JPH1011573A - Image processor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To minimize a capacity necessary for storing an image family by executing gradation processing with respect to original image information based on a gradation converting table and output-displaying an obtained processed image. SOLUTION: A processing control part 58 commands a file input/output control part 51 to read image data in an original file and refers to a header information format table 59 to identify the kind of processing stored in the header of a processed file to call a corresponding processing function within an image processing part 55. The called image processing function, while referring to corresponding image processing information format in the table 59, reads an image processing parameter from an image processing information part in the header of the processed file to establish a processing condition and then image-processes image data stored in a data storing part 54. A control part 53 outputs image-processed image data to an image output device 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing apparatus for reproducing an image by storing an image family composed of an original image and a processed image, and more particularly to a case where a stimulable phosphor plate is used. Related to an image processing apparatus.

[0002]

2. Description of the Related Art Conventionally, in image processing technology, when image data (called an original image) stored in a storage device is subjected to a certain type of image processing by an image processing device, an image after processing is processed. It is frequently seen that data (called processed images) is stored again in the storage device. For example, in an image having a wide dynamic range from a low-density region to a high-density region, an image of only a low-density region or an image of only a high-density region obtained by gradation conversion is necessary for some research or diagnostic purposes. In some cases, or when it is desired that the processed images can be referenced (reproduced) later as necessary, these processed images are usually stored in a storage device.

In such a case, in the prior art, a method has been adopted in which image data of each processed image is stored in a storage device, but in this method, FIG.
One original image data D ₀ as shown in FIG.
, And a plurality of processed image data D ₁ , D ₂ ,..., D _n, and one image family is formed for one original image data. The image family referred to here is one original image data D
₀ a plurality of processing the image data D _1, ... is defined as the mass of the image data to be formed by D _n.

However, the conventional method of reproducing image information to be processed based on such a storage method has the following disadvantages.

For example, suppose that the storage capacity required to store the original image data is N (assuming that the image size does not change due to the image processing performed on the original image), and the image processing is performed on the original image. Assuming that the number of obtained images is m, the total storage capacity M required to store this family is M = (1 + m) N. Therefore, even when m is 1, twice the capacity of the original image data is required, and M increases linearly with the increase in m. Thus, the conventional storage method can be said to be an inefficient storage method even if a device having a large storage capacity such as an optical disk device is used as the storage device.

[0006]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the conventional storage method, and aims to minimize the capacity required for storing an image family consisting of an original image and its processed image. An object of the present invention to achieve the above object is to provide an image input unit for inputting image information obtained by reading a stimulable phosphor plate, and an image based on the image information input by the image input unit. An image processing device that performs processing and obtains a processed image, and an image output unit that outputs and displays the processed image obtained by the image processing unit. Based information is stored as original image information, and when the image processing is gradation processing, information indicating that the image processing is gradation processing; And a storage unit for storing a gradation conversion table, which is a processing content applied to the original image information, in association with the original image information, wherein the image processing unit outputs and displays the processed image. At this time, an image obtained by performing gradation processing on the original image information based on the information indicating that the image processing is gradation processing and the gradation conversion table stored in the storage unit. The processed image is output and displayed on the image output means.

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail.

In the image reproducing method according to the present invention, the storage capacities required for the header section and the image data section are each ε.
And N, the total storage capacity M required by the family having m processed images is M = (ε + N) + mε = N + (1 + m) ε, where ε is a very small value compared to N Therefore, the increase in M due to the increase in the number of processed images can be almost ignored. If the average storage capacity required for one image in the family is L, The average storage capacity L required for one image decreases rapidly as the number m of processed images increases.

Since L ≒ N according to the conventional storage method, the storage method according to the image reproducing method of the present invention requires an average amount of information per image of about (m) compared to the conventional storage method.
+1). That is, in a family in which m processed images exist, the same effect as when (m + 1) images in the family are compressed and stored to about (m + 1) times each is obtained. For example, when the value of m is 9, it is equivalent to about 1/10 compression of the image data of each image constituting the family.

FIG. 5 shows the configuration of a header in the present storage method. As shown in FIG. 5B, the header includes two parts, a processing target file pointer part and an image processing information part. Is included. The processing target file pointer section stores information indicating where the image file to be processed is stored in the storage device. For example, the address information in the storage device of the image file to be processed is It is remembered. The image processing information section stores image processing information such as information indicating the type of image processing to be performed on the image data to be processed indicated by the processing target pointer section and the processing content. For example, if the image processing to be performed is gradation conversion processing, information indicating that the processing is gradation conversion processing (referred to as a type of processing), the gradation conversion table itself used for the processing, or Information (referred to as processing content) that can refer to this and information supplementing the processing content are stored.

FIG. 6 shows various examples of the image processing information format. FIG. 6A shows an example of the image processing information format stored in the header when the image processing is gradation conversion. In this example, the image processing information includes (1) information indicating that the type of processing is gradation conversion, (2) information amount per pixel of the target image (K bits), and (3) pixel value 0 of the target image. It is composed of three pieces of information of gradation conversion table information in which pixel values after gradation conversion for .about. (2 ^k -1) are arranged in 2 ^k k bits each.

When the image processing to be performed is frequency processing by a convolution method using a digital filter, information (type of processing) indicating that the processing is frequency processing by a convolution method using a digital filter, The digital filter matrix itself to be used for processing, or information (processing content) that can refer to the digital filter matrix and information supplementing the processing content are stored in the header.

FIG. 6B shows an example of a format of image processing information stored in a header when image processing is frequency processing by a convolution method using a digital filter. In the case of this example, the image processing information includes (1) information indicating that the processing is frequency processing by a convolution method using a digital filter, and (2) each element required to store a digital filter matrix in a header. (3) The number of lines (n) and the number of columns (m) of the filter matrix (4) Each element (1, 1) to (n, m) of the nxm digital filter matrix It consists of digital filter matrix information in which n × m values are arranged in k bits.

FIG. 6C shows an example of the format of image processing information stored in the header when the image processing to be performed is frequency processing using orthogonal transformation.

In the case of this example, the image processing information includes: (1) information indicating that the processing is frequency processing using orthogonal transformation; and (2) the type of orthogonal transformation applied to the image data (for example, Fourier transformation, cosine Information indicating transformation, Hadamard transformation, gradient transformation, etc. (3) Information amount (k bits) required to store in the header each weight coefficient multiplied by the transformation coefficient obtained by orthogonal transformation (4) Header (For example, the real number of a fixed-point number indicates the number of bits stored in each of the integer part and the decimal part). (5) The number of lines in the weight matrix (n ) And the number of columns (m) (6) Each element (1, 1) to n × m weight matrix
The value (n, m) is composed of weight matrix information in which n × m pieces of k bits are arranged in accordance with the format shown in the above (4).

FIG. 6D is a modification of the information shown in FIG. 6C. For example, when a weight matrix of a weight coefficient to be multiplied by a transform coefficient is prepared in advance and stored in a storage device or the like, information indicating the weight matrix stored as information indicating the processing content is stored. deep. For example, when a plurality of weight matrices are prepared, a number assigned to each matrix in advance may be stored. The format shown in FIG. 6D can be applied to other than frequency processing using orthogonal transform.

As described above, the storage format of the information stored in the image processing information section of the header may be any format as long as the same processing can be reproduced from this information. The image processing is not limited to the gradation processing and the frequency processing as long as the processing contents can be stored in a format in which the processing can be reproduced. For example, it may be a geometric transformation (coordinate) transformation such as a projective transformation and an affine transformation which is a special case thereof. For example, the two-dimensional affine transformation is the equilibrium movement, rotation,
In the conversion that enlarges and reduces, the coordinate system of the image before conversion is x-
Assuming that the coordinate system of the converted image is a uv coordinate system and the y coordinate system is

[0018]

(Equation 1) It is expressed as When (x, y) is represented using (u, v),

[0019]

(Equation 2) Become. From this equation, a point (x, y) before the conversion corresponding to the grid point (u, v) after the conversion is obtained.
y is a real value, so (x, y) is a non-grid point. Therefore, it is necessary to obtain the density value of the non-grid point (x, y) by interpolation. The simplest interpolation method is a nearest neighbor method using a grid point density value in an (xy) coordinate system closest to the non-grid point (x, y), and a more accurate method is a non-grid point ( There are a linear interpolation method that performs linear interpolation using density values at four grid points around (x, y), and a cubic convolution method known as a high-precision interpolation method. Thus, for a certain image, when the image processing applying the two-dimensional affine transformation, determined conversion factor to determine the two-dimensional affine transformation a, b, c, d, t x, the t _y or 2-dimensional affine inverse transform The storage method according to the present invention can be applied by storing the conversion coefficient and the type or interpolation formula of the interpolation method for obtaining the density of the non-grid point in the header as image processing information.

Other image processing, such as various orthogonal transforms (Fourier transform, cosine transform, Hadamard transform, slant transform, etc.), filtering using a digital filter and not using a convolution method (for example,
Regarding image cutout, simple pixel rearrangement (for example, 90 ° rotation of image, corner turn, etc.) and dither method, the contents of these image processing information should be stored in the header section even when processing with a median filter. Thereby, the storage method according to the present invention can be applied.

Under the above-described image file configuration,
An embodiment of the present invention will be described with reference to FIG.

FIG. 1 is a block diagram showing an embodiment of an image reproducing apparatus according to the present invention. In FIG. 1, reference numeral 1 denotes an image recorded on an image information storage medium such as paper, film, or stimulable phosphor plate. An image input device that reads image information and outputs it as a digital signal. For example, the image information in a recording medium is converted into an electric signal by mechanical scanning with a laser beam or the like or electrical scanning of an element such as a CCD. This is a device that outputs a digital signal by a / D converter. However, if the output signal from the image input device 1 is a digital signal, the image information recording medium, the mechanism of the image input device, and the number of devices are not limited at all.

Reference numeral 2 denotes an image output device for outputting or displaying an image as visually recognizable information. For example, it may be a device that hard copies an image on paper or film, or a display device such as a CRT that displays an image. The number of these devices may be plural, and different types of devices may be arranged in parallel.

Reference numeral 3 denotes a storage device for storing files such as image data, such as a magnetic disk device and an optical disk device.

Reference numeral 4 denotes an operation table in which a user inputs processing commands such as image processing by the image processor 5, image input from the image input device 1, and image output to the image output device 2, and is a terminal device having a keyboard, for example. is there.

The image processor 5 (indicated by a dashed line) is a device for analyzing a command input from the operation table 4 and executing the commanded process.
A file input / output control unit 51 for controlling input / output of files such as image files stored in the storage device, a file management unit 52 for managing files such as image files stored in the storage device 3, and an image input device 1 And a data input / output control unit 53 for controlling input / output of image data with the image output device 2, a data storage unit 54 for temporarily storing information such as image data, and various types of image processing such as gradation processing and frequency processing. An image processing unit 55 having a processing function, a header processing unit 56 having a function of creating a header, a processing control unit 58 for giving a processing instruction to each unit in accordance with an instruction received from the instruction analyzing unit 57, and an input from the operation table 4. A command analysis unit 57 that analyzes the received command and gives an instruction to the processing control unit 58;
Header information format table 5 that stores a format of header information such as an image processing information format.
9.

Next, the operation of the image reproducing apparatus having the above configuration will be described with reference to the flowchart of FIG.

The operation of the present apparatus is classified into the following three. (1) Input → storage operation (2) Processing → storage operation (3) Read → output operation First, (1) input → storage operation will be described.

When an input → storage command is input from the operation table 4 (F-1), the command analyzer 57 analyzes the content of the command (F-2) and outputs an instruction to the processing controller 58. As a result, the image information stored in the image storage medium is read by the image input device 1 (F-3). The processing control unit 58 outputs a header creation command to the header processing unit 56, and the header processing unit 56 creates a new header in the data storage unit 54. In the header, original file identification information indicating that the file has the original file, that is, the image data section next to the header section, is stored (for example, a special value such as zero is stored in the processing target file pointer section or the original file identification information is stored). The original file can be identified by providing a flag indicating that the file is a file) (F-4). Further, other necessary information, for example, the size of image data and storage capacity information (for example, the number of bits) required to store one pixel of image data may be stored in a format common to each image processing.

Next, the processing control section 58 outputs an image data input command to the data input / output control section 53, and the data input / output control section 53 converts the image data sent from the image input apparatus 1 into data. The information is stored in the storage unit 54. The file input / output unit 51 stores the header and the image data stored in the data storage unit 54 as one image file (original file) in the storage device 3 according to a command from the processing control unit 58 (F-5), and In the file management unit 52,
Register the stored image file.

In the present invention, the image input device 1
The data compression process is performed from the time when the image data is input to the time when the image data is stored in the storage device 3 as the original file. This data compression may be performed any time before the data is stored in the storage device 3, and is not particularly limited. For the compression ratio,
There is no particular limitation as long as image quality degradation is not a problem. For example, when an image file obtained by compressing image data by 1/10 is stored as an original file, the value of m is set to 9 as described above. Then, about 1/100 (1/10 × 1)
/ 10 = 1/100), it is possible to bring about an enormous effect in terms of a reduction in storage capacity because it requires only the same amount of information as when compression is performed. As a result, it is possible to obtain reproduced image information with good image quality as compared with the case where data compression of about 1/100 is performed. In addition, for example, the image data is
Is stored as an original file, and if the value of m is 1, the image data constituting the family is approximately 約 (１ ／ × 1/1).
2 = 1/4), the amount of information is equivalent to that of compression, so that a great effect can be brought about in terms of reduction of storage capacity, and in addition to actual image data constituting a family, Reproduced image information with good image quality can be obtained as compared with the case where data compression of about a quarter is performed. That is, if the image storage method according to the present invention is used,
Regardless of the size of the data compression ratio for the original image and the number of images in the family,
This makes it possible to reduce the storage capacity and obtain a reproduced image with good image quality. Thus, the input → storage operation is completed.

Next, the (2) processing → storage operation will be described.

A processing-> storage command is input from the operation table 4 (F-1) (here, a command for performing one image processing on the image data of the original file stored in the storage device 3 is input). Command analysis unit 57 analyzes the content of the command (F-2), and gives an instruction to the process control unit 58. The header processing section 56 receives a command from the processing control section 58, creates a new header section in the data storage section 54 and searches the header management section 52,
The information (for example, address information) indicating the storage location of the original file to be processed in the storage device 3 is checked and set in the file pointer to be processed in the header (F-6, F-7).

The header processing section 56 refers to the corresponding image processing information format in the header information format table 59 and sets the image processing contents to be processed as image processing information in the image processing information section in the header. (F-8). When all the information is set in the header, the file input / output control unit 51 receives the instruction from the processing control unit 58, stores the header, that is, the processed file in the storage device 3, and (F-9) the file management unit 52 Then, the newly stored processed file is registered (here, the processed file is a file consisting only of the header part storing the image processing information). Thus, the processing → storage operation is completed.

Next, (3) the read → output operation will be described. Reading from the operation table 4 → output command is input (F-1) Here, the image file specified by the user as an output target is an original file or a processed file which stores one image processing for the original file. Suppose there is. The command analysis unit 57 analyzes the content of the command (F-2) and gives an instruction to the processing control unit 58. File input / output control unit 51 receiving a command from processing control unit 58
After the file management unit 52 searches the storage location of the file to be output specified by the user, only the header of the file is read from the storage device 3 (F-1).
0), and stored in the data storage unit 54. Header processing unit 56
Checks the original file identification information of the header written in the data storage unit 54, and determines whether the file is an original file (F-11).

If the file is an original file, the processing control unit 58 instructs the file input / output control unit 51 to read the image data portion of the file (F-1).
3) The image data is stored in the data storage unit 54. The data input / output control unit 53 receives the command from the processing control unit 58, outputs the image data stored in the data storage unit 54 to the image output device 2 (F-15), and ends the storage → output operation.

If the file is not the original file, that is, if the file is a processed file (the storage location of the original file in the storage device 3 is stored in the processing target pointer section of the header)
The processing control unit 58 instructs the file input / output control unit 51 to read the image data of the original file, and (F-12, F-13) refers to the header information format table 59 and stores the image data in the header of the processed file. The type of the processing being performed is identified, and the corresponding processing function in the image processing unit 55 is called. The called image processing function reads the image processing parameters from the image processing information section in the header of the processed file while referring to the corresponding image processing information format in the header information format table 59, and establishes the processing conditions. Performs image processing on the image data stored in the data storage unit 54 (F
-14).

The data input / output control unit 53 includes a processing control unit 58
(F-15), the image data that has been subjected to the image processing and stored in the data storage unit 54 is output to the image output device 2 (F-15). Thus, the storage-> output operation ends.

The operation shown in the above embodiment is performed by the storage device 3
In the family stored in FIG. 5, a processed file obtained by performing one image process on the original file or the image data of the original file (ie, FIG.
Although only the case where the value of the image processing information number n in (c) is 1 and the processing file pointer portion is a processing file having a header storing the storage location of the original file) is described, In the image reproducing method of the invention, the number of pieces of image processing information stored in the header is not limited to one.

For image data to be processed, n (n
When the image processing of> 1) is performed, n pieces of image processing information are stored in the image processing information section as shown in FIG. When a plurality of pieces of image processing information are stored in the header as described above, for example, k (1 ≦ k ≦ (n−1), n ≧
2) If a pointer indicating where the (k + 1) th image processing information is stored in the header is provided in the second image processing information, each image can be obtained even if the storage capacity required for each image processing information is not constant. It is possible to know the storage location of the processing information. Similarly, a pointer indicating where the (k'-1) th image processing information is stored in the header may be provided in the k '(2≤k'≤n) th image processing information. .

As described above, a plurality of pieces of image processing information can be included in the header. In other words, the user can instruct a plurality of image processings on the processing target image in the (2) processing → storage operation of the above embodiment. Further, the image reproducing method of the present invention does not limit an image file to be subjected to image processing to an original file. That is, a processed file (header file) may be designated as an image file to be processed.

Hereinafter, description will be made with reference to FIG.

Assuming that an original file (file F0) and a processed file (file F1) obtained by performing image processing A on the original file already exist in the storage device 3, the file F1 When a file (file F2) subjected to image processing B is newly created, any of the following two methods may be used.

(Method 1) As shown in FIG. 3A, the processing information of the processing B is set in the image processing information section in the header of the file F2, and the file F1 is stored in the processing file pointer section.
Setting information that points to a storage location in the storage device.

(Method 2) As shown in FIG. 3B, the processing information of the processing A and the processing B is set in the image processing information section in the header of the file F2, and the storage of the file F0 is stored in the processing file pointer section. A method of setting information indicating a storage location in the device. At this time, two of processing A and processing B
One image processing information employs a pointer or the like to clarify the relative positional relationship or absolute positional relationship between two pieces of information in the header.

Since the present method has been achieved by the above-described configuration, it is not necessary to store image-processed image information, and information of the image family can be stored regardless of the number (m + 1) of images constituting the image family. It is possible to prevent an increase in storage capacity when storing. Also, since the information obtained by compressing the image information is used as the original image information, the effect of reducing the storage capacity is multiplied by the effect of the compression processing performed on the original image. The reduction in capacity can be greater.

Further, when the final compression ratio provided by the above configuration is to be achieved by performing only compression processing on each piece of image information constituting an image family as conventionally performed, at least Each image information must be compressed at a compression rate of at least twice (more precisely, about (m + 1) times or more) the compression rate performed on the original image information in the present method. In comparison, each piece of image information is greatly deteriorated by the compression processing. That is, according to the method,
The reproduction image quality can be remarkably improved as compared with the case where the conventional compression technique is used. Further, it is needless to say that the image reproducing method of the present invention can obtain the effect of reducing the storage capacity even if it is not performed for all the image information subjected to the image processing.

[0048]

As described above, according to the present invention,
The storage capacity for storing the information of the image family can be extremely reduced. Therefore, the storage cost per image to be stored is greatly reduced, and the deterioration of the image quality of the reproduced image can be prevented. It is possible.

Further, according to the present invention, the speed of reading, writing, and transferring information in the device is increased.

[Brief description of the drawings]

FIG. 1 is a block diagram of an embodiment of an image reproducing apparatus for realizing an image reproducing method according to the present invention.

FIG. 2 is a flowchart illustrating the operation of the apparatus shown in FIG.

FIGS. 3A and 3B are diagrams showing a connection relationship between files in a family of the image reproducing method according to the present invention.

FIG. 4A is an explanatory diagram of a conventional image data storing method, and FIG. 4B is an explanatory diagram of an image data storing method according to the present invention.

FIG. 5 is a configuration diagram of a header in a storage method according to the present invention.

FIG. 6 shows various examples of an image processing information format.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Image input device 2 Image output device 3 Storage device 4 Operation table 5 Image processor

Claims (1)

[Claims] An image input means for inputting image information obtained by reading a stimulable phosphor plate, image processing is performed on information based on the image information input by the image input means, and a processed image is formed. An image processing apparatus comprising: an image processing unit for obtaining; and an image output unit for outputting and displaying a processed image obtained by the image processing unit; wherein information based on the image information input by the image input unit is used as original image information. When the image processing is gradation processing, information indicating that the image processing is gradation processing, and a gradation conversion table that is processing content applied to the original image information are stored in the original image. Storage means for storing in association with information, the image processing means, when outputting and displaying the processed image,
A tone process is performed on the original image information based on the information indicating that the image process is a tone process stored in the storage unit and the tone conversion table, and the obtained image processed An image processing apparatus, wherein a processed image is output and displayed on said image output means.