KR20050115561A - Hologram data encoding/decoding system and method - Google Patents

Abstract

According to the present invention, it is possible to accurately detect a border region even in a data image having an image capable of representing a large value of lines per line. To this end, the present invention encodes a data image of a unit of a page having an arbitrary size. Unlike the conventional method of encoding / decoding hologram data by recording on a storage medium and over-sampling and decoding the data image during playback, it is determined whether there is data of a specific structure that can represent a large value of line-by-line total values. Selectively transform the data in an selective / alternative manner by detecting and transforming the data value in units of n bits by using a specific code value of n bits for a predetermined predetermined length of data each time data of a specific structure is detected. Recording to a storage medium, and when data of a specific structure is detected at the time of reproduction. Similar to the total value of each line in the border area, the data values of predetermined lengths following the data of a specific structure are restored and reproduced by using a predetermined code value of n bits. By suppressing occurrence of the line-to-line total value in the large data image, it is possible to effectively detect the edge area of the data image for decoding on the reproduction side, and effectively prevent the deterioration of the reproduced data image due to the detection failure of the edge area. It is.

Description

Hologram data encoding / decoding system and method thereof {HOLOGRAM DATA ENCODING / DECODING SYSTEM AND METHOD}

The present invention relates to a holographic system, and more particularly to a holographic data encoding / decoding system suitable for encoding data or decoding data reproduced from a storage medium for recording the holographic data on a storage medium. It is about a method.

Recently, the field of technology using volume holographic digital data storage is actively being researched everywhere due to the remarkable development of semiconductor laser, charge coupled device (CCD), liquid crystal display (LCD), etc. As a result of these studies, fingerprint recognition systems for storing and reproducing fingerprints have been put to practical use, and are being expanded to various fields that can apply the advantages of large capacity and ultra-fast data transfer rate.

As described above, the holographic digital storage and reproducing system is a storage medium, for example, light, which reacts sensitively to the amplitude of the interference fringes when the interference fringes generated when the signal light from the object and the reference light interfere with each other. By recording on a storage medium such as a photorefractive crystal and recording the intensity and phase of the signal light by a method of changing the angle of the reference light or the like, the three-dimensional image of the object can be displayed and the binary Hundreds to thousands of holograms, organized in pages of data, can be stored in the same place.

On the other hand, a typical holographic digital storage and reproducing system, in the recording mode of recording hologram data to a storage medium, splits the laser light generated from the light source into a reference light and an object light, and stores the object light into external input data (ie, storage). And modulates the pixel into binary data of one page unit in contrast, interfering with the modulated object light (ie, signal light) and the recording reference light reflected by a predetermined deflection angle. The interference fringe obtained by the recording is recorded in the storage medium as hologram data corresponding to the input data.

At this time, the N × N (e.g., 240 x 240) hologram data recorded in the storage medium is subjected to encoding processing for inserting a series of preprocessing (e.g., error correction codes (parity bits), etc., and oversampling in decoding). N × N (eg, 240 × 240) hologram data (ie, 240 × 240) reproduced from the storage medium after being encoded through a spatial light modulator and then encoded by signal light through a spatial light modulator. , An interference fringe shape image) is irradiated through a charge coupled device (CCD) or the like and converted into a data image having a size of (N + M) × (N + M) (for example, a data image of 1024 × 1024). The data is converted to data before encoding, that is, a data image having an N × N size (for example, 240 × 240 is a data image) through an oversampling process, and then restored to the original data before encoding through a process such as ECC decoding. do. That is, as an example, as shown in FIGS. 3A and 3B, a data image having a size of 1024 × 1024 is converted into a data image having a size of 240 × 240 through over sampling. Here, in FIG. 3A, the four side portions of the data image displayed in dark black color indicate a band-shaped border.

In general, a data image reproduced from a storage medium and output through a CCD, that is, a data image of one page unit has a size of (N + M) × (N + M), for example, 1024 × 1024. These page images consist of a band-shaped border and a real data image with a size of 720 × 720 within the border, and a 240 × 240 grid (each grid is 3 × 3 pixels) for oversampling to extract the actual data. ).

Therefore, in order to extract the N × N data image, which is the original data size, from the (N + M) × (N + M) size data image, the edge of the (N + M) × (N + M) size data image is first used. It is necessary to detect, and as one method for this, a method of obtaining the sum of the pixels of each row line and the sum of the pixels of each column line may be used.

4 is a histogram showing the result of calculating the sum of pixels of a row line as an example. Referring to Fig. 4, it can be seen that there are two (parts indicated by round circles) having particularly large values on both sides, and these x-axis pixel values become the edge positions on both sides. Here, when the sum of the pixel lines forming the border is a large value, the pixels of the actual data image portion have a form in which pixel data values of "1" and "0" are randomly mixed, while forming a border. This is because the pixels are all the same pixel data value (e.g., "1").

Next, after detecting the edge through a series of processes as described above, as shown in Figures 5a and 5b, for example, starting from the upper left corner portion in the border and sequentially moving to the upper right corner portion The pixels are extracted using the grid line by line. 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, and the 240 x 240 size data image is transferred to a decoder and decoded into original data before encoding.

On the other hand, as an example, when a data image having a shape as shown in FIG. 6 is reproduced after being stored in a storage medium, those having large values such as a border may appear in various forms in the vicinity instead of only on both sides. In this case, there is a problem that a situation in which the edge of the data image is not accurately detected in the conventional method as described above, and this problem is a factor that causes deterioration (distortion) of the reproduced data image.

The present invention is to solve the above-mentioned problems of the prior art, a hologram data encoding / decoding system that can accurately detect (determining) the edge region even in a data image having an image that can represent a large value for each line line and The purpose is to provide a method.

According to an aspect of the present invention, there is provided a holographic system for recording a data image on a storage medium by recording an interference fringe by interfering a signal light obtained by modulating a reference light and a data image into a signal light. A system for encoding / decoding data, the system comprising: means for detecting data of a predetermined specific structure in an input data image and generating a corresponding deformation control signal when the data of the specific structure is detected; Each time, the data following the data of the specific structure is transformed by m preset units of n-bit size by using a mask having a specific code value of n-bit size, thereby selectively / alternatively transforming the input data image. Means and the image after encoding the selectively / alternately modified data image. Means for recording on a storage medium, means for extracting and decoding an encoded data image of one size from a data image reproduced on the storage medium, detecting data of the specific structure in the decoded data image, and Means for generating a corresponding restoring control signal when the data of < RTI ID = 0.0 > By reconstructing m preset units in units, a hologram data encoding / decoding system including means for selectively / alternately reconstructing the decoded transformed data image is provided.

According to another aspect of the present invention for achieving the above object, the present invention provides a holo for recording a data image on a storage medium by recording an interference fringe by interfering signal light obtained by modulating a reference light and a data image into signal light. A method of encoding / decoding data in a graphic system, wherein when data of a predetermined specific structure is detected in an input data image, data following the data of the specific structure is masked using a mask having a specific code value of n-bit size. a first step of selectively / alternatively transforming the input data image by m preset by m bits in units of n bits, and a second step of repeatedly performing the first step whenever new data of the specific structure is detected. Encoding a data image comprising the process and the selectively / alternately modified data image. A third process of recording in the storage medium, a fourth process of extracting and decoding an encoded data image of one size from the data image reproduced in the storage medium, and data of a specific structure preset in the decoded data image When is detected, by selectively restoring the data following the data of the specific structure by the predetermined m pieces in units of n-bit size using the mask having the specific code value, the decoded transformed data image is selectively / alternatively altered. A hologram data encoding / decoding method includes a fifth process of restoring and a sixth process of repeatedly performing the fifth process whenever a new data of the specific structure is detected.

In accordance with another aspect of another aspect for achieving the above object, the present invention provides a holo for recording a data image on a storage medium in a manner of recording an interference fringe by interfering signal light modulated with the reference light and the data image with the signal light. A method of encoding / decoding data in a graphic system, wherein when data of a predetermined structure is detected in an input data image, all data of one page unit following the data of the specific structure is converted into a specific code value of n-bit size. A method of selectively modifying a part of the input data image by modifying the data in n-bit size units using a mask having a mask, and encoding and recording a data image including the selectively modified data image on the storage medium. A second process and a data image to be reproduced on the storage medium. A third process of extracting and decoding an encoded data image of one size from the first size; and when data of a predetermined specific structure is detected in the decoded data image, all data of one page unit following the data of the specific structure Provided is a hologram data encoding / decoding method comprising a fourth process of selectively restoring an n-bit size unit by using a mask having the specific code value.

The above and other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

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

First, the core technical idea of the present invention is to encode / decode hologram data in a manner of encoding a data image of a unit of a page having an arbitrary size, recording it on a storage medium, and over-sampling and decoding the data image during playback. Unlike the conventional method, it is detected whether there is data of a specific structure that can represent a total value of each line of a large value, and a predetermined predetermined length (i.e., m) that follows (followed) whenever data of a specific structure is detected. Bytes, and then selectively transforms the data in n-bit units (ie, exclusive OR) using a specific code value of n bits to write to the storage medium. Whenever data of a specific structure is detected at the time of reproduction, a predetermined n-bit specific code value (code used for data modification on the recording side) Hologram data recorded and reproduced in units of pages by restoring data values of a predetermined length (i.e., m bytes) following the data of a specific structure to original data values before transformation by using the same code value). By encoding / decoding, it is possible to easily achieve the object of the present invention through such technical means.

1 is a block diagram of a typical holographic recording system employing an encoding apparatus according to a preferred embodiment of the present invention.

Referring to FIG. 1, a typical holographic recording system includes a spindle motor 102, a storage medium 104, a reference light path 106, a signal light path 108, an optical system 110, a data input block 112 and And an encoding block 114, where the encoding block 114 substantially refers to the encoding device of the present invention. That is, the encoding apparatus of the present invention includes a memory block 1141, a data monitoring block 1142, a data modification block 1143, an error correction code (ECC) encoding block 1145, a modulation encoding block 1147, and a data image generation block. (1149).

First, a schematic view of the operation of a typical holographic recording system is provided with a storage medium 104 which is rotationally driven by a spindle motor 102, which storage medium 104 has a reference light for recording hologram data. The reference light path 106 irradiated to the storage medium 104 side and the signal light path 108 to which the signal light modulated with the hologram data are irradiated to the storage medium 104 side are provided.

Further, although not shown in the drawings, the reference optical path 106 includes an optical system, a reflector, and the like, and the signal optical path 108 includes an optical system 110, a data input block 112, and the like. The data input block 112 includes a spatial light modulator for modulating a page-based data image provided by the encoding block 114 corresponding to the encoding apparatus of the present invention into signal light.

Thus, in a typical holographic recording system having the above-described configuration, the interference fringes obtained through the interference between the reference light irradiated through the reference light path 106 and the signal light irradiated through the signal light path 108 are recorded. The data image in units of pages is recorded in the storage medium 104 in a manner.

Next, a process of encoding a data image of one page unit for recording in a holographic recording system having the above-described configuration according to the present invention will be described.

First, the encoding apparatus of the present invention includes a memory block 1141, a data monitoring block 1142, a data conversion block 1143, an ECC encoding block 1145, a modulation encoding block 1147, and a data image generation block 1149. In this case, the memory block 1141 stores digital image data in units of pages to be recorded on the storage medium 104 mounted in the holographic recording system.

Referring to FIG. 1, the data monitoring block 1142 monitors each line data of one page provided from the memory block 1141 so as to have data of a specific structure, for example, data having a form of “00000000” or “11111111”. (I.e., data in which one byte is all " 0 " values or all " 1 " values) is present. When data of a specific structure is detected, a corresponding deformation control signal is generated on the line L11 to generate data Provided as a deformation block 1143. For example, in the data monitoring block 1142, a "high level" control signal is generated on the line L11 and provided to the data transformation block 1143 every time data of a specific structure is detected.

Next, the data modification block 1143 is a certain size, for example, one byte, for the pixel data provided from the memory block 1141 in response to the modification control signal provided from the data monitoring block 1142 via the line L11. Selectively or alternately transform data in units. That is, in the data transformation block 1143, m preset consecutive data after data of a specific structure (for example, 2 bytes, 4 bytes, 6 bytes, 8 bytes, 12) is applied when the deformation control signal is applied through the line L11. Bytes (16 bytes, etc.) are transformed (exclusive OR). These m data transformations are executed each time a high level transformation control signal is applied from the data monitoring block 1142 via the line L11. That is, in the data transformation block 1143, the data provided from the memory block 1141 may be selectively and alternately transformed in response to the transformation control signal provided through the line L11 and transferred to the ECC encoding block 1145.

For example, when the data of a specific structure detected is "00000000" and a high level deformation control signal is generated on the line L11, a specific code value (in units of 1 byte) for the data after the data of the specific structure is defined. For example, by taking an exclusive OR using a mask with " 00010111 ", m-byte pixel data groups are transformed into pixel data groups with arbitrary bit values in units of 1 byte. The deformation is repeated each time a deformation control signal is generated on the line L11 (i.e., detection of the next specific structure data).

Similarly, when the data of the specific structure detected is " 11111111 " and thus a high level deformation control signal is generated on the line L11, a specific code value (e.g., " By taking an exclusive OR using " 01100010 "), the m-byte pixel data groups are transformed into pixel data groups having arbitrary bit values in units of 1 byte, which is transform control on line L11. Repeated whenever a signal occurs.

Therefore, in the data transformation block 1143, image data having a form in which deformation (modification in m bytes) and non-deformation are mixed is provided to the ECC encoding block 1145 according to whether specific structural data is detected.

Data of a specific structure as described above, that is, data of "00000000" and "11111111" is a data structure that can represent the total value of each line of a large value when the value is continuous, the data of this specific structure is continuous In this case, in the histogram of the sum of pixel values per line to detect the edge of the reproduction data image, the data may appear in a form having large values such as the edge. Accordingly, in the present invention, a predetermined m-byte data following the data of a specific structure is modified (exclusive-OR) in order to prevent the data of the specific structure from being continuous when data of a specific structure is detected. By selectively / alternatively altering the transformation of data, it fundamentally blocks the generation of data of a specific structure that can be mistaken for edges.

On the other hand, in the present embodiment, whenever a specific structure data having a form of "00000000" or "11111111", that is, a specific structure data of 1 byte is detected, a mask of a specific code value is applied to subsequent m bytes of data. However, the present invention is not necessarily limited to the above, but the present invention is not necessarily limited thereto, and the specific structure data is checked by consecutive n bytes (for example, 2 bytes, 3 bytes, 4 bytes, etc.) instead of 1 byte. Thus, when specific structure data is contiguous n (n bytes), data transformation using exclusive OR can be performed on subsequent data.

Next, the ECC encoding block 1145 inserts a code for correcting errors of a signal due to noise or the like by mathematical calculation, i.e., adds a parity bit for error correction in units of n bits of pixel data, and the like. The modulation encoding block 1147 encodes pixel data of a data image to which an error correction code is added in order to reduce an error rate in a reproduction signal, for example, data conversion such as 4: 6, 6: 8, 8:12, and the like. The pixel data is encoded in such a manner that the data image of one encoded page is transferred to the next data image generation block 1149.

Subsequently, in the data image generation block 1149, a predetermined bit border area is generated in the data image having an arbitrary size (N × N, N × M, M × N, etc.) provided from the modulation encoding block 1147 described above. That is, a data image having an edge region of a predetermined bit for oversampling during reproduction decoding is generated and provided to the data input block 112. For example, when a data image having a size of 240 × 240 is provided, a data image having a size of 243 × 243 having a border area having three bits of top, bottom, left and right of the image is generated.

As a result, the data image having the border region of the predetermined bit is modulated into the signal light and irradiated to the storage medium 104 through the signal light path 108 to interfere with the reference light irradiated through the reference light path 106. Are recorded (stored) in any space in the storage medium 104 as interference fringes.

Therefore, according to the present invention, even if the data image to be recorded on the storage medium is a data image having a shape as shown in FIG. 6 as an example, that is, a data image that can represent a total value of each line of a large value Whenever data of a specific structure appears, it transforms the pixel data following the data of the specific structure in a predetermined m-byte unit by using an exclusive OR using a specific code value of n bits (that is, it does not represent a large value for each line of a large value). By transforming the data image, the data image to be recorded is transformed into a data image that does not have a large value of pixels per line (i.e., a large value similar to that of the border line) and is recorded. Effective edge detection for data reproduction can be realized.

On the other hand, in a preferred embodiment of the present invention, each time data of a specific structure is detected before encoding the data image (ECC encoding), a predetermined preset value following the specific code value is obtained through an exclusive OR using a specific code value (n bit mask). Although the present invention has been described as selectively / alternatively transforming m-byte data values, the present invention is not necessarily limited thereto. After ECC encoding a data image to be recorded on the storage medium, an optional OR alternately exclusive OR is performed. Of course, the pixel data values of the data image can be transformed, and of course, the same result can be obtained.

Next, a description will be given of a process of reproducing, according to the present invention, a data image which is selectively / alternately image-modified and recorded on a storage medium through a series of processes as described above.

2 is a block diagram of a typical holographic reproduction system employing a decoding device according to a preferred embodiment of the present invention.

Referring to FIG. 2, a typical holographic reproduction system includes a spindle motor 202, a storage medium 204, a read light path 206, a reproduction light path 210, an image detection means 210 and a decoding block 212. Wherein the decoding block 212 means substantially the decoding device of the present invention. That is, the decoding apparatus of the present invention includes an over sampling block 2121, a demodulation block 2123, an ECC decoding block 2125, a data monitoring block 2126, a data recovery block 2127, and a memory block 2129. do. In addition, the constituent members denoted by reference numerals 202, 204 and 206 in FIG. 2 refer to constituent members substantially the same as those denoted by reference numerals 102, 104 and 106 in FIG.

That is, a typical holographic reproducing system is provided with a storage medium 204 which is rotationally driven by the spindle motor 202, which has read light necessary for reproducing the recorded hologram data. The read light path 206 irradiated to the < RTI ID = 0.0 >) side < / RTI >

In addition, an image detecting means 210, for example, a CCD camera, is provided on the side of the reproduction light path 208. In such a CCD camera, each pixel constituting the image light to be reproduced is n × n pixels (for example, 3). X 3 pixels) and photoelectric conversion in a manner to provide to the decoding block (212). For example, assuming that the data image light reproduced from the storage medium 204 (that is, the checkered pattern of binary data) has a resolution size of 240 × 240 and has 3 bits of top, bottom, left and right borders, the image The detection means 210 generates a photoelectrically converted data image having a resolution size of 1024 × 1024 including the edge and provides it to the decoding block 212.

Thus, in a typical holographic reproduction system having the configuration as described above, the original pixel contrast is configured by an interference fringe diffracting the read light when the read light is irradiated to the storage medium 204 through the read light path 206. One page of binary data (ie, checkered pattern) image light is reproduced, and the image light is provided to the decoding block 202 as a data image captured and photoelectrically converted by the CCD camera.

Next, a process of decoding the data image encoded and reproduced by one page unit to be reproduced in the holographic reproduction system having the above-described configuration will be described according to the present invention.

First, the decoding apparatus of the present invention includes an over sampling block 2121, a demodulation block 2123, an ECC decoding block 2125, a data monitoring block 2126, a data recovery block 2127, and a memory block 2129. Include.

Referring to FIG. 2, the over sampling block 2121 detects an edge of a reproduction data image through a method using a total pixel value of each line, and the original data image, that is, an encoded data image, through over sampling. Is extracted and transmitted to the demodulation block 2123. For example, suppose that a 1024 × 1024 size data image is provided through image capturing with a 3 × 3 pixel per pixel for a playback data image having a resolution size of 240 × 240 and 3 bits of top, bottom, left, and right edges. In the oversampling block 2121, the original data image of the 240 × 240 size (i.e., the second pixel is extracted after extracting one pixel from the 720 × 720 data image using a 3 × 3 mask after detecting the edge). Encoded data image).

In this case, in the present invention, before encoding a data image to a storage medium, m-byte pixel data groups preset in n-bit units are selectively / alternately modified, i.e., in a specific structure, by using a specific code value of n-bit. Whenever data occurs, the original pixel data is selectively and alternately transformed and recorded by performing an exclusive OR with an n-bit specific code value (n-bit mask) on m-byte pixel data groups following the data of a specific structure. As a result, since the total data for each line having the same value as that of the border area is not included in the actual data area, it is possible to reliably detect the border area (that is, the four-side border position of the data image) in the reproduced data image.

Next, the demodulation block 2123 decodes the image of the encoded data into the original data before encoding, for example, decodes the pixel data by a data conversion scheme such as 6: 4, 8: 6, 12: 8, and the like. The decoding block 2125 corrects an error of the reproduced data image through error correction decoding using an error correction code embedded in the reproduced data image, and the data image of one page in which the error correction is performed in the next data monitoring block 2126 and data recovery block 2127, respectively.

The data monitoring block 2126 then monitors the pixel data provided from the ECC decoding block 2125 so that data of a specific structure, for example, data in the form of "00000000" or "11111111" (that is, all one byte Whether a value of "0" or all "1" is present, and when a data of a specific structure is detected, a corresponding high level restoration control signal is generated on the line L21 to generate a data restoration block 2127; ) For example, in the data monitoring block 2126, whenever a data having a specific structure is detected, a high level restoration control signal is generated on the line L21 and provided to the data restoration block 2127.

In addition, the data recovery block 2127 may be provided in m-byte units of pixel data provided from the ECC encoding block 2125 in response to the restoration control signal provided from the data monitoring block 2126 through the line L21. Exclusive using the transformed (exclusive OR) pixel data with a predetermined n-bit specific code value (i.e., a specific code value used to transform the data image before encoding the data image, for example 0010111 or 0110001). By taking an exclusive OR, the original pixel data group before transformation is restored. That is, in the data restoration block 2127, when a high level restoration control signal is applied through the line L21, data restoration (exclusive OR) is selectively performed only on preset m-byte pixel data following the data of a specific structure. To selectively or alternately perform restoration of the pixel data.

For example, as in the above-described assumption in the encoding block, data from byte 1 to byte 10 returns a value of "0, 0, 0, 0, 0, 0, 0, 0, 0, 0". And if it is set to transform (exclusive OR) subsequent 5 bytes when two consecutive bytes are " 0 " or " 1 " The values 0, 0, 1, 1, 1, 1, 1, 0, 0, 1 "are obtained, and the same code as the code values used for data modification in accordance with the present invention after playing these values on the reproduction side When alternating / selectively restoring data (exclusive OR) using values, the resulting data after restoration is restored to the original value before data transformation, that is, "0, 0, 0, 0, 0, 0, 0, 0, 0, 0." , 0 ". That is, bytes 1 and 2 remain intact, bytes 3 through 7 are restored through an exclusive OR, bytes 8 and 9 remain as they are, and byte 10 is restored through an exclusive OR. Data restoration is performed selectively / alternatively.

Accordingly, the pixel data of the data image reconstructed through the selective / alternative data reconstruction (exclusive-OR) process as described above is stored in the memory block 2129 for providing to the display side, not shown.

That is, according to the decoding apparatus of the present invention, an exclusive logical sum is performed on preset m-byte pixel data following data of a specific structure in units of n bits by using a specific code value of n bits at the time of encoding before recording to a storage medium. Since the data image is deformed in advance, the edge of the data image can be reliably and accurately detected at the time of decoding on the reproduction side, and by adopting an exclusive logical sum with the same code value used at the time of deformation of the data image, The reproduced playback data image can be easily restored to the original data image before deformation.

On the other hand, in a preferred embodiment of the present invention, whenever one or m predetermined structure data (for example, two, three, four, etc.) of n-bit specific structure data occurs, the data in n-bit units following thereafter Is transformed by m (e.g., 4, 8, 12, 16, etc.) bytes by an exclusive OR using a mask having a specific code value. Each time m set detections are performed by restoring a predetermined m byte through an exclusive OR using a mask having the same specific code value as that of the encoding side, but the present invention is not limited thereto. When specific structural data occurs in one or m presets (e.g., 2, 3, 4, etc.), all data following the specific structural data (i.e. It takes an exclusive OR on the data after the data of the structure and transforms it, and also on the reproduction side, when one or m predetermined structure data of n bits is detected, all subsequent data (that is, a specific structure on one page) Of course, it is possible to encode / decode the data image for the hologram by taking an exclusive logical OR on all data subsequent to the data and restoring the original data before transformation. In the case of such a modified method, it may be preferable to set the unit of n bytes instead of 1 byte in consideration of the frequency of occurrence of data of a specific structure.

As described above, according to the present invention, the above-described method of encoding / decoding hologram data in such a manner as to encode a data image of a unit of a page having an arbitrary size, record it on a storage medium, and over-sample and decode the data image during playback Unlike the conventional method, it is detected whether there is data of a specific structure that can represent a large value of line-by-line, and each time data of a specific structure is detected, a predetermined predetermined length (i.e., m bytes) is followed. Selecting and altering data in an optional / alternative manner of transforming the data value in n-bit units using a specific code value of n bits for the data, recording the data on a storage medium, and reproducing the data each time data of a specific structure is detected at the time of reproduction. A predetermined length of data following data of a specific structure by using a specific code value of n bits set. By restoring the data values back to the original data values before deformation and suppressing the generation of line-to-line total values in the large data image similar to the line-to-line total values of the border area, It is possible to effectively detect the edge area, thereby effectively preventing deterioration (distortion) of the reproduced data image due to the detection failure of the edge area.

1 is a block diagram of a typical holographic recording system employing an encoding apparatus according to a preferred embodiment of the present invention.

2 is a block diagram of a typical holographic reproduction system employing a decoding apparatus according to a preferred embodiment of the present invention;

3A is a data image having a size of 1024 × 1024, 3B is a 240 × 240 size data image extracted through over sampling from a 3A data image,

4 is a histogram showing the result of calculating the sum of pixels of a horizontal line as an example;

5A is a diagram showing the upper left corner of the playback data image, and 5B is a diagram showing the upper right corner of the playback data image;

6 is an exemplary view of a data image recorded on a storage medium.

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

114: encoding block 212: decoding block

1141 and 2129 memory blocks 1142 and 2126 data monitoring blocks

1143 data transformation block 1145 ECC encoding block

1147: modulation encoding block 1149: data image generation block

2121: oversampling block 2123: demodulation block

2125 ECC decoding block 2127 data recovery block

Claims (9)

A system for encoding / decoding data in a holographic system that records a data image on a storage medium by interfering signal light obtained by modulating a reference light and a data image into a signal light to record an interference fringe. Means for detecting data of a predetermined specific structure in the input data image and generating a corresponding deformation control signal when the data of the specific structure is detected; Whenever the deformation control signal is generated, the input data image is selectively modified by modifying data following the data of the specific structure by m preset units in n-bit size units using a mask having a specific code value of n-bit size. Means of alternating deformation, Means for encoding said selectively / alternatively modified data image and then writing it to said storage medium; Means for extracting and decoding an encoded data image of one size from the data image reproduced on the storage medium; Means for detecting data of the specific structure in the decoded data image and generating a corresponding restoration control signal when the data of the specific structure is detected; Whenever the restoration control signal is generated, the data following the data of the specific structure is restored by m preset units in n-bit size units by using a mask having the specific code value. Alternative means of restoration Hologram data encoding / decoding system comprising a. The method of claim 1, And the deformation and restoring control signal generating means each generates the deformation control signal and the restoring control signal each time n pieces of data having the specific structure are detected in the preset holographic data encoding / decoding system. The method according to claim 1 or 2, And the modifying and reconstructing means respectively transform and reconstruct the data through an exclusive OR between the n-bit pixel data and the n-bit specific code value. A method of encoding / decoding data in a holographic system in which a data image is recorded on a storage medium by recording interference patterns by interfering signal light obtained by modulating a reference light and a data image into signal light. When data of a predetermined specific structure is detected in the input data image, by modifying the data following the data of the specific structure by m preset units in n-bit size units using a mask having a specific code value of n-bit size, A first process of selectively / alternatively modifying the input data image; A second process of repeating the first process each time new data of the specific structure is detected; A third process of encoding the data image including the selectively / alternately modified data image and recording the data image on the storage medium; A fourth process of extracting and decoding an encoded data image of one size from the data image reproduced in the storage medium; When data of a predetermined specific structure is detected in the decoded data image, by reconstructing the data following the data of the specific structure by m predetermined units by n-bit size using a mask having the specific code value, A fifth process of selectively / alternately reconstructing the decoded transformed data image; A sixth process of repeating the fifth process whenever new data of the specific structure is detected; Hologram data encoding / decoding method comprising a. The method of claim 4, wherein The method may further include performing the first and fifth processes, respectively, when n preset pieces of data are detected. The method according to claim 4 or 5, And the method transforms and reconstructs the data through an exclusive logical sum between the n-bit pixel data and the n-bit specific code value. A method of encoding / decoding data in a holographic system in which a data image is recorded on a storage medium by recording interference patterns by interfering signal light obtained by modulating a reference light and a data image into signal light. When data of a predetermined specific structure is detected in the input data image, all data of one page unit following the data of the specific structure are transformed into n-bit size units by using a mask having a specific code value of n-bit size. A first process of selectively transforming a portion of the input data image; A second process of encoding a data image including the selectively modified data image and recording the data image on the storage medium; A third step of extracting and decoding an encoded data image of one size from the data image reproduced in the storage medium; When data of a predetermined specific structure is detected in the decoded data image, all data of one page unit following the data of the specific structure are selectively restored in n-bit size units using a mask having the specific code value. 4th course Hologram data encoding / decoding method comprising a. The method of claim 7, wherein The method may further include performing the first and fourth processes, respectively, when n pieces of data of the specific structure are detected. The method according to claim 7 or 8, And the method transforms and reconstructs the data through an exclusive logical sum between the n-bit pixel data and the n-bit specific code value.