KR100551384B1 - Holography data decoding method - Google Patents

Abstract

The present invention relates to a holographic data decoding method implemented by focusing on the fact that each row and column of a reproduction data image includes at least one "0" (off pixel), where N: M (where N < M). The reproduction data image by the coding data is divided into J × J (J × J = M) square pixel unit zones, and then the “1” s are sequentially arranged by the intensity of light for each unit zone. A holographic data decoding method in which "0" s are assigned to Y (where X + Y = M) and decoded into original N-bit data, wherein the number of rows corresponding to each row is sorted for each row of the reproduction data image. Sorting " 0 " and sorting the remaining number of " 0 " and the X " 1 " except as sorted " 0 " in ascending order. According to the present invention, not only the cause of image quality deterioration of the reproduced data image can be eliminated, but also the decoding processing time can be reduced because it is not necessary to sort all the pixels.

Description

Holographic data decoding method {HOLOGRAPHY DATA DECODING METHOD}

1 illustrates a data image detected by a CCD from a storage medium in a holographic digital storage and playback system;

2 is a block diagram of a holographic digital storage and playback system capable of performing the holographic data encoding / decoding method according to the present invention;

3 illustrates a form in which a 6: 9 code is mapped to a spatial light modulator according to the present invention.

<Description of the code | symbol about the principal part of drawing>

110: storage and playback device 111: light source

112: optical separator 113, 116: shutter

114, 117: reflector 115: actuator

118: spatial light modulator 119: storage medium

120: CCD 130: data encoding device

150: data decoding device

The present invention relates to a holographic system, and more particularly to a holographic data decoding method suitable for decoding holographic data reproduced from a storage medium.

Currently, research and development of holographic recording media capable of storing hundreds to hundreds of Gbytes as optical storage media and their recording / reproducing apparatuses are being actively conducted for large-capacity and high-speed processing of data storage memories.

The recording of the holographic data is made by recording the intensity and direction of the signal light reflected from the object. The intensity and direction of the light of the object is composed of the interference of the signal light and the reference light to form an interference fringe, and the interference fringe is formed in a holographic storage medium made of a material that responds to the intensity of the interference fringe. The holographic data recorded on the storage medium can be read only by the reference light used in the recording process, and reference light having a different wavelength or phase from the reference light used during recording cannot be read through the holographic data recorded on the storage medium. .

By using this holographic property, it is possible to store a large amount of data inside a small recording medium by recording a lot of holographic data in the same place of the recording medium with different reference light.

A typical holographic digital storage and reproducing system splits a laser light generated from a light source into a reference light and a signal light in a recording mode in which holographic data is recorded on a storage medium, and splits the signal light into external input data (ie, input data to be stored). Holographic corresponding to the input data, the interference fringes obtained by modulating the pixel-contrast binary data of one page unit and interfering with the modulated signal light and the recording reference light reflected at a predetermined deflection angle. Record as data to storage media.

At this time, the A × A (eg, 240 × 240) holographic data recorded on the storage medium is subjected to a series of preprocessing (for example, encoding processing for encoding pixel data and inserting an error correction code (parity bit), etc.). After the frame is encoded by the frame generation process for oversampling, the signal is modulated into a signal light through a spatial light modulator and recorded on a storage medium, and the A × A (eg, 240 × 240) reproduced from the storage medium is reproduced. The holographic data (i.e., the interference fringe shape image) is irradiated through a charge coupled device (CCD) or the like and has a data image (e.g., data of 1024 x 1024) having a size of (A + B) x (A + B). Image), and the data before encoding through the oversampling process, that is, the data image having an A × A size (for example, 240 × 240 is a data image), and then before encoding through ECC decoding or the like. Original having Data is restored.

1 is a diagram illustrating a data image detected by a CCD from a storage medium in a holographic digital storage and reproduction system, wherein image data of one page unit is (A + B) × (A + B), for example. For example, it has a size of 1024 x 1024. The page image includes a band-shaped border and a data image having a size of 720 x 720 in the frame.

Therefore, in order to extract the A × B data image, which is the original data size, from the (A + B) × (A + B) sized data image, first of all, from the (A + B) × (A + B) sized data image, It is necessary to detect an edge. As one method for this, a method of obtaining a total sum of pixels of each row line and a total sum of pixels of each column line may be used. In other words, if the total sum of pixels of each row line and the sum of pixels of each column line are found, there is an extraordinarily large line on each side, and these lines become the edge positions of both sides. Here, the total sum of the pixel lines constituting the border is represented by a large value, whereas pixels in the actual data image region have a form in which pixel data values of "1" and "0" are randomly mixed, while the pixels forming the border are formed. This is because they all have the same pixel data value (for example, "1").

Next, after detecting the edge through a series of processes described above, for example, pixels are extracted for each line, starting from the upper left corner of the edge and sequentially moving to the upper right corner. For example, assuming that the original data image is 240 × 240 size and that the data image obtained through the CCD on the playback side is 720 × 720 size, 240 pixels are selected by skipping two pixels for each line. A 240 x 240 size data image is extracted. The 240 x 240 size data image is transferred to the decoder and decoded into original data before encoding.

On the other hand, one of the methods of decoding the reproduction signal is a method using a threshold value, the method of using the threshold value is a method using an average or 0.5 value of the pixel and a method using a local threshold value. In the former case, if the average or the value of the pixel is larger than 0.5, it is read as 1, and if it is smaller, it is read as 0. The local threshold utilization method divides the playback signal of one page into several regions, and applies different threshold values to each divided region, that is, the closer the center of the page, the higher the threshold value and the center of the page. It is a method of determining 1 and 0 by applying a relatively low threshold value as it moves away from (ie, closer to an edge portion).

Another method for reducing the error rate of the reproduction signal is a method proposed by the Stanford University (hereinafter referred to as the Stanford method) in the United States. After the recording on the storage medium, and after the playback in reverse decoding. For example, 0 is coded as 01, 1 is coded as 10, and recorded and decoded after the reverse process.

Another method for reducing the error rate of the reproduction signal is the method proposed by IBM (hereinafter referred to as the IBM method), which is coded so that the number of 1's and 0's is the same, recorded on a storage medium, and reproduced. After that, the decoding is done in the order of intensity.

For example, for a 6: 8 code, 64 combinations with the same number of 1s and 0s of 8 bits are associated with 64 data (from 6 bits to 8 bits), and during playback (8-bit signals). ) A combination of four strong ones with ones and the rest with zeros, which are then converted to six bits and decoded. This IBM scheme has a code rate of about 67% at 4: 6, a code rate of about 75% at 6: 8, and a code rate of about 67% at 8:12.

However, according to the conventional encoding and decoding methods as described above, as illustrated in FIG. 1, a band shape may also appear in the data image area in addition to the band shape of the specific border area. This is because pixel data values of "0" are randomly mixed, but pixel data values of "1" may be concentrated in a specific row line or column line.

In this case, as described above, if the total sum of pixels of each row line and the sum of pixels of each column line are found in order to detect a border in the data image, a line having a large value such as a border is detected in several places. It cannot be accurately understood, which has a problem of causing a deterioration in image quality of a reproduced data image.

In addition, since the data is sorted for each pixel during decoding, there is a problem that the processing time required for the data determination process of the modulation code becomes long.

The present invention has been proposed to solve such a conventional problem, and employs a method of decoding in the order of intensity within a square pixel unit area, where "0" (off pixel) is added to each row and column of the reproduction data image. It is an object of the present invention to provide a holographic data decoding method that does not need to sort all the pixels in consideration of at least one included.

According to a preferred embodiment of the present invention for realizing this object, a square pixel unit region of a J × J (where J × J = M) is obtained by reproducing a reproduction data image using N: M (where N &lt; M) coded data. After dividing the data into each unit area, sort by the intensity of the light, and give X "1" and Y "0" (but X + Y = M) sequentially to the original N-bit data. A method of decoding holographic data, the method comprising: sorting a number of "0" corresponding to a row by sorting each row of a reproduction data image, and the remaining number of "0" except the sorted "0", and A method of decoding holographic data comprising sorting X "1s" in ascending order.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. Through this embodiment, it is possible to better understand the objects, features and advantages of the present invention. However, the present invention is not limited to these examples.

FIG. 2 is a block diagram of a holographic digital storage and reproducing system capable of performing the holographic data encoding / decoding method according to the present invention. The storage and reproducing apparatus 110 and the data encoding apparatus ( 130 and the data decoding device 150.

The storage and reproducing apparatus 110 represents a general general reproducing system, and includes a light source 111 for generating laser light required by holography, and a storage medium 119 for storing three-dimensional holographic data (ie, interference fringes). (For example, a photorefractive crystal) and a CCD 120, and between the light source 111 and the storage medium 119 are two paths including a plurality of optical systems, that is, a reference light processing path PS1. And a signal light processing path PS2 are formed.

First, the optical splitter 112 splits the laser light incident from the light source 111 into a reference light and a signal light, where the reference light of the vertically polarized light is provided to the reference light processing path PS1 and the branched signal light is signal light processed. Provided by path PS2.

Next, the shutter 113, the reflector 114, and the actuator 115 are provided on the reference light processing path PS1 in the emission direction of the reference light, and through the light transmission path, the reference light processing path PS1 is used to display the holographic data. The reference light required for recording or reproduction is reflected at a predetermined deflection angle and provided to the storage medium 119.

In this case, although not illustrated in FIG. 2 for convenience of explanation and improvement of understanding, a plurality of optical lenses (for example, a waist configuration lens, a beam expander, etc.) for reference light processing are provided on the reference light processing path PS1. do.

Accordingly, the vertically polarized reference light branched from the optical separator 112 and incident through the opening of the shutter 113 is adjusted through an optical lens or the like not shown and expanded to an arbitrary size (that is, the signal light processing path PS2 described later). ) To a size sufficient to cover the size of the signal light extending through the beam expander, and a preset reproduction for the predetermined angle, for example, the recording angle during recording or reproduction, through the reflector 114. After being deflected at an angle, it is incident (irradiated) onto the storage medium 119.

Here, the reference light used in recording or reproducing rotates the reflector 114 using the actuator 115 whenever the binary data of each page unit is recorded on the storage medium 119, thereby adjusting the deflection angle θ. It is controlled by a change method, and through this reference light deflection technique, hundreds to thousands of holographic data can be stored in the storage medium 119 or the stored holographic data can be reproduced.

On the other hand, the shutter 116, the reflector 117 and the spatial light modulator 118 are sequentially provided on the signal light processing path PS2 in the emission direction of the signal light, and the shutter 116 is controlled from the system control means (not shown). Therefore, the open state is maintained in the recording mode, and the cutoff state is maintained in the reproduction mode.

In this case, although not illustrated in FIG. 2 for convenience of explanation and improvement of understanding, a plurality of optical lenses (eg, reimaging lenses, beam expanders, field lenses, etc.) for signal light processing are provided on the signal light processing path PS2. ) Is provided.

Accordingly, the signal light branched from the optical separator 112 and incident through the opening of the shutter 116 is reflected at a predetermined deflection angle through the reflector 117 and then transmitted to the spatial light modulator 118.

Subsequently, in the spatial light modulator 118, the signal light transmitted from the reflector 117 is made of light and shade of pixels according to the input data (i.e., input data coded according to the present invention) provided from the data encoding apparatus 130. The signal light incident on the spatial light modulator 118 when the input data is image data in one frame unit of the image is modulated into signal light in one frame unit. The light is incident on the storage medium 119 in synchronization with the reference light incident from the reflector 114 of the path PS1.

Accordingly, in the storage medium 119, in the recording mode, recording incident from the reflector 114 with signal light modulated in units of pages of binary data provided from the spatial light modulator 118 and its corresponding deflection angle θ is performed. The interference fringe obtained through the interference between the standard reference lights is recorded. That is, the light induced phenomenon of the kinetic charge is generated in the storage medium 119 according to the intensity of the interference fringe obtained by the interference between the modulated signal light and the reference light. Through this process, the holographic data is stored in the storage medium 119. Interference fringes are recorded.

Meanwhile, the data encoding apparatus 130 performs data coding using an N: M (where N &lt; M) unbalanced code, and digitally input data input from an external device (ie, input data to be recorded on a storage medium). ) Is divided into groups by blocking N-bit units (for example, 6 bits), where each block data divided into groups is " 1 " for X (for example, 3) and " 0 " After conversion (for example, 9 bits) to M bits of Y (for example, 6 bits), coding is performed, and one page of binary data coded with each block data is transmitted to the spatial light modulator 118. In this case, in the mapping of the data to the spatial light modulator 118, a combination in which "1" is not continuously arranged horizontally or vertically in a JxJ (for example, 3x3) square pixel unit area is selected.

Therefore, the spatial light modulator 118 irradiates the storage medium 119 with the signal light generated by modulating the signal light incident from the reflector 117 in units of one page of binary data composed of pixels. 119 stores holographic data coded according to the present invention.

On the other hand, when reproducing holographic data coded according to the present invention and recorded (stored) in the storage medium 119, the shutter 116 on the signal light processing path PS2 side under control from a system control means (not shown). ) Is blocked and the shutter 113 is opened on the reference light processing path PS1 side.

Therefore, the reference light (reproducing reference light) branched from the optical separator 112 is reflected through the reflector 114 and irradiated to the storage medium 119. As a result, in the storage medium 134, interference recorded by the reference light for reading is obtained. The patterned reading reference light is diffracted and demodulated into one page of binary data (that is, a checkered pattern) composed of the original pixel contrast, where the demodulated reproduction signal is irradiated to the CCD 120.

Subsequently, the CCD 120 restores the reproduction output irradiated from the storage medium 119 to original data, that is, an electrical signal, and the reproduced reproduction signal is transmitted to the data decoding apparatus 150.

The data decoding apparatus 150 decodes a coded reproduction signal reproduced from the storage medium 119 and output through the CCD 120 into an original signal before coding, and has a size of (A + B) × (A + B). In order to extract an A × A data image, which is the original data size, from the data image, first, an edge is detected from a data image of size (A + B) × (A + B). As one method for this purpose, a method of obtaining the total pixel sum of each row line and the total pixel sum of each column line may be used. In other words, if the total sum of pixels of each row line and the sum of pixels of each column line are found, there is an extraordinarily large line on each side, and these lines become the edge positions of both sides. Here, the total sum of the pixel lines constituting the border is represented by a large value, whereas pixels in the actual data image region have a form in which pixel data values of "1" and "0" are randomly mixed, while the pixels forming the border are formed. This is because they all have the same pixel data value (for example, "1").

Next, after detecting the edge through a series of processes described above, for example, pixels are extracted for each line, starting from the upper left corner of the edge and sequentially moving to the upper right corner. For example, assuming that the original data image is 240 × 240 size and the data image obtained through the CCD 120 on the playback side is 720 × 720 size, two pixels are skipped for each line to select pixels. In this way, a data image of 240 × 240 size is extracted.

In this case, the data decoding apparatus 150 divides the extracted data image by J × J (for example, 3 × 3) square pixel unit zones, and arranges the unit data in descending order based on the light intensity for each unit zone. "1" is given by X (for example, 3), and "0" is given by Y (for example, 6), and K bits (for example, 3 bits) of information bits of the total M bits are provided. Decode the original N-bit (eg, 6-bit) data.

Accordingly, in the present invention, in recording and reproducing holographic data through the coding and decoding process as described above, " 1 " is continuously or horizontally contiguous in the JxJ (e.g., 3x3) square pixel unit region. Since a combination that does not lie is selected, there can never be a similar pixel data line in the data image area which can be mistaken for a border area.

The inventors of the present invention conducted experiments on the process of coding holographic data and reproducing and decoding the coded data according to the present invention.

[Example]

This embodiment is for the case of a 6: 9 code, that is, a case in which 6-bit blocks separated into groups are coded by 9 bits, recorded, reproduced, and decoded.

The input data to be recorded on the storage medium is blocked in 6 bit units and separated into groups, and each block data divided into groups is converted into 9 bits of 3 pieces of "1" and 6 pieces of "0". . 6-bit input data has 2 ⁶ = 64 combinations, and 9-bit code has ₉ C ₃ = 84 combinations, so it can be seen that coding can be performed without difficulty. For example, input data 111000 maps to 000100101, 101001 maps to 010110000, and 001110 maps to 010000110.

When the 9-bit code is mapped to the spatial light modulator, a combination in which "1" is not continuously arranged horizontally or vertically is selected in the 3x3 square pixel unit area. In other words, there are 6 combinations (1 1000000, 000111000, 000000111, 001001001, 101010010, 100100100) where "1" can be placed consecutively in a unit area. Therefore, out of 84 codes consisting of 9 bits, there are only 78 codes minus the above 6 combinations. 6: 9 Mapping is performed.

FIG. 3 illustrates a form in which a 6: 9 code is mapped to a spatial light modulator. 111000, which is presented as an example of the input data, is mapped to a 000100101 code, and mapped to a spatial light modulator in the form as shown in FIG. 3 (a). , 101001 is mapped to 010110000 code and mapped to the spatial light modulator in the form as shown in FIG. 3 (b), and 001110 is mapped to spatial light modulator in the form as shown in FIG.

Next, in the decoding process according to the present embodiment, the data image is divided into 3 × 3 square pixel unit areas, and then, in each of the unit areas, the "1" is sequentially divided into three by "" in descending order based on the light intensity. Give six "0" s.

Then, sort for three "0" by sorting for each row. That is, in FIG. 3 (a), (b) and (c), the three elements are sorted and one off pixel is found in each row. Thus, three off pixels can be found.

In this way, when an off pixel is found for each row and column, there is an off pixel that is not yet determined. That is, when three off pixels are determined, three off pixels are not yet determined.

In this case, when the remaining six pixels except three off pixels, that is, three off pixels and three on pixels are sorted in ascending order, the lower three pixels become off pixels.

The aligned pixels are then decoded into the original 6-bit data to terminate the decoding process.

That is, as can be seen from the 6: 9 code mapped to the spatial light modulator in Fig. 3, the reproduction data is constituted by selecting a combination in which the same data values as the edge pixel data values are not placed continuously horizontally or vertically. Each row and column of the image is characterized by including at least one or more "0" (off pixel), the present invention devised a scheme that does not need to sort all the pixels in view of this point.

For example, when sorting all 9 pixels in total, it takes time proportional to n ² , that is, time proportional to 9 * 9 = 81, but 3 * 3 when sorting pixels by the method according to the present invention. It can be seen that only ² +6 ² , ie time proportional to 63, is required.

This can be seen that the larger the size of the square code, the effect is doubled.

Although the foregoing description of the present invention has been described with reference to an embodiment, it is obvious that the technology of the present invention may be easily modified by those skilled in the art.

For example, in the above-described embodiment, a 6: 9 code using a 3 × 3 square pixel unit area is illustrated, but a C: 16 code using a 4 × 4 square pixel unit area and a D: using a 5 × 5 square pixel unit area: 25 code and so on.

Such modified embodiments should be included in the technical spirit described in the claims of the present invention.

As described above, the present invention codes data by square pixel unit regions of a code combination in which the same data is not continuously placed horizontally or vertically, and after playback, decodes the data in the square pixel unit region according to the order of intensity. There can never be a similar pixel data line which may be mistaken for the border area, thereby eliminating the factor causing the deterioration of the image quality of the reproduced data image, thereby compensating for the entire image. In addition, according to the present invention, since it is not necessary to sort all the pixels during reproduction of the data image, the decoding processing time can be reduced.

Claims (4)

N: Separation of the reproduction data image by M (where N &lt; M) coding data is divided into J × J (J × J = M) square pixel unit areas, and then aligned based on the light intensity for each unit area. In the holographic data decoding method to decode the original N-bit data by sequentially giving X "1" and Y "0" (where X + Y = M), Sorting each row of the reproduction data image to sort the number of " 0 " corresponding to the row; Sorting the remaining number of " 0 " and the X " 1 " Holographic data decoding method comprising a. The method of claim 2, The decoding method, Dividing the reproduction data image into 3 × 3 square pixel unit areas; Giving three "1" s and six "0s" sequentially by arranging the unit areas based on the intensity of light; Sorting three "0s" by sorting for each row, Sorting the remaining three " 0 " except the three " 0 " and the three " 1 " in ascending order to decode the original 6-bit data; Holographic data decoding method comprising a. The method according to claim 1 or 2, And the reproduction data image is configured by selecting a combination in which the same data value as the edge pixel data value is not continuously placed in the horizontal or vertical whole. The method of claim 3, wherein And at least one "0" in each row and column of the reproduction data image.

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