JPS61184052A - Picture data compressing method - Google Patents

Abstract

PURPOSE:To improve the compressing efficiency of the entire picture by dividing one picture data into >=2pts and compressing the split picture data with different compressing rates in response to the required amount of picture information for each part. CONSTITUTION:The picture data of an original picture 1 is split into >=2pts. In this case, the original picture 1 includes a part A requiring detailed information and a part B whose outline is understood and the data is split into the part A 5a and the part B 5b. Then the picture data of the parts 5a, 5b is compressed with different compressing rates in response to the required amount of picture information with respect to each part. That is, the part A 5a is compressed into a compression rate of 1/n and the part B 5b is compressed with a compression rate of 1/m. Thus, the compressed picture 3 compressing the entire picture data of the original picture 1 is obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to an image data compression method for appropriately compressing image data such as medical images when storing, transmitting, and processing the image data, and in particular, relates to an image data compression method for appropriately compressing image data such as medical images. This article describes an image data compression method that can increase efficiency.

2. Description of the Related Art As shown in FIG.
The compressed image) Elephant 3 was obtained. Therefore, the entire area of the original image 1 was compressed at substantially the same compression rate. Here, in the original image 1, there is generally a part that requires detailed image information, such as part A, and a part that only needs to be understood briefly, such as part B. The amount of image information is not necessarily uniform.

Problems to be Solved by the Invention However, in the conventional method described above, the entire area of the original image 1 is uniformly compressed at approximately the same compression rate, so usually the image information necessary to understand part A is In order to secure the amount, the entire area was compressed at a compression rate suitable for compressing the above part A. Therefore, although the amount of image information is not required for the B part, it is [1] at the same rate as the A part.
iIi@data remained. That is, although the B portion could have been compressed to reduce the image data, the compressed image 3 was created with the B portion containing unnecessary image information. As a result, the data amount of the compressed image 3 increases, and the compression efficiency of the image data as a whole decreases. In addition, since the amount of data in the compressed image 3 is large as mentioned above, the storage capacity to store it is large (nearly required), the transmission time is long, and the cost is also high. The present invention aims to solve these problems.

Means for Solving the Problems The means of the present invention for solving the above problems, as shown in FIG. 1, first divides the image data of the original image 1 into two or more parts (4). At this time, it is assumed that the original image 1 includes a portion A that requires detailed image information and a portion B that only requires an overview. To divide. Next, each of the above parts 5a, 5
The image data of b is compressed (6a, 6b) at different compression rates depending on the amount of image information required for each part.

That is, the A portion 5a is compressed at a compression rate of l/n (6a)L, and the 8 portion 5b is compressed by 1/m (here m).
Compress (6b) with a compression ratio of n). As a result, a compressed image 3 in which the entire image data of the original image 1 is compressed is obtained.

Operation: The image data compression method configured as described above compresses each of the divided portions 5a and 5b at different compression rates, so that the portion 5a that requires detailed image information can be compressed without losing the image information. , as much image information as possible is discarded for the part 5b that only needs to be understood, and as a result, the compressed image 3 after compression is
This reduces the overall amount of data.

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

FIG. 2 is an explanatory diagram showing an embodiment of the image data pressure and betting method according to the present invention, and FIG. 3 is a block diagram showing an outline of the apparatus used to implement this method. The above device includes a central processing unit (CPU) 10, a main memory 11, a display device 12 such as a CRT (7), a two-dimensional scanning device 13, a keyboard 14, and a first compression/decompression circuit 1.
5a and a second compression/expansion circuit 15b, a coordinate indicating device 16 such as a trackball, mouse, or joystick, and an external storage device 17 such as a magnetic disk or optical disk. In addition, in FIG. 3, reference numeral 18 is a bus for transferring data.

Now, in FIG. 2, it is assumed that image data of an original image 1 such as a medical image is compressed to obtain a compressed image 3. First, under the control of the central processing unit 10 shown in FIG.
Load into. At this time, the read image is displayed on the display device 12. Here, as shown in FIG. 2, it is assumed that the original image 1 includes a portion A that requires detailed image information and a portion B that only requires an overview. Next, the operator selects the display device 12.
Look at the display image, confirm the above part A, and press the keyboard 14.
Alternatively, operate the coordinate indicating device 16 to specify the position of the "CA part."This divides the A part 5a, which you want to know in detail, and the 8 part 5b, which you only need to understand in detail (4).Next, this division For each portion 5a, 5b, the image data is sampled at an appropriate sampling pitch (7
)do.

In this case, image data is extracted at the same sampling pitch for both the A portion 5a and the 8 portion 5b.

As shown in Figure 4, the number of pixels in each part of A and B at this time is (+, y+ for part A), and if there is one in the X direction and one in the Y direction of part B, it is X2.y2. The amount of data is x1Xy+, and the amount of data in part B is (X2
XY2)(xtxy+). The image data of portion A 5a and image data of portion 8 5b sampled (7) in this way are compressed at different compression rates depending on the amount of image information required for each portion 5a, 5b. That is, the A portion 5a is compressed (8a
) L, for the 8 portion 5b the second compression/expansion circuit 15b
It is compressed (8b) at a compression rate of 1/m.

Here, as described above, the compression rate for the 8 portions 5b is set to high (m)n because the amount of image information required for the 8 portions 5b is small and a large amount of image information may be discarded. The image data thus compressed for each portion 5a, 5b (8a, 8b) is stored in the external storage device 17 shown in FIG. 3 as compressed image 3 data.

Next, in order to redisplay the data of the compressed image 3 that has been saved, the compressed image data of each part of A-2a is downloaded from the external storage device 17 under the control of the central processing unit 10 shown in FIG. the first compression/expansion circuit 15
a and the second compression/expansion circuit 15b, and are expanded by multiplying them by n and m by the reciprocals of their respective compression rates. At this time,
Since the sampling pitches of the original A portion 5a and the 8th portion 5b were the same, the sampling pitches of the expanded image data of the image portions 5a and 5b are the same. The expanded image data of each portion 5a, 5b is stored in the main memory 11 and displayed on the display device 12 in the same manner as the original image 1.

FIG. 5 is an explanatory diagram showing another embodiment of the present invention, and is an explanatory diagram showing another embodiment of the present invention.
Figure E6 is a block diagram outlining the apparatus used to implement the method. In this embodiment, the original image 1 is converted into the A portion 5a.
After dividing the image data into eight parts 5b, the sampling pitch for sampling the image data of each part 5a and 5b is set to a different sampling pitch depending on the required amount of image information in each part 5a, 5b (7a, 7b). ,
Each part 5a, 5b after this sampling (7a, 7b)
The image data is compressed at substantially the same compression rate (8).

Therefore, the device only needs one compression/expansion circuit 15 (see FIG. 6). Here, the above sampling (7a
, 7b), since the A part 5a is a part that requires detailed image information, its sampling pitch is small and the number of pixels is increased (while the 8 part 5b is a part where it is only necessary to understand the outline, so Increase the sampling pitch to reduce the image ta.For example, A part 5
If the sampling pitch of a is °1″, 8 parts 5
The sampling pitch of b is set to "L" (here 1>1), and each sampling pitch is specified by thinning or interpolation using a value stored in advance in the keyboard 14 or external storage device 17, etc., and the above original image 1 is The image data of each portion 5a and 5b may be extracted from the main memory 11 into which the image data has been read, by processing it at a newly specified sampling pitch. At this time, the number of pixels in each part of A and B is as shown in FIG.
Then, in Fig. 7, the sampling pitch for part A is "1", so the number of pixels is Xl and Yl, and for part B, the sampling pitch is "L", so the number of pixels is X2A and X2A. Therefore, the amount of data in part A is )(j
r) (TX7) becomes. Here, when comparing the amount of data of the entire original image 1 in FIG. 5 with the amount of data of the entire portions A and B, which were sampled separately with different sampling bits in FIG. 7, the following results are obtained.

X2 X y2! 2 In other words, the amount of data of the entire portion A and portion B after being sampled separately is (1) twice that of the entire original image 1. For example, if the area of part A is 1/4 of the original image 1 and the sampling pitch of part B is t = 2, then (1)
The value of the equation is 7/16, which shows that the amount of data in the entire A part and B part becomes smaller after sampling separately.

Note that operations other than the above sampling (7a, 7b) are as follows:
The process proceeds in the same manner as the first embodiment shown in FIG. 2, and the data of the compressed image 3 is stored in the external storage device 17 shown in FIG.

Next, in order to redisplay the data of the compressed image 3 stored above, the compressed image data of each part A and B is taken out from the external storage device 17 and inputted to the compression/expansion circuit 15 shown in FIG. and decompress it at the reciprocal of the compression rate. At this time,
The central processing unit 10 needs to perform interpolation calculations on the image data of the B portion, which has a large sampling pitch, so that the number of pixels matches that of the image data of the A portion, which has a small sampling pitch.

In the above explanation, the original image 1 is divided into the A part 5a and the 8 part 5b by two buttons, but the present invention is not limited to this, and the same effect can be obtained even if the original image 1 is divided into three or more parts. Applicable. Further, the image data to be divided may be an analog image or a digital image. Furthermore, the present invention
K can be similarly applied not only to medical images but also to various other types of images.

Effects of the Invention As explained above, the present invention divides one image data into two or more parts, and compresses the image data of each divided part at different compression rates depending on the amount of image information required for each part. Since the image is compressed using , it is possible to discard as much image information as possible for the part (5b) where detailed image information is required, without losing the image information for the part (5a) that requires detailed image information. The data amount of the compressed image 3 can be reduced as a whole.Therefore, the compression efficiency of the entire image data can be increased.Furthermore, since the data amount of the compressed image 3 is reduced as described above, this Reduce the storage capacity for storing
Transmission time can be shortened and costs can further be reduced.

[Brief explanation of drawings]

Fig. 1 is an explanatory diagram showing the basic outline of the image data compression method according to the present invention, Fig. 2 is an explanatory diagram showing an embodiment of the method of the present invention, and Fig. 3 is an explanatory diagram showing the implementation of the method. FIG. 4 is an explanatory diagram showing the number of pixels in each part of an image; FIG. 5 is an explanatory diagram showing another embodiment of the method of the present invention; FIG. 6 is an illustration of the implementation of the method. Figure 7 is an explanatory diagram showing the number of pixels when the sampling pitch is different for each partial pressure of an image, and Figure 8 is an explanatory diagram showing a conventional image data compression method. It is. 1... Original image, 3... Compressed image, 4... Division, 5a... Part that requires detailed image information (part A), 5b... Part that only needs to be understood (B part), 5a, 5b...compression, 7.7a, 7b...sampling, 8.8a, 8b...compression.

Claims (1)

[Claims] 1. By dividing one image data into two or more parts and compressing the image data of each divided part at different compression rates depending on the amount of image information required for each part. , an image data compression method characterized by compressing the entire image data. 2. The image data compression method according to claim 1, wherein sampling of the image data of each divided portion is performed at the same sampling pitch for each portion, and the compression ratio is made different for each portion. . 3. The scope of claims characterized in that the image data of each of the divided parts is sampled at different sampling pitches depending on the amount of image information required for each part, and the compression ratio is approximately the same for each part. 1st
Image data compression method described in section.