance between the centers of the reference areas is greater than the radius of the reference area, based on a value obtained by multiplying the radius of the reference area by 2 and subtracting the distance between the centers of the reference areas Determining a measurable range of the object and determining a measurable range of the object based on the distance between the centers of the reference regions if the distance between the centers of the reference regions is less than the radius of the reference region And a hologram image acquiring device. 5. The method of claim 4,
Wherein the light reflector controller controls the light reflector before acquiring the hologram image. The method according to claim 1,
A light generator for generating and outputting light;
A noise removing unit for removing noise from the output light; And
A first light converting unit for converting the light having passed through the object into the spherical object light when the noise-
Further comprising: a light source for generating a holographic image; 13. The method of claim 12,
Wherein the noise removing unit is formed of a rotatable diffusion plate. 14. The method of claim 13,
A second light converting unit for converting the noise-removed light into parallel light before passing through the object,
Further comprising: a light source for generating a holographic image; 15. The method of claim 14,
Wherein the second light converting unit is formed as a collimator. 13. The method of claim 12,
Wherein the noise removing unit removes speckle noise from the noise. The method according to claim 1,
A light generator for generating and outputting light;
A light size adjusting unit for adjusting the size of the output light; And
And a first light conversion unit for converting the light having passed through the object into the spherical wave type object light when the size-adjusted light passes through the object,
Further comprising: a light source for generating a holographic image; 18. The method of claim 17,
A noise eliminator for removing noise from the output light using a rotatable diffusion plate; And
And a second light-converting section for converting the noise-
Further comprising:
Wherein the light size adjusting unit adjusts the size of the light converted into the parallel light when the output light is converted into the parallel light. 18. The method of claim 17,
Wherein the light size adjusting unit adjusts the size of the output light based on the size of the hole formed in the first light converting unit. A lens assembly for converting spherical-wave-shaped object light into plane-wave-shaped light;
A light splitting unit splitting the plane wave light into first light and second light to reflect the first light and transmit the second light;
A light reflection part for reflecting the transmitted second light in the same direction as the traveling direction of the first light;
A hologram image acquiring unit acquiring a hologram image of an object based on the combination of the first light and the second light; And
A reconstruction unit for reconstructing a three-dimensional shape of the object based on the hologram image,
And an image reconstruction device for reconstructing the three-dimensional shape of the object.

Images