KR101423163B1 - Holographic Printer for Filtering Holographic Fringe Pattern and Recording That on Holographic Recording Medium by the Hogel and Holographic Printing Method thereof - Google Patents

Abstract

A holographic printer and a holographic printing method thereof are provided. A holographic printer according to an embodiment of the present invention includes a light modulator for displaying a holographic fringe pattern for a specific portion of an object and diffracting an incident wave and a light modulator for shielding a part of the diffracted wave field emitted from the light modulator To a specific region of the holographic recording medium. As a result, it is possible to record holographic fringe patterns on a holographic recording medium by a part of the gel-gel basis, thereby enabling more realistic hologram recording, and filtering diffracted wave fields emitted from the holographic fringe pattern to remove non- It becomes possible to record the hologram, thereby eliminating the tile phenomenon of the hologram.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a holographic printer and a holographic printing method for holographically printing a holographic fringe pattern on a holographic recording medium,

Field of the Invention [0001] The present invention relates to a holographic printer, and more particularly to an apparatus and method for recording a wave-field diffracted by a spatial light modulator in which a holographic interference pattern for an object is displayed into a holographic recording medium .

A conventional holographic stereogram is a method of multiplexing a plurality of two-dimensional images and recording them in a holographic recording medium, which uses a holographic recording medium as a high-resolution display panel. The recorded contents are a plurality of two-dimensional images, thereby realizing a three-dimensional stereoscopic image.

However, such a method can not reproduce a perfect three-dimensional space, which is a characteristic feature of the hologram, because problems such as visual fatigue and image distortion caused by a lens generated in a conventional binocular-based three-dimensional stereoscopic image display are maintained.

In addition, the conventional fringe printer is a method of reducing a holographic interference pattern for a three-dimensional object and recording it in a holographic recording medium. Since the holographic recording medium has a thin hologram characteristic, the diffraction efficiency is low and there is no color selectivity. This is a difficulty.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a holographic printer for recording a holographic fringe pattern into a holographic recording medium while filtering the holographic fringe pattern by a small amount for a more realistic hologram recording, And a holographic printing method thereof.

It is also an object of the present invention to diffract an incident beam according to a holographic interference pattern by displaying a holographic interference pattern for a three-dimensional object on a spatial light modulator and for entering a beam for more realistic holographic recording , and only a desired 1st diffracted light field is transmitted by a spatial band pass filter. The transmitted first-order diffracted light component is a wave-field constituting a hologram image, and this wave-field is recorded in the holographic recording medium. This is to provide a digital holographic printing method for producing a hologram which can reproduce a perfect three-dimensional space same as an analog film hologram, by the same method as the analog film hologram characteristic without existing digital processing.

According to an aspect of the present invention, there is provided a holographic printer including: a light modulator that displays a holographic fringe pattern for a specific portion of an object and diffracts an incident wave; And a filtering unit for blocking some of the diffracted wave fields emitted from the light modulating unit and transmitting the blind to a specific area of the holographic recording medium.

The filtering unit may pass the first-order diffracted component among the diffracted wave fields, and may block the first-order diffracted component and the non-diffracted component.

A first lens that is provided between the light modulation unit and the filtering unit and that focuses the diffracted wave field emitted from the light modulation unit to the filtering unit; And a second lens provided between the filtering unit and the holographic recording medium for aligning the diffracted wave field transmitted through the filtering unit and entering a specific area of the holographic recording medium.

The wave field diffracted by the holographic fringe pattern for a specific part of the object displayed on the light modulation part is reduced to a specific area of the holographic recording medium by the first lens and the second lens, .

In addition, the holographic fringe pattern for a particular portion of the object may be a holographic fringe pattern for a particular portion of a virtual object created by the computer.

Wherein a specific portion of the object displayed on the light modulation portion changes sequentially and a specific region of the holographic recording medium to which the filtering portion conveys the diffracted wave field sequentially changes in response to a specific portion of the object can do.

Irradiating a reference wave to the holographic recording medium to cause an object wave emitted from the holographic recording medium to enter another holographic recording medium and irradiating a reference wave to the other holographic recording medium, Can be recorded in the other holographic recording medium.

Meanwhile, according to another embodiment of the present invention, a holographic printing method includes diffracting an incident wave in a holographic fringe pattern for a specific portion of an object; And blocking some of the diffracted wave field generated in the diffraction step and delivering it to a specific area of the holographic recording medium.

As described above, according to the present invention, a wave-field for a virtual object diffracted by a holographic fringe pattern can be filtered to record in a holographic recording medium while eliminating inappropriate components, Likewise, a more realistic holographic recording becomes possible. Also, by fabricating the second hologram from the recorded hologram, it is possible to produce a natural hologram by eliminating the tiling phenomenon of the hologram.

1 is a view of a holographic printer according to an exemplary embodiment of the present invention,
2 is a diagram schematically illustrating, by a holographic printer, the concept that a holographic fringe pattern is partially / sequentially written on a holographic recording medium in a gel-gel basis,
3 is a diagram schematically illustrating a concept of generating a secondary hologram with a master hologram,
Fig. 4 is a diagram provided for explanation of the secondary hologram reconstruction method.

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

1 is a diagram provided in the description of a holographic printer according to an embodiment of the present invention. The holographic printer according to the present embodiment is an apparatus for recording a hologram.

For this purpose, a holographic printer converts a diffracted wave field generated by a holographic fringe pattern for an object to be recorded with a hologram into a holographic emulsion (Holographic Emulsion) 160).

As shown in FIG. 1, the holographic printer performing such functions includes a spatial light module (SLM) 120, a lens-1 (L ₁ ) 130, a band pass filter (BPF) 140, And a lens-2 (L ₂ ) 150.

Although not shown in FIG. 1, the computer 110 and the holographic emulsion 160 are further illustrated in FIG. 1 for ease of understanding and explanation, and will be described below with the configurations of the holographic printer.

The computer 110 is a device for generating a holographic fringe pattern for a virtual object to be recorded as a hologram with a graphic tool. The holographic fringe pattern generated by the computer 110 is divided into portions and applied to the SLM 120.

For example, the computer 110 divides the generated holographic fringe pattern into 8 × 8, and divides the generated (1, 1), (1,2), ..., (1,8) , (1), (2,2), ..., (8,8) are sequentially applied to the SLM 120.

As a result, a holographic fringe pattern of a specific part of the object (a part applied from the computer 110) is displayed on the SLM 120, which is one type of the optical modulation device, to diffract the Illuminating Wave.

The diffracted wave field emitted from the SLM 120 is incident on the Lens-1 130 provided between the SLM 120 and the BPF 140. The lens-1 130 focuses the diffracted wave field onto the BPF 140.

The BPF 140 transmits some components in the diffracted wave field and blocks the others. Specifically, the BPF 140 transmits the 1st Order Diffracted Wave Field and blocks the -1st Order Diffracted Wave and the Non-Diffracted Wave.

The first diffraction component transmitted through the BPF 140 is incident on the Lens-2 150 provided between the BPF 140 and the holographic emulsion 160. The lens-2 150 aligns a first order diffracted light component transmitted through the BPF 140 in a specific area of the holographic emulsion 160 and makes incident thereon.

As shown in FIG. 1, is generated by the 'holographic fringe pattern for a specific part of an object' displayed on the SLM 120 by the lens-1 130 and the lens-2 150 The diffracted wave field is reduced to appear in the holographic emulsion 160.

The first-order diffraction component incident on the holographic emulsion 160 becomes an object wave. This first-order diffraction component interferes with a reference wave incident on the holographic emulsion 160, and this interference pattern is recorded in the holographic emulsion 160.

The object wave, which is the first-order diffraction component incident on the holographic emulsion 160, is an object wave for a specific portion of the object, not the whole object. Therefore, the interference pattern recorded in the holographic emulsion 160 is an interference pattern for a specific portion, not an entire object, and is referred to as Hogel, which is an abbreviation of a holographic element.

Thereafter, the computer 110 displays a holographic fringe pattern of another portion of the object on the SLM 120. The computer 110 also controls the holographic printer so that the first order diffraction component generated by the SLM 120 and transmitted by the BPF 140 is incident on other areas of the holographic emulsion 160. [ Here, another region of the holographic emulsion 160 is a region corresponding to another portion of the object.

That is, when the holographic fringe pattern for an object is divided into 8 占 8 portions, the holographic emulsion 160 is also divided into 8 占 8 regions,

(1, 1) portion of the holographic fringe pattern is displayed on the SLM 120, the first-order diffraction component is incident on the (1,1) region of the holographic emulsion 160,

2) When the (1,2) portion of the holographic fringe pattern is displayed on the SLM 120, the first order diffracted wave component is incident on the (1,2) region of the holographic emulsion 160,

....

8) When the SLM 120 displays the (1,8) portion of the holographic fringe pattern, the first diffracted component is incident on the (1,8) region of the holographic emulsion 160,

9) When the (2,1) portion of the holographic fringe pattern is displayed on the SLM 120, the first diffracted component is incident on the (2,1) region of the holographic emulsion 160,

...

64) When the (8,8) portion of the holographic fringe pattern is displayed on the SLM 120, the first order diffraction component is incident on the (8,8) region of the holographic emulsion 160.

Accordingly, the holographic fringe pattern for the object is recorded in the holographic emulsion 160 partly / sequentially on a gel-by-gel basis by the holographic printer.

FIG. 2 schematically shows the concept that a holographic fringe pattern is partially or sequentially recorded on a holographic emulsion 160 by a holographic printer. In FIG. 2, a plurality of regions constituting the holographic emulsion 160 become hogels, and the hogels are gathered to form a hologram.

The second hologram may be recorded in another holographic emulsion using the hologram recorded in the holographic emulsion 160 according to the above embodiment as a master hologram. Respectively.

As shown in FIG. 3, when a reference wave is irradiated to the holographic emulsion 160, the hologram recorded in the holographic emulsion 160 is restored. That is, an object wave is emitted from the holographic emulsion 160, which is incident on another holographic emulsion 170.

At this time, when a reference wave is applied to the holographic emulsion 170 to interfere with the object wave incident from the holographic emulsion 160 and the interference pattern is recorded in the holographic emulsion 170, The master hologram is recorded in the holographic emulsion 170 as a secondary hologram.

Therefore, when the reference holographic emulsion 170 is irradiated with the recorded reference hologram, the hologram is restored as shown in FIG. 4, which is the same as the hologram reconstructed from the holographic emulsion 160.

On the other hand, it is also possible to generate a plurality of secondary holograms from one master hologram. That is, it is possible to record the master hologram recorded in the holographic emulsion 160 in a plurality of different holographic emulsions.

In the above embodiment, the number of hog gels is assumed to be 64 (= 8 × 8), which is merely an example for convenience of explanation. The technical idea of the present invention can also be applied when the number of hogels is differently implemented.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

110: Computer 120: Spatial Light Module (SLM)
130: Lens-1 (L ₁ ) 140: BPF (Band Pass Filter)
150: lens-2 (L ₂ ) 160, 170: holographic emulsion

Claims (8)

An optical modulation unit displaying a holographic fringe pattern for a specific portion of an object and diffracting an incident wave; And
And a filtering unit for blocking some components of the diffracted wave field emitted from the light modulating unit and transmitting the blind to a specific area of the holographic recording medium,
Irradiating a reference wave to the holographic recording medium to cause an object wave emitted from the holographic recording medium to enter another holographic recording medium and irradiating a reference wave to the other holographic recording medium to interfere with the incident object wave, Pattern is recorded in said another holographic recording medium.
The method according to claim 1,
Wherein the filtering unit comprises:
Wherein the first-order diffracted component passes through the diffracted wave field, and the -1st-order diffracted component and the non-diffracted component are blocked.
The method according to claim 1,
A first lens that is provided between the light modulation unit and the filtering unit and that focuses the diffracted wave field emitted from the light modulation unit on the filtering unit; And
And a second lens provided between the filtering unit and the holographic recording medium for aligning the diffracted wave field transmitted through the filtering unit and entering a specific area of the holographic recording medium. printer.
The method of claim 3,
The first lens and the second lens,
Wherein a wave field diffracted by a holographic fringe pattern for a specific portion of an object displayed on the light modulation unit is reduced and incident on a specific area of the holographic recording medium.
The method according to claim 1,
The holographic fringe pattern for a particular portion of the object may include,
Wherein the holographic data is a holographic fringe pattern for a specific portion of a virtual object generated by a computer.
The method according to claim 1,
A specific portion of the object displayed on the light modulation unit sequentially changes,
Wherein the specific area of the holographic recording medium to which the filtering unit conveys the diffracted wave field changes sequentially corresponding to a specific part of the object.
delete Diffracting an incident wave into a holographic fringe pattern for a particular portion of an object; And
And blocking and transmitting some of the diffracted wave fields generated in the diffraction step to a specific area of the holographic recording medium,
Irradiating a reference wave to the holographic recording medium to cause an object wave emitted from the holographic recording medium to enter another holographic recording medium and irradiating a reference wave to the other holographic recording medium to interfere with the incident object wave, Pattern is recorded in said another holographic recording medium.

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