JP3809227B2 - Recording / playback device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a recording / reproducing apparatus that compresses an image signal input from a camera or the like, digitally records it on a recording medium, reproduces the data, and decompresses the data, and is particularly suitable for use in a system for printing a reproduced still image. The present invention relates to a recording / reproducing apparatus.
[0002]
[Prior art]
FIG. 10 shows a conventional system in which a camera input image is digitally recorded on a recording medium, and then reproduced and printed.
In FIG. 10, image information as a subject is collected by a lens 100, dispersed by a color filter 101, and then stored as an electrical signal in a solid-state imaging device 102 such as a CCD. In the case of using three CCDs (three-plate CCD), the color filter 101 is split into RGB (red, green and blue) by a prism and converted into an electrical signal by the CCD. When a single CCD (single-plate CCD) is used, it is split into YMCG (yellow / magenta / cyan / green) by a transmissive color filter and converted into an electrical signal by the CCD.
[0003]
The electrical signal converted by the solid-state imaging device 102 is corrected by the γ correction unit 103 so that each dispersed light amount becomes a non-linear display characteristic (γ characteristic) of the electronic monitor. The corrected electric signal of the light amount of each component is converted into 8-bit gradation digital data by the AD converter 104. The digital data indicating the light amount of each component is further converted into a luminance signal of the standard signal and two color difference signal (Y / Cr / Cb) components by the matrix conversion unit 105, and band-limited by the band filter 106 to be a moving image. It becomes image digital data which is one of the standard signals for handling.
[0004]
This standard signal image data is digitally recorded on a small cassette tape medium in the consumer DVC format, and the following processing is performed. First, the sampling unit 107 resamples the standard signal into 4-1-1 digital image data (525-60 system) or 4-2-0 digital image data (625-50 system). This is to compress the data amount of the standard signal by leaving the luminance signal having a large visual effect and thinning out the data of the two color difference signals in half. Furthermore, the amount of data is compressed by encoding the high frequency component of the data resampled by the image compression encoding unit 108. The compressed encoded data is processed by the error correction encoding unit 109, and the ability to correct transmission system errors is added to the digital data.
[0005]
After these processes, the digital data is correctly arranged in the data arrangement unit 110 so as to conform to the recording format of the cassette tape medium, then modulated by the digital modulation recording unit 111, and the magnetic tape medium 112 as the digital cassette tape. To be recorded.
Thus, the image information input from the camera is digitally recorded on the magnetic tape medium 112.
[0006]
Next, a procedure for reproducing the recorded data and printing image information of a still image will be described.
The electric signal reproduced from the magnetic tape medium 112 is demodulated as digital data by the digital reproduction / demodulation unit 113, and the digital data sequentially arranged so that the data can be processed by the data alignment unit 114 is subjected to error correction decoding. The conversion unit 115 corrects transmission system errors to increase data reliability and transfer image data to the printing system.
[0007]
In the printing system, first, the image data encoded by the image decompression decoding unit 116 is decompressed to restore the digital image data. The restored digital image data is subjected to inverse γ correction by the inverse γ correction unit 117 so as to match the linear display characteristics of the printer, and is brought close to data for reproducing the subject. Next, the standard signal component (Y, CR, CB) is converted into a coloring medium component such as ink or toner by the matrix conversion unit 118, and color printing is performed by the color printing unit 119 according to the digital data of each component. A color still image print image 120 is obtained.
[0008]
[Problems to be solved by the invention]
In the above conventional example, in order to digitally record digital image data captured by the camera input unit on a magnetic tape medium as a small cassette tape (consumer DVC format), image signals are converted in the following processing steps. Yes.
(1) The γ correction unit 103 corrects the non-linear display characteristic (γ characteristic) which is a display characteristic unique to the electronic monitor.
(2) The matrix conversion unit 105 performs matrix conversion of signal components that ensure color reproducibility that can be realized by an electronic monitor.
(3) The band filter 106 limits the band only to signal components that satisfy the display characteristics of the electronic monitor.
(4) The sampling unit 107 thins out the color difference signal of the standard signal component of the moving image in half.
[0009]
Among these, the one that has a great influence on the printing of still image information based on the consumer DVC format is given in (4). That is, the sampling unit 107 compresses the data amount of the image data specialized for visual characteristics based on a moving image. For this reason, even when a printing system with a wide gradation range is used, there has been a problem that it is not possible to obtain a high-definition color print image due to the data processing of this sampling portion.
[0010]
The γ correction process (1) is a process performed because of the non-linear color development characteristic of an electronic monitor. In a printing system having a relatively linear display characteristic, the γ correction process is performed. If it is not restored, printing faithful to the subject will not be performed. Therefore, the inverse γ correction unit 117 restores the linear display characteristics. However, in the consumer DVC format, 8-bit gradation data is secured in the γ correction state, and this is subjected to the inverse γ correction. In a printing system having a linear display characteristic, only a gradation of about 6 bits can be secured. On the other hand, some printing systems can reproduce 8-bit (256) gradations, and even if high-definition printing is performed using this system, sufficient image quality cannot be obtained due to the quantization error described above. There was a problem.
[0011]
Accordingly, an object of the present invention is to provide a recording / reproducing apparatus capable of recording information lost during processing when an input image signal is processed and digitally recorded, and obtaining a reproduced image obtained by restoring the information during reproduction. To do.
[0012]
[Means for Solving the Problems]
In the present invention, an image processing means for processing an input image signal, a first encoding means for compression-coding the image signal processed by the image processing means, and the image processing means Auxiliary signal extraction means for extracting information lost during processing to form auxiliary signals, a second encoding means for compressing and encoding the extracted auxiliary signals, and the first and second encodings Recording and reproduction processing means for recording the first and second encoded data encoded by the means on a recording medium in a predetermined format and reproducing them, and related information related to the auxiliary signal are stored in the storage means and read out. A storage control unit; a first decoding unit that decodes an image signal of a reproduction signal reproduced from the recording medium by the recording / reproduction processing unit; and the storage control unit that reads the image signal from the storage unit Based on related information Decoded by the reproduction auxiliary signal extraction means for extracting the auxiliary signal from the reproduction signal, second decoding means for decoding the auxiliary signal extracted from the reproduction signal, and the first decoding means. And image correction processing means for correcting the image signal with the auxiliary signal decoded by the second decoding means.
[0013]
[Action]
According to the present invention, information lost by, for example, the color difference signal thinning process or γ correction performed in the image processing means is recorded on the recording medium together with the image signal as the auxiliary signal, and the related information of the auxiliary signal is recorded on the recording medium. Is stored in a separate storage means, and an auxiliary signal is extracted based on the related information at the time of reproduction, and the reproduced image signal is corrected using this auxiliary signal, so that the lost information is restored and a high definition is obtained. An image can be obtained.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram of a printing system for still image information. FIG. 2 is a schematic view of a cassette for storing a recording medium. FIG. 3 is a diagram showing a recording format of the recording medium.
[0015]
In FIG. 1, reference numeral 1 denotes a lens that collects light rays of a subject, which is image information, 2 denotes a filter that decomposes the light rays into color components, 3 denotes a solid-state imaging device that accumulates the decomposed color light and converts it into an electrical signal. Is used. 4 is a γ correction unit, 5 is an AD conversion unit that converts an electric signal into digital data, and 6 is a luminance signal (Y) that is a signal component of a standard signal that handles one moving image image. A matrix conversion unit 7 for converting into two color difference signals (CR, CB) is a digital band filter that passes band component data of the standard signal.
[0016]
8 is a sampling unit that samples and thins out image data for digital recording on a recording medium in a consumer DVC format, and 9 is a coded data that uses the correlation of the image so that image quality deterioration is not noticeable. An image compression encoding unit for compressing, 10 is an error correction encoding unit for adding error correction capability to digital data, 12 is a modulation recording unit for digitally recording digital data on a recording medium, and 13 is a recording medium for digital data. Here, the magnetic tape medium 13 accommodated in the cassette type housing 13A shown in FIG. 2 is used.
[0017]
Reference numeral 14 denotes a reproduction demodulator that reproduces the digitally recorded magnetic tape medium 13 to generate digital data, 15 a data alignment unit that arranges the reproduced digital data in the processing order, and 16 an error correction code for an error in the digital data. An error correction decoding unit 17 that corrects by decoding, and an image decompression decoding unit 17 decompresses the compressed encoded image digital data to generate image digital data.
[0018]
Reference numeral 18 denotes a color correction unit that adds and corrects color difference auxiliary data, which will be described later, to image digital data, 19 denotes an inverse γ correction unit that reversely corrects digital image data of a standard signal having nonlinear display characteristics (γ characteristics), and 20 denotes image digital data. A matrix conversion unit that converts standard signal components (Y, CR, CB) of data into printing dye component signals, 21 is a color printing unit that prints each color according to each dye component signal, and 22 is digital still image information. It is a color still image print image printed in color.
[0019]
Reference numeral 23 denotes a color difference auxiliary signal extraction unit that extracts color difference information thinned out from the standard signal by the sampling unit 8 as a color difference auxiliary signal. Reference numeral 24 denotes a compression encoding unit that encodes the color difference auxiliary signal to compress the data amount. Is a system data section that compiles encoded color difference auxiliary signal data as part of system related data (system data) other than images and sound, and 26 performs serial communication to store part of the system data in the auxiliary storage medium 27. This is a serial communication unit to be performed. Reference numeral 27 denotes an auxiliary storage medium provided in a part of the tape cassette 13A shown in FIG. 2, which uses a solid-state storage memory. 28 is a still image auxiliary data extracting unit for extracting still image auxiliary data from the system data, 29 is a decompression decoding unit for decoding the encoded color difference auxiliary data, and 30 is a color difference auxiliary data extracting unit for extracting the color difference auxiliary data. .
[0020]
Next, an operation of inputting image information from the camera unit in the above configuration, recording it as digital data on a recording medium, and printing the reproduced digital image data by color still image will be described.
First, an operation for obtaining digital data by inputting image data from the camera unit will be described.
The light rays of the subject, which is image information data, are collected by the lens 1, and are decomposed into color light components by the color filter 2. As described in the conventional example, it is decomposed into three or four kinds of components such as RGB or YMCG according to the subsequent photoelectric conversion method. The separated color light is converted into an electric signal by each corresponding photoelectric conversion element. In general, a small-sized solid-state image sensor is often used as the photoelectric conversion element. In this embodiment, a CCD image sensor that accumulates light and converts it into an electrical signal is used.
[0021]
The converted electrical signal of each color component is nonlinearly corrected by the γ correction unit 4 so as to match the nonlinear characteristics of a general electronic monitor for displaying a moving image. The γ-corrected electrical signal of each color component is converted into digital data by the AD converter 5. The digital data of each color component is converted into a luminance signal (Y) which is one of the standard signals of the electronic monitor and two color difference signals (CR, CB) by the matrix converter 6. The band filter 7 limits the band of the three converted signals (Y, CR, CB) to the band of the standard signal. As described above, the image information is converted into an electrical signal by the camera unit, and further converted into digital data of three signals.
[0022]
Next, an operation for digitally recording this digital image data on a recording medium will be described.
First, since the three components (Y, CR, CB) of the standard signal are digitally recorded (consumer DVC format) on the magnetic tape medium 13 of the small tape cassette 13A as shown in FIG. CR, CB) is thinned out in half. This is because the luminance signal has a great influence on the resolution of the shape, and the color difference signal has a big influence on the resolution of the color, but when viewing a moving image as a human visual characteristic, the color difference signal is halved since the former is more important than the latter. I am trying to thin out. Specifically, 4-1-1 digital image signal (525-60 system with 525 horizontal scanning lines and 60 Hz frame period) in which the color difference signal (CR, CB) is one pixel for four pixels of the luminance signal, or Digital data of 4-2-0 digital image signal (625-60 system with a horizontal scanning line of 625, frame period of 50 Hz) in which the color difference signal (CR, CB) alternately becomes two pixels with respect to four pixels of the luminance signal. .
[0023]
The pixel data sampled as described above is further decomposed into frequency components by orthogonal transform (DCT), and operations such as encoding (Huffman encoding) that compresses high-frequency component data are image compression. The data amount is further compressed by being performed by the encoding unit 9. The image digital data compressed to an amount that can be digitally recorded on the magnetic tape medium 13 in this way is added with an error correction coding unit in order to add a correction capability that can be repaired to some extent even if an error occurs due to noise in the transmission system. At 10, a double Reed-Solomon error correction encoding process is performed. The digital image data subjected to the error correction encoding process is rearranged by the data array unit 11 so that it can be recorded on the magnetic tape medium 13. The digital recording modulation unit 12 modulates the digital data in a DC-free order in the rearranged order, and then performs digital saturation recording on the magnetic tape medium 13.
[0024]
As described above, image data (particularly moving image data) is recorded on the magnetic tape medium 13. The recording format is such that an oblique recording track T is formed in a guard bandless manner as shown in FIG. The image information data is recorded in the area c of each track T. Recording areas a and b are an area (a) that clearly specifies the recording system and an area (b) that records digital audio data. In addition, d is a subcode area in which a part of system data described later is recorded.
[0025]
Next, a recording operation of the color difference auxiliary signal for still image information, which is one of the features of the present invention, will be described.
The color difference signal data thinned out by the sampling unit 8 is extracted by the color difference auxiliary signal extraction unit 23 and used as a color difference auxiliary signal. Here, the thinned data is data (CR, CB) thinned when the digital image signal is sampled from the standard signal as described in the conventional example.
[0026]
The color difference auxiliary signal will be specifically described with reference to FIG. As shown in FIG. 4A, the difference between the thinned data and data obtained by interpolation from the adjacent sampling data is taken as a color difference auxiliary signal. For example, if the interpolation is linear interpolation within a scanning line, if the data to be sampled on both sides are 2 and 6, and the data to be thinned out is 5, the interpolation data is (2 + 6) / 2 = 4. The signal is 5-4 = 1. If the thinned data is 4, the color difference auxiliary signal is 4-4 = 0. Further, even when the interpolation is in a two-dimensional space (FIG. 4B) or in the time axis direction (FIG. 4C), the color difference auxiliary signal is difference information between the interpolation data and the thinned data. As shown in FIG.
[0027]
Next, referring back to FIG. In order to further compress the color difference auxiliary signal, the compression encoder 24 performs encoding. Specifically, it is effective to encode with zero run length, such as Huffman coding. Further, an ID is added to the encoded color difference auxiliary signal data, and the data is recorded in a recording format (consumer DVC format) as system data related to audio and image data.
[0028]
The structure of this system data is shown in FIG. The system data recorded on the magnetic tape medium 13 is as shown in FIG. The encoded color difference auxiliary signal data is converted into system data by the system data conversion unit 25 and sent to the error correction encoding unit 10 so that it can be recorded and stored on the magnetic tape medium 13. This system data is recorded on the magnetic tape medium 13 through the same processing (error correction coding, data arrangement, digital recording modulation) as the image information. In this case, the only difference between the image data and the system data including the color difference auxiliary data according to the present invention is that the image data is recorded in the subcode area d in FIG.
[0029]
On the other hand, part of the system data including the color difference auxiliary data is also transmitted to the serial communication unit 26. Part of the processing mode data indicating that a still image auxiliary signal is attached to the still image data of the standard signal together with the ID of the still image data, and contribution rate data indicating the contribution rate of the still image auxiliary data This is system data having a configuration as shown in FIG. This data is sent to the serial communication unit 26 and stored in the auxiliary storage medium 27 from here.
[0030]
As described above, for digital recording in a small cassette, for the still image data, the discarded color difference information is recorded on the magnetic tape medium 13 as the color difference auxiliary signal data of the system data, and also on the auxiliary storage medium 27. A code (the processing mode data and contribution rate data) indicating the presence or absence of processing and the quality of processing can be stored.
[0031]
Next, an operation for printing digital image data recorded on the magnetic tape medium 13 will be described.
The digital reproduction / demodulation unit 14 performs reproduction / demodulation work for generating original digital data from a digital signal waveform digitally saturated and recorded on the magnetic tape medium 13. The demodulated digital data is rearranged by the data alignment unit 15 for signal processing to be described later. The rearranged data is corrected by a data error in the transmission system by the error correction decoding unit 16 to improve data reliability. Here, for normal image data, the state encoded by the image decompression decoding unit 17 is decoded to generate original image data. However, the image data at this time is the same 4-1-1 digital image signal or 4-2-0 digital image signal as the data when the color difference signal is thinned and sampled.
[0032]
Here, the operation of correcting the color information according to the present invention and printing will be described.
First, among the system data read out from the auxiliary storage medium 27 by the serial communication unit 26, the data related to the still image information is extracted by the still image auxiliary data extraction unit 28. Here, the user designates image data to be printed as a still image.
[0033]
On the other hand, among the digital data reproduced from the magnetic tape medium 13 and error-corrected by the error correction decoding unit 16, system data including color difference auxiliary information is extracted by the still image auxiliary data extraction unit 28. Then, after collating the image data of the still image designated by the user with the color difference auxiliary data on the tape, the color difference auxiliary signal data is sent to the image decompression decoding unit 29. Since the color difference auxiliary data is encoded, it is decompressed by the image decompression decoding unit 29 and extracted by the color difference auxiliary data extraction unit 30 as color difference auxiliary data.
[0034]
The extracted color difference auxiliary data corrects the image data by the color correction unit 18. That is, the thinned color difference information is interpolated by the color correction unit 18, and the interpolation data is corrected by the color difference auxiliary data. Thus, the color difference thinning data lost in the moving image is reproduced in the case of a still image.
[0035]
Next, the color-corrected data is corrected for nonlinear display characteristics by the inverse γ correction unit 19, and the components of the standard signals (Y, CR, CB) are converted into printing dye components by the matrix conversion unit 20. Printing is performed by the printing unit 21. As a result, a high-definition color still image print image 22 is obtained.
[0036]
According to the present embodiment, the color difference auxiliary signal is used as difference data with respect to the interpolation data, and further the compression encoding process is performed, so that the data amount can be considerably reduced. Unlike the moving image display, these processes are performed only for printing of still image data, and therefore do not need to be real-time, and can be realized at low cost by processing in software.
[0037]
FIG. 6 shows a second embodiment of the present invention.
Since the present embodiment is a system in which the γ correction unit is also corrected in addition to the color difference auxiliary signal of the still image in the first embodiment, in FIG. 6, each block having the same operation as FIG. The same numbers are used, and duplicate descriptions are omitted.
In FIG. 6, reference numeral 36 denotes an AD conversion unit that AD converts an image signal from the image sensor 3 into digital data, and 37 denotes corrected image digital data subjected to display nonlinear characteristic (γ characteristic) correction and digital of the image signal. A residual calculation unit 38 for calculating a difference with the data, a matrix conversion unit 38 for converting the residual data of the decomposed light component of the subject into residual data of the signal component of the standard signal (Y, CR, CB), A band filter unit 39 limits the band of the residual data of the signal component.
[0038]
40 is a compression encoding unit that compresses still image auxiliary data by encoding, 41 is a system data conversion unit that handles the compression-encoded still image auxiliary data as system data related to images and sounds, and 42 is reproduced. A still image auxiliary data extracting unit 43 for extracting data related to the still image auxiliary data from the system data; 43, a decompression decoding unit that restores the encoded still image auxiliary data to the original data amount, and 44 Is a γ-corrected residual data extracting unit for extracting data related to γ-corrected residual from the still image auxiliary data, and 45 is a non-linear characteristic (γ characteristic) for moving image display, in order to obtain a substantially linear display characteristic signal. The inverse γ correction unit adds the γ correction residual data to the standard signal data.
[0039]
Next, an operation of inputting image information from the camera unit in the above configuration and recording it as digital data on a recording medium, and printing the recorded digital image data in a still image will be described.
First, an operation of inputting image data from the camera unit and converting it into digital data will be described.
The image information is decomposed into each light component through the lens 1 and the color filter 2 as in the first embodiment, and is converted into electrical signals of 3 to 4 types of components such as RGB or YMCG by the CCD image pickup device 3. Is done. The converted electrical signal of each color component is subjected to nonlinear correction by the γ correction unit 4 so as to match the nonlinear characteristic of moving image display, and converted to digital data by the AD conversion unit 5. The digital data of each color component is converted into a standard signal (Y, CR, CB) of the electronic monitor by the matrix conversion unit 6 and band-limited to the band of each signal (Y, CR, CB) by the band filter 7. As described above, the moving image processing part of the image information is converted by the camera unit into an electrical signal and further into digital data of three signals.
[0040]
On the other hand, as another process of the electrical signal of each color component electrically converted by the CCD image pickup device 3, it is directly converted into digital data by the AD converter 36, and the digital data directly converted from the γ-corrected digital data and Is calculated by the residual calculation unit 37. The γ-corrected residual data is converted into standard signal component data by the matrix conversion unit 38 and band-limited by the band filter 39 to the standard signal component band. As described above, the quantization error of linear data due to nonlinear γ correction of still image data is retained as γ correction residual data without being discarded.
[0041]
Next, an operation for digitally recording the digital image data on a recording medium will be described.
Since the recording operation of the three-component digital recording of the standard signal is the same as that of the first embodiment, the description is omitted. Here, the operation related to the still image auxiliary data centering on the handling of the γ correction error data described above will be described.
First, the color difference signal thinned out by the sampling unit 8 is extracted by the color difference auxiliary signal extraction unit 23, and data is transmitted as the color difference auxiliary signal. Specifically, it is the difference between the thinned data and the data obtained by interpolation from the adjacent sampling data, as in the first embodiment. Similarly, even when interpolation is performed in a two-dimensional space or in the time axis direction, the color difference auxiliary signal is given as a difference between the interpolation data and the color difference signal data to be thinned out.
[0042]
Next, an operation of compressing the data amount by encoding the color difference auxiliary signal data is performed by the compression encoding unit 40. On the other hand, the compression encoding unit 40 similarly performs a compression operation on the data amount of the γ correction residual data described above. These compressed still image auxiliary data are added with the same ID as the image data of the corresponding standard signal, and are recorded as system data in a small cassette recording format (consumer DVC format).
[0043]
The system data for recording the system data configuration on the magnetic tape medium 13 shown in FIG. 5 is shown in FIG. This still image auxiliary data is converted into system data by the system data converting unit 41. In order to record it on the magnetic tape medium 13, the error correction encoding unit 10 adds error correction capability together with the image data of the standard signal. Recording is performed on the magnetic tape medium 13 through the array unit 11 and the digital recording modulation unit 12. At this time, the recording format of the magnetic tape medium 13 is the same as in the first embodiment, in which the image data of the standard signal is recorded in the area c of FIG. 3, and the system data including the still image auxiliary data is d of FIG. Recorded in the area.
[0044]
A part of the system data including the still image auxiliary data is also transmitted to the serial communication unit 26. Some are processing mode data indicating that a still image auxiliary signal is attached to still image data of a standard signal, and contribution rate data indicating the contribution ratio of still image auxiliary data. ) System data. This data is sent to the serial communication unit 26 and stored in the auxiliary storage medium 27.
[0045]
In this way, for digital recording on a small-sized cassette tape, the γ correction residual data indicating the quantization error of the linear data due to the discarded color difference information or γ correction is used as the still image system data on the magnetic tape medium 13. And a code indicating the presence / absence of the process and the quality of the process can be stored in the auxiliary storage medium 27.
[0046]
Next, an operation for printing the digital image data recorded as described above will be described.
Digital data is detected from the magnetic tape medium 13 by the digital reproduction / demodulation unit 14, and after the data alignment unit 15, the data correction by the transmission system is corrected by the error correction decoding unit 16. Of the digital data, the image data related to the standard signal is decoded by the image decompression decoding unit 17 to become a 4-1-1 digital image signal or a 4-2-0 digital image signal.
[0047]
Next, an operation for correcting and printing color information according to the present invention will be described.
First, among the system data read from the auxiliary storage medium 27 by the serial communication unit 26, the data related to the still image auxiliary data is extracted by the still image auxiliary data extraction unit 42. Here, the still image data to be printed specified by the user is selected by the ID of the still image auxiliary data. On the other hand, system data including still image auxiliary data out of the digital data error-corrected by the error correction decoding unit 16 from the magnetic tape medium 13 is extracted by the still image auxiliary data extraction unit 42.
[0048]
After collating the ID of the still image data specified by the user with the ID of the still image auxiliary data on the tape, the corresponding still image auxiliary signal data is sent to the decompression decoding unit 43. The still image auxiliary data encoded here is decompressed, and color difference auxiliary data and γ correction residual data are generated. Of these, the color difference auxiliary data is extracted by the color difference auxiliary data extraction unit 30 and the color correction unit 18 corrects the image data. That is, the thinned color difference information is interpolated by the color correction unit 18, and the interpolation data is corrected by the color difference auxiliary data. As a result, similar to the first embodiment, the color difference thinning data lost in the moving image is reproduced when it is a still image.
[0049]
On the other hand, γ correction residual data of the decompressed still image auxiliary data is extracted by the γ residual data extraction unit 44 and added to the color corrected still image data described above by the inverse γ correction unit 45. . As a result, the inverse γ correction for returning the non-linear display characteristic (γ curve characteristic) of the still image data to the linear display characteristic is performed while securing an 8-bit quantization error. Next, each component (Y, CR, CB) of the standard signal subjected to the inverse γ correction is converted into a dye component for printing by the matrix conversion unit 20, and printing is performed by the color printing unit 21. Through the above operation, a high-definition color still image print image 22 is obtained.
[0050]
According to the present embodiment, as the still image auxiliary data, the color difference auxiliary data and the γ correction residual data are retained as the minimum necessary difference data, and further subjected to the compression encoding process. Can be small. Unlike the moving image display, these processes are performed only at the time of printing the still image data. Therefore, it is not necessary to have real-time characteristics, and can be realized at low cost by processing in software.
[0051]
FIG. 7 shows a third embodiment of the present invention.
In the present embodiment, the still image auxiliary data stored in the auxiliary storage medium is used during reproduction for the operation for designating the printing of still image data in the first and second embodiments. Accordingly, the operation relating to recording of still image auxiliary data is exactly the same as that in the first and second embodiments, and thus description thereof is omitted. Further, regarding the printing operation, in FIG. 7, blocks having the same functions as those described above are denoted by the same reference numerals and the description thereof is simplified.
[0052]
In FIG. 7, reference numeral 50 is a list of still image data IDs and types and qualities of auxiliary recording data, and a still image menu generating unit for displaying a selectable menu screen. 51 is a still image selected on the menu screen. Still image processing data search unit for instructing image reproduction means to search for image data and still image auxiliary data from ID, and 52 for still image correction printing control for instructing image correction means for still image correction processing mode of reproduced image data Part.
[0053]
Next, an operation in which the user selects and prints digital image data recorded on the magnetic tape medium 13 will be described.
First, among the system data read out from the auxiliary storage medium 27 by the serial communication unit 26, data related to still image auxiliary data is extracted by the still image auxiliary data extraction unit 42. As described in the explanation of the recording operation in the first and second embodiments, the data called from the system data includes the still image data ID and the still auxiliary image signal attached to the standard still image data. This is contribution rate data indicating the contribution rate of the processing mode data indicating that the image data is still present and the still image auxiliary data. The system data related to the still image auxiliary data is first sent to the still image menu generation unit 50. Here, a menu screen on which data related to still image processing and related data (not shown) such as recording time and date / time of still image images from other system data can be listed is displayed on an electronic monitor or the like. This is shown in FIG.
[0054]
Here, in addition to guessing the content of still image information by looking at the date and time, the user adds what still image auxiliary data to the still image (still image processing mode data) and how effective the processing is. (Contribution rate data) can be recognized. This data can be used as a guide when performing high-definition still image printing. The still image printing capability is characterized by various printing systems. There are various options for still image printing, such as those that excel at gradation reproduction and those that excel at resolution reproduction.
[0055]
The above still image processing mode data and contribution rate data can be used as a guide for this selection. For example, if color difference auxiliary data is attached to certain still image information as system data and the contribution ratio is large, printing may be performed with a high gradation printing system. Further, if the contribution ratio to the blue tone is large, high-definition printing can be realized by printing with a printing system with good blue color reproducibility. Furthermore, if the contribution ratio of the γ correction residual data is large, it is effective to print with a printing system that excels in linear color reproducibility. Furthermore, when image quality auxiliary data is not attached, the image quality is the same, but if printing is performed with a high-speed printing system, the correction processing time can be saved, which is effective for mass high-speed printing. In this way, the user can select still image printing according to the characteristics of the printing system using the still image processing mode data and the contribution rate data as a guide.
[0056]
As described above, the still image menu generation unit 50 selects a still image to be printed by the user, and sends the corresponding still image ID and still image processing mode data to the still image processing data search unit 51. The still image processing data search unit 51 generates a control code for searching for a still image with a still image ID and sends still image processing mode data to the still image correction print control unit 52. The still image correction printing control unit 52 generates a control code for performing image correction using auxiliary data based on the still image processing mode data.
[0057]
Next, an operation for retrieving a still image with the still image ID (image data reproduction operation by the still image processing data retrieval unit 51) will be described. Still image data is retrieved from the magnetic tape medium 13 using the ID of the still image auxiliary data. The retrieved image data is decoded by the image decompression decoding unit 17 through the digital reproduction demodulation unit 14, the data alignment unit 15, and the error correction decoding unit 16, and the image data of the standard signal is reproduced. On the other hand, the still image auxiliary data in the system data recorded on the magnetic tape medium 13 is also extracted by the still image auxiliary data extracting unit 42 according to the ID to be searched and decompressed and decoded according to the control code of the still image processing searching unit 51. Is decoded by the converting unit 43, and either or both of the γ correction residual data extraction unit 44 and the color difference auxiliary data extraction unit 30 are processed, and still image auxiliary data such as color difference auxiliary data or γ correction residual data. Is generated.
[0058]
Next, an image correction process using a control code for performing image correction (an output from the still image correction print control unit 52) and its printing operation will be described.
The control code for image correction sent from the still image correction printing control unit 52 controls the color correction unit 18 of the image data of the standard signal from the image expansion decoding unit 17. That is, if the still image processing mode data is color difference auxiliary data, the color correction unit 18 is operated, and if the still image processing mode data is γ correction residual data, the inverse γ correction unit 45 is operated. If both of the data are present, both are operated, and if there is no correction data, this portion is passed.
[0059]
First, the color correction unit 18 corrects the image data of the standard signal with the color difference auxiliary data extracted by the color difference auxiliary data extraction unit 30. That is, the thinned color difference information is interpolated by the color correction unit 18, and the interpolation data is corrected by the color difference auxiliary data. As a result, the color difference thinning data lost in the moving image is reproduced for the still image as in the first embodiment. On the other hand, for the inverse γ correction unit 45, the γ correction residual data extracted by the γ correction residual data extraction unit 44 is added to the color-corrected still image data. As a result, the non-linear display characteristic (γ curve characteristic) of the still image data is corrected by securing an 8-bit quantization error to the linear display characteristic.
[0060]
The image data corrected as described above is further processed by the matrix conversion unit 20 so as to be converted from the respective components (Y, CR, CB) of the standard signal to the dye component for printing, and then the color printing unit 21. Will be printed.
[0061]
As described above, according to the present embodiment, the user can easily select the printing of the still image data suitable for the printing system, search and correct the still image based on the auxiliary data, and effective high-definition still image printing can be performed. It is a system that can be realized.
In addition, according to the present embodiment, the still image menu generation unit 50 can list the attributes and contribution ratios of the still image auxiliary data, so that effective high-definition still image printing can be specified and batch printing can be performed. Is also effective.
Furthermore, according to the present embodiment, by providing means for invalidating the still image processing mode data of the still image auxiliary data in the still image menu generating unit 50, correction processing with a low contribution rate can be omitted or the print system can be omitted. It is possible to omit correction processing that is not affected, and an efficient printing system can be realized by shortening the image processing time.
[0062]
FIG. 9 shows a fourth embodiment of the present invention.
This embodiment is a case where the user rewrites or deletes the still image auxiliary data in the first and second embodiments so as to suit the printing system. Accordingly, the operation relating to recording of still image auxiliary data and the operation of reproducing and printing are the same as those in the first and second embodiments, and thus the description thereof is omitted. In FIG. 9, the same numbers are assigned to the same operations as those in the first and second embodiments, and the description thereof is also omitted.
[0063]
In FIG. 9, 60 is a manual correction unit for manually correcting the correction of reproduced image data, 61 is a display coefficient of display characteristics by setting a multiplication coefficient of γ correction residual data for inverse γ correction of image data. An inverse γ correction unit 62 that can set linearity, 62 is a color correction unit that can set the balance of gradation reproducibility of image data by independently setting the multiplication coefficient of color difference auxiliary data (CR, CB), and 63 is stationary Γ correction residual data correction unit for storing and correcting γ correction residual data of image auxiliary data, 64 a color difference auxiliary data correction unit for storing and correcting color difference auxiliary data of still image auxiliary data, and 65 from the magnetic tape medium 13. A digital image data memory unit storing digitally reproduced digital image data.
[0064]
Next, an operation for changing the still image auxiliary data recorded on the magnetic tape medium 13 to still image auxiliary data manually set by the user will be described.
First, as in the first and second embodiments, digital image data and still image auxiliary data desired to be printed are read from the magnetic tape medium 13, and the digital image data memory unit 65, the γ correction data correction unit 63, and the color difference are respectively read. The data is stored in the auxiliary data correction unit 64. The digital image data downloaded from the digital image data memory unit 65 sets the balance of gradation reproducibility by the color difference signal in the color correction unit 62. That is, the color correction unit 62 generates a color difference signal thinned out from the digital image data as interpolation data, and further adds the color difference auxiliary data downloaded from the color difference auxiliary data correction unit 64 to the interpolation data, thereby performing the thinning. The reproduced color difference signal data is reproduced. Further, the color correction unit 62 can perform an operation of multiplying the color difference signal data to be added by a coefficient specified by the manual correction unit 60. Therefore, when the user operates the manual correction unit 60 and designates the color difference signal data multiplication coefficient for each color difference signal (CR, CB), the balance of the gradation reproducibility of the image data can be changed.
[0065]
The image data in which the balance of gradation reproducibility is corrected by the operation of the color correction unit 62 described above is sent to the inverse γ correction unit 61. The inverse γ correction unit 61 adds the γ correction residual data downloaded from the γ correction residual data correction unit 63 to the image data, thereby linearly changing the non-linear display characteristics (γ curve characteristics) of the still image data. An 8-bit quantization error is secured and returned to the correct display characteristics. Further, the inverse γ correction unit 61 can perform an operation of multiplying the γ correction residual data to be added by a coefficient specified by the manual correction unit 60. Therefore, when the user operates the manual correction unit 60 and designates the γ correction residual multiplication coefficient, the linearity of the display characteristics of the image data can be changed.
[0066]
The image data in which the linearity of the display characteristics of the inverse γ correction unit 61 is corrected is printed by the color printing unit 21 via the matrix conversion unit 20. The user sees the color still image print image 22 and determines whether or not to further perform manual correction. When the correction is performed, the above-described operation is repeated.
[0067]
On the other hand, if the image quality of the color still image print image 22 satisfies the user, the user operates the manual correction unit 60 to send the designated multiplication coefficient to the inverse γ correction unit 61 and the color correction unit 62 again. Each correction unit 61, 62 multiplies the respective correction data by the designated multiplication coefficient, and sends it to the γ correction residual data correction unit 63 and the color difference auxiliary data correction unit 64. The γ correction residual data correction unit 63 and the color difference auxiliary data correction unit 64 rewrite the respective still image auxiliary data and send them to the compression encoding unit 24 to compress and encode the still image auxiliary data. Further, the system data conversion unit 25 converts the still image auxiliary data into system data and records it on the magnetic tape medium 13 through the error correction encoding unit 10, the data array unit 11, and the digital modulation recording unit 12. On the other hand, what is stored in the auxiliary storage medium 27 is processed via the serial communication unit 26.
[0068]
As described above, in the present embodiment, the user can correct and set still image auxiliary data so as to suit the printing system, and can store the data on the magnetic tape medium 13 as the still image auxiliary data. Has been made.
Further, according to the present embodiment, by setting the multiplication coefficient to zero, if there is a setting for invalidating the still image auxiliary data, the still image auxiliary data itself is erased, thereby recording the recording medium. The area can be used effectively.
[0069]
In the first to fourth embodiments described above, the still image auxiliary data is limited to the γ correction and the color difference signal. However, other than that, for example, color space distortion due to matrix conversion is corrected. Data or the like may be still image auxiliary data.
[0070]
【The invention's effect】
As described above, according to the present invention, information lost by image processing during recording can be restored during reproduction, and a high-definition still image can be obtained.
[0071]
In addition, by displaying a still image menu based on related information related to lost information and enabling a still image estimated from this menu to be searched, a user can obtain a desired still image with high definition, Editing etc. can be performed easily.
[0072]
Further, by allowing the user to manually control the image correction, for example, when a reproduced image is printed, a reproduced image suitable for the printing system can be formed.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a still image printing system according to a first embodiment of the present invention.
FIG. 2 is an external perspective view of a cassette for storing a recording medium.
FIG. 3 is a configuration diagram showing an outline of a recording format of a recording medium.
FIG. 4 is a configuration diagram illustrating a method of generating auxiliary color difference data according to the present invention.
FIG. 5 is a configuration diagram of system data of still image auxiliary data according to the present invention.
FIG. 6 is a block diagram showing a still image printing system according to a second embodiment of the present invention.
FIG. 7 is a block diagram showing a still image printing system according to a third embodiment of the present invention.
FIG. 8 is a configuration diagram of a still image menu selection screen according to the third embodiment of the present invention.
FIG. 9 is a block diagram showing a still image printing system according to a fourth embodiment of the present invention.
FIG. 10 is a block diagram showing a conventional still image printing system.
[Explanation of symbols]
2-color filter
3 Solid-state image sensor
4 γ correction unit
8 Sampling part
9 Image compression encoding unit
11 Data array part
12 Digital modulation recording section
13 Magnetic tape media
14 Digital reproduction demodulator
15 Data array part
17 Image decompression decoding unit
18 color correction unit
19 Inverse γ correction unit
22 Color still image print image
23 Color difference auxiliary signal extraction unit
24 Compression encoding unit
25 System Data Conversion Department
26 Serial communication part
27 Auxiliary storage media
28 Still image auxiliary data extraction unit
29 Decompression decoding unit
30 Color difference auxiliary data extraction unit
37 Residual calculation unit
40 Compression encoder
41 System Data Department
42 Still image auxiliary data extraction unit
43 Decompression decoding unit
44 γ correction residual data extraction unit
45 Reverse γ correction unit
60 Manual correction section
61 Inverse γ correction unit
62 Color correction unit
63 γ correction residual data correction unit
64 Color difference auxiliary data correction part

Claims (10)

Image processing means for processing an input image signal;
First encoding means for compressing and encoding the image signal processed by the image processing means;
Auxiliary signal extraction means for extracting information lost when the image processing means processes the image signal to form an auxiliary signal;
Second encoding means for compressing and encoding the extracted auxiliary signal;
Recording and reproduction processing means for recording the first and second encoded data encoded by the first and second encoding means on a recording medium in a predetermined format and reproducing the data,
Storage control means for storing and reading related information related to the auxiliary signal in the storage means;
First decoding means for decoding an image signal among the reproduction signals reproduced from the recording medium by the recording / reproducing processing means;
Reproduction auxiliary signal extraction means for extracting the auxiliary signal from the reproduction signal based on the related information read from the storage means by the storage control means;
Second decoding means for decoding the auxiliary signal extracted from the reproduction signal;
A recording / reproducing apparatus comprising: an image correction processing unit that corrects the image signal decoded by the first decoding unit with the auxiliary signal decoded by the second decoding unit. The image processing means performs a process for thinning out the color information signal forming the image signal, and the extraction means is obtained by interpolation from the thinned color information signal and the adjacent color information signal. The recording / reproducing apparatus according to claim 1, wherein a difference from a signal is extracted as the auxiliary signal. The image processing means performs gamma correction processing of the image signal, and the extraction means extracts a difference signal between the gamma-corrected image signal and an image signal not gamma-corrected as the auxiliary signal. The recording / reproducing apparatus according to claim 1. The recording / reproducing apparatus according to claim 1, wherein the related information includes identification information indicating that the still image has the auxiliary signal. 2. The recording / reproducing apparatus according to claim 1, wherein the related information includes information indicating a contribution rate that the auxiliary signal can contribute to correction in the image correction processing unit. A menu generation unit that generates a display still image menu based on the related information read from the storage unit, and a still image specified based on the displayed menu is searched for from the image correction processing unit. 5. A recording / reproducing apparatus according to claim 4, further comprising search means for outputting. 2. A recording / reproducing apparatus according to claim 1, further comprising control means for controlling correction in the image correction processing means by a user. 2. The recording / reproducing apparatus according to claim 1, further comprising an imaging unit for obtaining the input image signal. 2. The recording / reproducing apparatus according to claim 1, further comprising printing means for printing the image corrected by the image correction processing means. The recording / reproducing apparatus according to claim 1, wherein the storage means is provided in a housing for storing the recording medium.

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