JP2000122514A - Device and method for deciding hologram pattern and recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To rapidly decide a binary hologram pattern of less noise. SOLUTION: An input image Fourier conversion part 1 decides a multilevel hologram pattern of an inputted original image (f) to output it. A hologram pattern binarization part 2 binarizes this multilevel hologram pattern by a threshold value. An inverse Fourier transformation part 3 calculates a regenerative image of a binarized hologram pattern. A difference calculation part 4 calculates a difference image corresponding to a difference between the regenerative image and the original image, and further, calculates the multi-level hologram pattern of the difference image. A difference image Fourier conversion part 5 calculates the multilevel hologram pattern of the difference image, and a hologram pattern correction part 6 corrects the multilevel hologram pattern of the difference image. A switch control means SW inputs the multilevel hologram pattern corrected by the hologram pattern correction part 6 to the hologram pattern binarization part 2 until a normal/defective condition decision part 10 in the difference calculation part 4 outputs a normal decision result.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and a method for determining a hologram pattern, and more particularly to a three-dimensional or two-dimensional digital image input as an original image and expressed as a two-dimensional digital binary image. TECHNICAL FIELD The present invention relates to a hologram pattern determination device and a hologram pattern determination method for determining a hologram pattern.

[0002]

2. Description of the Related Art Conventionally, a three-dimensional or two-dimensional digital image is used as object light, an interference fringe pattern (hologram pattern) with reference light is calculated as a multi-valued image, and the calculated hologram pattern (multi-valued image) is calculated. Some methods for converting a value hologram pattern into a binary image have been invented.

When a hologram is produced by using a computer, first, a hologram pattern produced on the computer is represented by multi-values, and the multi-valued hologram pattern is projected on a display or the like, photographed and reduced on a film. ,
There is such a method. However, this method requires a photograph of the hologram and the subsequent development of the film, which is complicated and time-consuming. If a hologram pattern as a binary image (binary hologram pattern) can be obtained by binarizing a multi-valued hologram pattern, a hologram pattern is printed on a film using a plotter according to the binary hologram pattern. The method makes it possible to produce holograms. If the multi-valued hologram pattern can be binarized in this manner, procedures such as photographing and development can be omitted, and the production time can be reduced. Therefore, recently, a method of binarizing a multi-valued hologram pattern has attracted attention.

As a binarization method, for example, there is a binarization method using a single threshold. 3A and 3B are respectively
An example of a certain target object and a multi-level hologram pattern calculated from the target object are shown. FIG. 4 (a) shows FIG.
FIG. 4B is a diagram showing a binary hologram pattern obtained by binarizing the multi-value hologram pattern shown in FIG. 4B with a threshold, and FIG. 4B is a reproduction reproduced on a computer from the binary hologram pattern. It is a figure showing an image.

[0005] Even with a single threshold, FIG.
As shown in (b), a reproduced image reproduced on a computer can be obtained from the binary hologram pattern. However, as shown in FIG. 4B, simply binarizing a multi-valued hologram pattern with a single threshold value causes much noise due to quantization errors on and around a reproduced image from the hologram. There is a problem that occurs.

[0006] In order to reduce such noise, for example, “Iterative quantization of digital amplitude holo”
grams ”, Frank Wyrowski, APPLIED OPTICS, Vol. 28, N
o.18, pp.3864-3870 (1989) proposes an iterative processing method.

In this Wyrowski processing method, two kinds of variable thresholds, threshold 1 and threshold 2, are provided as thresholds for binarizing a hologram pattern. First, the respective values of the threshold 1 and the threshold 2 are set to the lower limit and the upper limit of the values that the multi-valued hologram pattern can take. For example, when one pixel of the multi-level hologram pattern is represented by 8 bits having 256 gradations from 0 to 255, the threshold 1 is set to 0 and the threshold 2 is set to 255. Then, for the multi-valued hologram pattern, all pixels having a value less than or equal to the threshold value 1 are 0
In addition, all pixels having a value of 2 or more are set to 255,
The hologram pattern is quantized such that the other pixels have the same value.

A reproduced image is obtained by calculation from the hologram pattern quantized in this way, and the difference between the reproduced image and the original image is obtained by comparing the reproduced image with the original image. Until the difference converges, the reproduced image is corrected, and a multi-valued hologram pattern is produced again from the corrected reproduced image. The above-described quantization is performed again on the multi-valued hologram pattern manufactured in this manner using two types of thresholds. When the difference has converged, the threshold 1 is increased by a certain step, and the threshold 2 is decreased by the same step, and the above processing is performed until the difference converges. The above processing is repeated until the threshold value 1 and the threshold value 2 become the same value. When the threshold value 1 and the threshold value 2 become the same, the hologram pattern at that time is binarized into 0 and 255. The hologram pattern when the threshold value 1 and the threshold value 2 become the same and the difference converges,
The binary hologram pattern to be obtained is used.

[0009]

However, this method is
There has been a problem that the number of repetition processes is large and it takes time to binarize the hologram pattern.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and a hologram pattern determining apparatus and method for determining a hologram pattern in which a digital image is input as an original image and expressed as a two-dimensional digital binary image. And a recording medium.

[0011]

In order to achieve the above object, a hologram pattern determining apparatus according to a first aspect of the present invention provides a hologram pattern determining apparatus in which a digital image is input as an original image and is represented as a two-dimensional conversion pattern. In a binary computer-generated hologram pattern determination device that determines a binary hologram pattern, an original image hologram pattern calculation unit that calculates a multivalued hologram pattern from an original image, and a multivalued hologram pattern calculated by the original image hologram pattern calculation unit An original image binary hologram pattern calculation unit for calculating a binary hologram pattern, wherein the original image binary hologram pattern calculation unit binarizes the multi-value hologram pattern with a threshold to determine a binary hologram pattern. Value hologram pattern binarization means, Reconstructed image calculating means for calculating a reconstructed image of the binary hologram pattern determined by the value hologram pattern binarizing means, and a difference image corresponding to a difference between the reconstructed image reproduced by the reconstructed image calculating means and the original image Using a multi-level hologram pattern calculated by the differential image hologram pattern calculated by the differential image hologram pattern calculating section, and a multi-level hologram pattern calculated by the differential image hologram pattern calculating section. Correcting the binary hologram pattern binarized by the hologram pattern binarizing means, a corrected hologram pattern calculating means for calculating a corrected hologram pattern, and using the original image and the reproduced image, according to a predetermined standard A reproduction image quality judgment unit for judging the quality of the reproduction image; To the pattern binarization means, input the output of the original image hologram pattern calculation means as an initial value, thereafter, input the output of the modified hologram pattern calculation means, the pass / fail judgment result of the reproduction image pass / fail judgment means is good And a switching control unit for outputting the output of the multi-value hologram pattern binarization unit at the time when the result of the pass / fail judgment is good, as an original image binary hologram pattern. , Characterized in that.

FIG. 1 is a block diagram showing the overall configuration of the hologram pattern determining apparatus according to the first embodiment. First, a three-dimensional or two-dimensional digital image is input to an original image hologram pattern calculation unit as an original image. The original image hologram pattern calculating means performs an interference fringe pattern between the input original image and the reference light by a method such as performing a Fourier transform based on the theory of Fourier transform holography, or performing a Fresnel transform according to the theory of Fresnel transform holography. (Hologram pattern) is calculated.
By expressing the hologram pattern calculated in this way as a multi-value image, a multi-value hologram pattern is manufactured.

Next, the multivalued hologram pattern binarization means binarizes the multivalued hologram pattern calculated by the original image hologram pattern calculation means to calculate a binary hologram pattern. As a binarization method, for example, there is a binarization method using a single threshold.

The reconstructed image calculating means calculates a reconstructed image of the binary hologram pattern thus obtained. For the calculation of the reproduced image, a reproduction method corresponding to the hologram pattern calculation method performed by the original image hologram pattern calculation means is used. That is, for example, if the hologram pattern is calculated by Fourier transform, the inverse Fourier transform is performed. If the hologram pattern is calculated by the Fresnel transform, the inverse Fresnel transform is performed.

[0015] The reproduced image quality judgment means judges the quality (high or low) of the image quality of the reproduced image from the reproduced image and the original image. For example, the mean square error (MSE) between the reproduced image and the original image
Also, when the original image is a signal and the reproduced image is a signal containing noise, a signal-to-noise ratio (SN ratio) and the like are calculated. If the change is smaller than the comparison, it is determined to be good. If a good judgment is made, the binary hologram pattern at this point is
It is determined as the final binary hologram pattern, and the following processing is not performed.

If the determination is negative, the following processing is continued. First, the difference image calculation means calculates a difference between the reproduced image and the original image and outputs the difference as a difference image. This difference image represents noise in the reproduced image due to a quantization error when binarizing the multi-valued hologram pattern.

The difference image hologram pattern calculating means includes:
A multi-level hologram pattern of the difference image is calculated from the difference image obtained by the difference image calculation means. For calculating the multi-valued hologram pattern of the difference image, a method similar to the method of calculating the multi-valued hologram pattern of the original image performed by the original image hologram pattern calculating means is used.

The modified hologram pattern calculating means assigns a certain weight (usually, the absolute value is 1 or less) to the multi-valued hologram pattern of the difference image, and calculates the binary value calculated by the multi-valued hologram pattern binarizing means. The hologram pattern is corrected by determining the difference from the value hologram pattern. By this correction, the noise of the reproduced image due to the quantization error due to the binarization is efficiently reduced from the binary hologram pattern. The hologram thus obtained is input as a new hologram pattern to the multi-value hologram pattern binarization means by the switching control means. Thereafter, the processing after the multi-valued hologram pattern binarization means is repeated. Therefore, the output of the original image hologram pattern calculation means is input to the multi-value hologram pattern binarization means as an initial value, and thereafter,
The output of the corrected hologram pattern calculation means is input. The original image binary hologram pattern calculation means performs the processing after the multi-value hologram pattern binarization means.

By the above processing, the noise of the reproduced image caused by the quantization error due to the binarization of the hologram pattern is reduced.
Since the correction is made in the hologram pattern, efficient noise reduction can be realized.

The reproduced image quality determination means may determine whether the error between the reproduced image and the original image repeatedly calculated for the single original image has not changed by a predetermined number of times, And when the reproduced image is calculated a predetermined number of times different from the predetermined number of times,
When at least one of the above cases is satisfied, it is desirable to output a good judgment.

The reproduced image quality determining means determines whether the mean square error between the reproduced image and the original image repeatedly calculated for the single original image has not changed by a predetermined number of times,
If the mean square error is continuously increased by a predetermined number of times and the reproduced image is calculated by a predetermined number of times different from the predetermined number of times, the determination is good. It is desirable to output

It is preferable that the original image hologram pattern calculating means calculates a multi-valued hologram pattern after limiting the band of the original image.

A hologram pattern determining method according to a second aspect of the present invention is a hologram pattern determining method in which a digital image is input as an original image and an original image binary hologram pattern expressed as a two-dimensional conversion pattern is determined. An original image hologram pattern calculating step of calculating a multi-valued hologram pattern from an original image; a multi-valued hologram pattern binarizing step of binarizing the multi-valued hologram pattern to determine a binary hologram pattern; A reproduction image calculation step of calculating a reproduction image of the binary hologram pattern determined by the binarization step; and calculating a difference image corresponding to a difference between the reproduction image reproduced by the reproduction image calculation step and the original image. Calculating a difference image, and a multi-valued hologram of the difference image A differential image hologram pattern calculating step of calculating a differential pattern hologram pattern, and a binary hologram binarized by the multi-level hologram pattern binarizing step using the multi-level hologram pattern calculated by the differential image hologram pattern calculating step Correcting a pattern, calculating a corrected hologram pattern, calculating a corrected hologram pattern, and using the original image and the reproduced image, a reproduced image quality determination step of determining the quality of the reproduced image according to a predetermined reference, In the multi-valued hologram pattern binarization step, the output of the original image hologram pattern calculation step is input as an initial value, and thereafter, the output of the corrected hologram pattern calculation step is input, and the pass / fail of the reconstructed image pass / fail determination step is determined. Until the judgment result is good, A switching control step of outputting the output of the multi-value hologram pattern binarization step as an original image binary hologram pattern at the time when the pass / fail judgment result is good. And

Further, a computer-readable recording medium according to a third aspect of the present invention comprises a computer
An original image hologram pattern calculating means for calculating a multi-valued hologram pattern from an input image; a multi-valued hologram pattern binary for determining a binary hologram pattern by binarizing the multi-valued hologram pattern calculated by the original image hologram pattern calculating means Converting means, a reproduced image calculating means for calculating a reproduced image of the binary hologram pattern determined by the multi-valued hologram pattern binarizing means, and a difference between the reproduced image reproduced by the reproduced image calculating means and the original image. A differential image calculating means for calculating a corresponding differential image, a differential image hologram pattern calculating means for calculating a multi-valued hologram pattern of the differential image, a multi-valued hologram pattern calculated by the differential image hologram pattern calculating means, Binarized by multi-level hologram pattern binarization means A modified hologram pattern calculating means for correcting a value hologram pattern and calculating a modified hologram pattern; and a reproduced image quality judgment for judging the quality of the reproduced image according to a predetermined standard using the original image and the reproduced image. Means, to the multi-valued hologram pattern binarization means, input the output of the original image hologram pattern calculation means as an initial value, thereafter input the output of the corrected hologram pattern calculation means, Until the pass / fail judgment result becomes good, the calculation of the corrected hologram pattern is repeated, and the output of the multi-level hologram pattern binarization unit at the time when the pass / fail judgment result becomes good is output as an original image binary hologram pattern. And a program functioning as a repetition control means.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a hologram pattern determining apparatus according to the present invention will be described with reference to the drawings. In this embodiment, a two-dimensional digital image is used as an input image.

FIG. 2 is a block diagram showing a schematic configuration of the hologram pattern determining apparatus according to the embodiment of the present invention. The hologram pattern determination device (hereinafter, this processing device) includes an input image Fourier transform unit 1 as an original image hologram pattern calculation unit, a hologram pattern binarization unit 2 as a multi-value hologram pattern binarization unit, and a reproduction unit. A difference calculation unit 4 including an inverse Fourier transform unit 3 as an image calculation unit, an ei calculation unit 8 as a difference image calculation unit, an Erri calculation unit 9 as a reproduced image quality determination unit, and a pass / fail determination unit 10. A difference image Fourier transform unit 5 as a difference image hologram pattern calculation unit, a hologram pattern correction unit 6 as a correction hologram pattern calculation unit, a hologram pattern output unit 7 for outputting a binary hologram pattern, A repetition control unit SW for repeating the operation is provided.

Next, the operation of the hologram pattern determining apparatus having the above configuration will be described.

First, a two-dimensional digital image f (x, x) is input to the input image Fourier transform unit 1 and the difference calculation unit 4 as an input image.
y) is given. The digital image f (x, y) is obtained, for example, by a method of reading a document with a scanner, photographing with a digital camera, or the like. Here, x and y indicate the coordinates of each image in the x-axis direction and the y-axis direction, respectively, and f indicates the luminance of the image at each coordinate position.

The input image Fourier transform unit 1 calculates a multivalued hologram pattern for the supplied digital image f (x, y) based on the theory of Fourier transform holography. In Fourier transform holography,
The dynamic range of the intensity signal on the hologram surface tends to be very large. Therefore, this is alleviated by adding a random phase φ (x, y) to the input image. That is, the input image Fourier transform unit 1 limits the band of the digital image f (x, y) based on Equation 1.

[0030]

G (x, y) = │f (x, y) │exp (jφ (x, y))

Further, the input image Fourier transform unit 1 calculates a multivalued hologram pattern of the band-limited digital image g (x, y). The calculation of the hologram pattern is
This is performed based on Equation 2.

[0032]

H (u, v) = | G (u, v) | cos (Φ (u, v) −θ (u, v)) + B

Here, u and v are x and y coordinate values, H (u, v) is a multi-valued hologram pattern (gradation of the hologram pattern at the position of coordinates (u, v)), G (u, v) Is the Fourier transform of g (x, y), Φ (u, v) and θ (u, v) represent the phases of the object light and the reference light on the hologram plane, respectively, and B is H (u, v) ≧ 0
Is a bias signal for satisfying the following.

As described above, the input image Fourier transform unit 1 calculates and outputs an initial multivalued hologram pattern H (u, v) for the input image. The repetition control unit SW
The output multivalued hologram pattern H (u, v) is output to the hologram pattern binarization unit 2. Hereinafter, the multi-valued hologram pattern H (u, v) in which the number of repetitions is i-th (i ≧ 0)
The subscript i is added to represent Hi (u, v).

The hologram pattern binarization unit 2 binarizes the multi-value hologram pattern Hi (u, v) supplied from the input image Fourier transform unit 1 with a threshold value “128”, and converts the multi-value hologram pattern Hi ′ (u). , v). That is, Hi (u, v) of “128” or more is set to 1 and Hi (u, v) of less than “128” is set to 0. The hologram pattern binarization unit 2 outputs the calculated binary hologram pattern Hi ′ (u, v) to the hologram pattern output unit 7 and the inverse Fourier transform unit 3.

The inverse Fourier transformer 3 converts the binary hologram pattern H supplied from the hologram pattern binarizer 2
i ′ (u, v) is subjected to inverse Fourier transform to calculate a reproduced image gi (x, y), and the calculated reproduced image gi (x, y) is output to the difference calculator 4.

The Erri calculation unit 9 of the difference calculation unit 4 uses the supplied image data f (x, y) and the reproduced image gi (x, y) to obtain a mean square error Erri defined by Equation 3. Is calculated, and the calculated mean square error Erri is supplied to the pass / fail determination unit 10.

[0038]

(Equation 3)However, M2 is the number of pixels and f ＾ (＾ is substituted for the upper bar.
) Is the average value of f (x, y), σ_fRepresents the standard deviation of f (x, y)
Then g i ＾ is the average value of gi (x, y), σ_giIs gi (x, y)
Represents the standard deviation.

The pass / fail judgment unit 10 judges pass / fail of the image quality of the reproduced image based on the mean square error Erri calculated by the Erri calculation unit 9 and outputs the result to the hologram pattern output unit 7. I do. It is assumed that the condition for determining good is one of the following conditions.

(1) When the number of repetitions exceeds 100 (when i ≧ 100) (2) When the value of the mean square error Erri does not change for five consecutive times (3) Mean square error Erri If the value of increases 5 times in a row

If any of the above conditions is satisfied, the pass / fail judgment unit 10 supplies a “good” signal to the hologram pattern output unit 7. The hologram pattern output unit 7
When a signal of “good” is input, Hi ′ (u,
v) is output as a binary hologram pattern.

If none of the above conditions is satisfied, the pass / fail judgment unit 10 supplies a “no” signal to the hologram pattern output unit 7. Hologram pattern output unit 7
Responds to the "No" signal and does not output Hi '(u, v).

On the other hand, the ei calculation unit 8 obtains the difference image ei (x, y) according to the formula 4, and outputs the obtained difference image ei (x, y) to the difference image Fourier transform unit 5. Note that the difference image ei (x, y)
Indicates the luminance difference at the corresponding coordinate position (x, y) between the original image f (x, y) and the i-th reproduced image gi (x, y).

[0044]

[Equation 4] ei (x, y) = gi (x, y) −f (x, y)

The difference image Fourier transform unit 5 calculates the difference image e
A hologram when i (x, y) is Fourier transformed in the same manner as the input image Fourier transform unit 1 and the difference between the original image f (x, y) and the reproduced image gi (x, y) is viewed as a gradation image. A difference hologram pattern Ui meaning a pattern is calculated. Then, the calculated difference hologram pattern Ui is output to the hologram pattern correction unit 6.

The hologram pattern correcting section 6 corrects the difference hologram pattern Ui supplied from the difference image Fourier transform section 5 according to the formula 5, and produces a corrected hologram pattern Hi ″ (u, v).

[0047]

## EQU5 ## Hi ″ = Hi′−αUi

Here, α is a constant weighting coefficient larger than 0 and equal to or smaller than 1. In this embodiment, α = 0.86
And By multiplying this weight, the mean square error Er
This has the effect of converging ri efficiently.

The repetition control unit SW supplies Hi ″ thus obtained to the hologram pattern binarization unit 2 as a multivalued hologram pattern Hi + 1. Thereafter, the supplied multivalued hologram pattern Hi + 1 is set to Hi (i is updated), and the same operation is repeated until the pass / fail determination unit 10 determines that the pass is good.

As described above, initially, assuming that i = 0,
The multi-level hologram pattern H0 obtained by converting the original image f by the input image Fourier transform unit 1 is supplied to the hologram pattern binarizing unit 2. And the inverse Fourier transform described above,
The calculation of the difference image e0, the Fourier transform of the difference image e0, and the correction of the hologram pattern are performed to obtain a corrected hologram pattern H0 ″. The corrected hologram pattern H0 ″ is set as the next multivalued hologram pattern H1 and the hologram pattern binarization unit is used. 2 and the same process is repeated thereafter. Then, the binary hologram pattern Hi 'at the time when the above-described good condition is satisfied is used as the output of the hologram pattern determination device.

A comparative example of a hologram pattern actually manufactured by the above process and a hologram pattern formed by a conventional method will be described with reference to FIGS. First, FIG. 3A is a diagram showing an image of a target object to be holographically formed, and FIG. 3B is a hologram pattern (multi-value hologram pattern) of the target object. FIG. 4 (a)
FIG. 4 is a diagram showing a binary hologram pattern when the multi-value hologram pattern shown in FIG. 3B is simply binarized by a single threshold. FIG. 4B is a diagram showing a reproduced image of the binary hologram pattern shown in FIG. However, the number of pixels of the target object and the hologram pattern is 128 × 128 (p
ixel), and 1 pixel is represented by 256 gradations from 0 to 255.

As shown in FIG. 4B, a reproduced image obtained by simply binarizing a hologram pattern has much noise.

On the other hand, FIG. 5 shows a binary hologram pattern determined by the processing described in this embodiment and a reproduced image obtained by reproducing the hologram pattern on a computer.
FIG. 5A shows a binary hologram pattern.
FIG. 5B is a diagram showing a reproduced image of FIG. 5A reproduced on a computer. 4 (b) and FIG. 5 (b),
It can be seen that the reproduction quality is improved by this processing method.

FIG. 6 shows the image of FIG.
9 is a table showing comparison results when the Wyrowski processing method and the present processing method are used. From this table, this treatment method
It can be seen that the number of repetitions for achieving the same level of Erri is reduced as compared with the processing method of Wyrowski, and the processing time is shortened.

As described above, according to the binary computer generated hologram pattern determining apparatus and method of the present invention, Wy
Compared to the rowski processing method, the number of repetitions for achieving the same Erri can be reduced, and the processing time can be shortened. Further, a high-quality image with less noise can be obtained as compared with a hologram reproduced by a hologram pattern binarized by a single threshold value.

In the above description, the blocks for executing each processing for determining the hologram pattern have been described. However, these blocks may be realized as an actual physical configuration using, for example, ASIC technology. Alternatively, it may be realized as a function of software processing using an ordinary computer, a DSP (Digital Signal Processor), or the like. An example of the operation of software when executing the functions and configurations shown in FIG. 2 by software processing will be described with reference to the flowchart of FIG.

First, a two-dimensional digital image f (x, y) is input as an input image. Next, a pointer i indicating the number of repetitions is set to 0 (step S1).

Next, the digital image f (x, y) is band-limited based on the equation (1), and the multivalued hologram pattern Hi (u, v) of the band-limited digital image g (x, y) is converted into the equation (2). Calculation is performed based on the calculation (step S2). Multi-valued hologram pattern Hi (u,
v) is binarized to calculate a binary hologram pattern Hi '(step S3).

Next, the calculated binary hologram pattern Hi '(u, v) is subjected to inverse Fourier transform to calculate a reproduced image gi (x, y) (step S4).

The supplied image data f (x, y) and the reproduced image gi
Using (x, y), the mean square error Erri defined by Equation 3
Is calculated (step S5).

Next, based on the calculated mean square error Erri, it is determined whether or not the image quality of the reproduced image is equal to or higher than the reference level (step S6). It is assumed that the condition to be determined to be equal to or higher than the reference corresponds to, for example, one of the following conditions.

(1) When the number of repetitions exceeds 100 (when i ≧ 100), (2) Mean square error Er
When the value of ri does not change continuously N times, (3) When the value of the mean square error Erri increases continuously M times

If it is determined that one of the above conditions is satisfied, the binary hologram pattern Hi '(u, v) calculated in step S3 is output (step S13).

On the other hand, if it is determined that none of the above conditions is satisfied, a difference image ei (x, y) is obtained according to Equation 4 (step S7), and the difference image ei (x, y) is Fourier-transformed. Calculate the difference hologram pattern Ui (step S
8).

Subsequently, the difference hologram pattern Ui is corrected according to the expression 5, and the corrected hologram pattern Hi ″
(U, v) is manufactured (step S9).

Then, the pointer i is updated and the corrected hologram pattern Hi ″ obtained is returned to step S3 as a multi-valued hologram pattern on which a binary hologram pattern is calculated (step S1).
0 to S12), the above operation is repeated. According to this configuration, a desired binarized hologram pattern can be obtained by software processing.

In the above embodiment, the original image f (x,
y) by subtracting the reproduced image gi (x, y) from the difference image ei
Although (x, y) is calculated, the difference image ei (x, y) may be calculated by subtracting the original image f (x, y) from the reproduced image gi (x, y). In this case, the ei calculation unit 8 of the difference calculation unit 4 subtracts the reproduced image gi (x, y) from the original image f (x, y) to obtain the difference image ei (x, y).
, And the difference image Fourier transform unit 5 calculates the difference image ei (x,
The difference hologram pattern Ui is calculated from y). next,
The hologram pattern correction unit 6 calculates the corrected hologram pattern Hi ″ by multiplying the difference hologram pattern Ui by a weight (α: −1 ≦ α ≦ 0) and subtracting the difference hologram pattern from the binary hologram pattern. Even in this case, the corrected hologram pattern Hi '' can be calculated at high speed,
As a result, it is possible to efficiently reduce the difference between the input image and the reproduced image.

The condition for the pass / fail judgment unit 10 to output a pass / fail judgment is only required to satisfy that the noise of the reproduced image with respect to the input image is sufficiently reduced, and will be described in the above embodiment. It is not limited only to the conditions set.

In the above embodiment, the calculation of the hologram pattern was performed by Fourier transform, and the calculation of the reproduced image was performed by inverse Fourier transform. However, these calculation methods need only correspond to the hologram pattern calculation method and the reproduction method, and can be arbitrarily changed. For example, the calculation of the hologram pattern may be performed by Fresnel conversion, and the calculation of the reproduced image may be performed by inverse Fresnel conversion.

Although a two-dimensional image is used as an input image in this embodiment, the processing time of a three-dimensional input image can be shortened in the same manner as a two-dimensional input image, and noise can be reduced. A reproduced image can be obtained.

[0071]

According to the present invention, the difference between the input image and the reproduced image can be efficiently reduced by correcting the difference between the input image and the reproduced image in the hologram pattern and repeating this process. . Therefore, a binary hologram pattern in which noise of a reproduced image is reduced due to a quantization error can be determined at high speed.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating the concept of a hologram pattern determining apparatus according to the present invention.

FIG. 2 is a block diagram illustrating a configuration of a hologram pattern determination device according to an embodiment of the present invention.

FIG. 3A is a diagram illustrating an input image used in the embodiment, and FIG. 3B is a diagram illustrating a hologram pattern manufactured from FIG. 3A.

4A is a diagram showing a binary hologram pattern obtained by simply binarizing FIG. 3B with a threshold, and FIG.
FIG. 3B is a diagram showing a reproduced image obtained by reproducing FIG. 3A on a computer.

5A is a diagram showing a binary hologram pattern manufactured from FIG. 3A according to the embodiment; FIG.
FIG. 3B is a diagram showing a reproduced image obtained by reproducing FIG. 3A on a computer.

FIG. 6 is a comparison table between the processing method of Wyrowski and the processing method of the present invention.

FIG. 7 is a flowchart illustrating an example of an operation of software.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Input image Fourier transform part 2 Hologram pattern binarization part 3 Inverse Fourier transform part 4 Difference calculation part 5 Difference image Fourier transform part 6 Hologram pattern correction part 7 Hologram pattern output part 8 ei calculation part 9 Erri calculation part 10 Good / No Judgment unit

Claims (6)

[Claims] 1. A digital image is input as an original image,
In a binary computer generated hologram pattern determination device that determines a binary hologram pattern of an original image expressed as a two-dimensional conversion pattern, an original image hologram pattern calculation unit that calculates a multi-valued hologram pattern from an original image; Means for calculating a binary hologram pattern with respect to the multi-valued hologram pattern calculated by the means. A multi-level hologram pattern binarizing means for converting the binary hologram pattern into a binary hologram pattern; a reproduction image calculating means for calculating a reproduction image of the binary hologram pattern determined by the multi-level hologram pattern binarization means; Reproduced by the reproduced image calculation means. Difference image calculation means for calculating a difference image corresponding to the difference between the reconstructed image and the original image; difference image hologram pattern calculation means for calculating a multi-valued hologram pattern of the difference image; calculation by the difference image hologram pattern calculation means Using the multivalued hologram pattern, the corrected hologram pattern is calculated by correcting the binary hologram pattern binarized by the multivalued hologram pattern binarization means, and a corrected hologram pattern is calculated. Using the reproduced image, comprising a reproduced image quality determination means for determining the quality of the reproduced image according to a predetermined reference, the multi-value hologram pattern binarization means, the original image hologram pattern as an initial value Input the output of the calculating means, and then input the output of the corrected hologram pattern calculating means Until the quality judgment result of the reproduced image quality judgment means becomes good, the calculation of the corrected hologram pattern is repeated, and the output of the multi-value hologram pattern binarization means at the time when the quality judgment result becomes good is obtained. A hologram pattern determination device, comprising: a switching control unit that outputs a binary hologram pattern of an original image. 2. The reproduction image quality determination means according to claim 1, wherein the error between the reproduced image repeatedly calculated for the single original image and the original image has not changed a predetermined number of times, A case where the number of consecutive times increases, and a case where the reproduced image is calculated a predetermined number of times different from the predetermined number of times. The hologram pattern determination device according to claim 1. 3. The reproduction image quality determination means, wherein a mean square error between the reproduction image and the original image repeatedly calculated for a single original image has not changed by a predetermined number of times;
A case where the mean square error is continuously increased a predetermined number of times, and a case where the reproduced image is calculated a predetermined number of times different from the predetermined number of times,
The hologram pattern determining apparatus according to claim 1, wherein a good judgment is output. 4. The original image hologram pattern calculating means according to claim 1, further comprising means for calculating a multi-valued hologram pattern after applying a band limitation to the original image. A hologram pattern determination device according to the item. 5. A digital image is input as an original image,
A binary computer generated hologram pattern determining method for determining an original image binary hologram pattern expressed as a two-dimensional conversion pattern, comprising: an original image hologram pattern calculating step of calculating a multi-valued hologram pattern from an original image; A multi-level hologram pattern binarization step of binarizing to determine a binary hologram pattern; and a reproduction image calculation step of calculating a reproduction image of the binary hologram pattern determined by the multi-level hologram pattern binarization step. A difference image calculation step of calculating a difference image corresponding to a difference between the reproduced image reproduced by the reproduction image calculation step and the original image; and a difference image hologram pattern calculation step of calculating a multi-valued hologram pattern of the difference image. The difference image hologram pattern Using the multi-valued hologram pattern calculated by the output step, the multi-valued hologram pattern is corrected by the binarization step, the corrected hologram pattern calculation step of calculating a corrected hologram pattern, Using the original image and the reproduced image, a reproduced image quality determination step of determining the quality of the reproduced image according to a predetermined criterion, wherein the multi-valued hologram pattern binarization step, The output of the original image hologram pattern calculation step is input, and thereafter, the output of the corrected hologram pattern calculation step is input, and the calculation of the corrected hologram pattern is repeated until the result of the quality judgment of the reproduced image quality judgment step becomes good. The multilevel hologram at the time when the result of the quality judgment is good. A hologram pattern determination method, comprising: a switching control step of outputting an output of the ram pattern binarization step as an original image binary hologram pattern. 6. A computer, comprising: an original image hologram pattern calculating means for calculating a multi-valued hologram pattern from an input image; binarizing the multi-valued hologram pattern calculated by the original image hologram pattern calculating means to form a binary hologram pattern A multi-valued hologram pattern binarizing means to be determined; a reproduced image calculating means for calculating a reproduced image of the binary hologram pattern determined by the multi-valued hologram pattern binarizing means; a reproduction reproduced by the reproduced image calculating means Difference image calculation means for calculating a difference image corresponding to the difference between the image and the original image, difference image hologram pattern calculation means for calculating a multi-valued hologram pattern of the difference image, and multiplication calculated by the difference image hologram pattern calculation means Using the multi-valued hologram pattern, Correction hologram pattern calculation means for correcting the binary hologram pattern binarized by the binarization means and calculating a correction hologram pattern, using the original image and the reproduction image, performing the reproduction in accordance with a predetermined reference. Reconstructed image quality determining means for determining the quality of an image, inputting the output of the original image hologram pattern calculating means as an initial value to the multi-valued hologram pattern binarizing means, and thereafter outputting the corrected hologram pattern calculating means Is input, and the calculation of the corrected hologram pattern is repeated until the quality determination result of the reproduced image quality determination means is good. The multi-value hologram pattern binarization means at the time when the quality determination result is good. A repetition control means for outputting the output of the original image as a binary hologram pattern, Recording a computer-readable recording medium.