JPH0844824A - Normalizing device - Google Patents

Abstract

PURPOSE:To facilitate the identification of a following step by performing normalizing processing corresponding to relative position deviation or size fluctuation in the input pattern of an identifying-object image. CONSTITUTION:The character image of the identifying-object image is inputted by an image data input device 1 and horizontally and vertically projected by a projecting device 11a. A first-order/second-order moment calculator 12a calculates the centroid of the character image and standard deviation from the horizontal and vertical projected feature amounts projected by the projecting device 11a. Based on the centroid and the standard deviation, a standard deviation image segmenting device 13 segments the character image in a rectangular area, resets a circumscribed rectangular area and transmits it to a normalized size calculator 14. The normalized size calculator 14 calculates a normalized image size. The segmented character image is transmitted through a projecting device 11b and a first-order/second-order moment calculator 12b to an affine transformer 2, and a normalized image is generated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a normalizing device for normalizing character images in pattern recognition.

[0002]

2. Description of the Related Art A normalization device used for normalizing the position and size of an image to be identified such as a character image is constructed as shown in FIG. In the figure, reference numeral 1 is an image data input device, which is connected to the affine transformation device 2. The identification target image, for example, a character image, input by the image data input device 1 is sent to the affine transformation device 2, and the affine transformation device 2 divides the character image into regions and linearly transforms each region, thereby The center of gravity of the character image is converted to the center of the normalized image to generate the normalized image. Note that FIG. 2B shows a normalized image generated by the conventional normalizing device.

[0003]

Characters to be distinguished include vertically long characters and horizontally long characters. If all of these characters are normalized to the same size, image distortion will increase, and subsequent characters will be identified. There is a great possibility that it will adversely affect.
For a character whose shape is partially irregularly deformed, as typified by, for example, a handwritten character, an affine transformation performed in the above-described conventional normalization device,
That is, sufficient normalization processing cannot be performed only by linear conversion. Further, the character portion is cut out using the circumscribing rectangle when the normalized image is generated. However, as shown in FIG. 2B, in the related art, since the image is not cut out by the standard deviation, the character portion is stretched away from the center of gravity. If an unnecessarily long stroke called an excessive stroke remains without being cut and the character part is cut out, it will be affected by the fluctuation of the stroke length around the character starting from the excessive stroke described above. There was a problem that it was not easy to identify.

The present invention has been made in view of the above-mentioned circumstances, and is sufficiently normalized without being affected by relative displacement, size variation, or excessive stroke in the input pattern of the image to be identified. It is an object of the present invention to provide a normalization device that performs processing and enables easy identification in the subsequent stage.

[0005]

The present invention comprises an image data input device for inputting an identification target image, and an affine transformation device for dividing the input identification target image into regions and performing linear transformation for each region. In the normalizing device,
A projection device for projecting the input image to be identified in the horizontal and vertical directions, and a first moment that is the center of gravity and a second moment that is the standard deviation are calculated based on the projection feature amount output from the projection device. A first / second moment calculation device, a standard deviation image cutting device that cuts out an image based on the standard deviation calculated by the first and second moment calculation device, an image size cut by this standard deviation image cutting device, and a standard normal image And a normalized size calculation device for calculating a normalized size from the normalized image size.

[0006]

The projection feature amount in the horizontal direction and the vertical direction with respect to the image to be identified is calculated, and the center of gravity and the standard deviation of the image to be identified are calculated. An circumscribing rectangle determined by a length that is a constant multiple of this standard deviation is used to cut out the identification target image with the calculated center of gravity as the center. Next, the normalized size calculation device compares the aspect ratio of the cut-out identification target image with the aspect ratio of the standard normalized image size, which is a predetermined normalized image size, and calculates the normalized image size. Do. Further, the centroid of the cut-out identification target image is obtained by the primary / secondary moment calculation device, and four rectangular regions determined by the centroid and the circumscribed rectangle are normalized by the normalized size calculation device. A scaling operation is performed in the affine transformation device based on the image size to generate a normalized image.

As described above, the identification target image is cut out based on the standard deviation obtained from the identification target image, the center of gravity is obtained, and four rectangular regions determined by the center of gravity and the circumscribed rectangle of the cut out identification target image. By performing the expansion / contraction operation on the basis of the above-mentioned normalized image size to generate a normalized image, the normalization process can be executed without being affected by an excessive stroke or the like, and the subsequent identification can be facilitated.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a normalization device according to an embodiment of the present invention.

In FIG. 1, reference numeral 1 denotes an image data input device, which is connected to a projection device 11a and takes in an original image which is an image to be identified, for example, a character image, and sends it to the projection device 11a. The projection device 11a projects the character image sent from the image data input device 1 in the horizontal and vertical directions, and sends it to the first / second moment calculation device 12a.
The primary / secondary moment calculation device 12a includes the projection device 11
The center of gravity of the character image and the standard deviations in the vertical and horizontal directions of the character image are calculated based on the horizontal and vertical projected feature amounts projected in a. The center of gravity and the standard deviation are sent to the standard deviation image cutting device 13, and the standard deviation image cutting device 13 uses the first and second moment calculation device 1.
The character image is cut out based on the center of gravity and the standard deviation obtained in 2a, and the circumscribed rectangular area is reset. Further, the cut-out data of the character image is sent to the normalized size calculation device 14, and the normalized size calculation device 14
Calculates the normalized image size from the aspect ratio of the cut out character image.

The character image cut out by the standard deviation image cutout device 13 is a normalized size calculation device 1
4 is also sent to the projection device 11b connected to the image projection unit 4 and projected in the horizontal and vertical directions, and the horizontal / vertical projection feature amount is sent to the primary / secondary moment calculation device 12b. The primary / secondary moment calculation device 12 b calculates the center of gravity of the cut-out character image and sends it to the affine transformation device 2. The affine transformation device 2 expands and contracts four rectangular areas determined from the center of gravity of the cut-out character image and the reset circumscribed rectangular area, respectively, to generate a normalized image. The expansion and contraction rates of the above four rectangular areas are different.

Next, the operation of the above embodiment will be described. In FIG. 1, a character image (in this case, the character "husband") is input by the image data input device 1, and the character image is sent to the projection device 11a. The projection device 11a calculates the horizontal projection feature amount and the vertical projection feature amount of the character image and sends them to the first / second moment calculation device 12a. Next, as shown in FIG. 2A, the primary / secondary moment calculation device 12a determines the center of gravity (G _x , G _y ) 21 of the character image from the calculated horizontal projection feature amount and vertical projection feature amount. The standard deviations σ _x and σ _y in the horizontal and vertical directions are calculated and sent to the standard deviation image clipping device 13. Standard deviation image cutout unit 13, as shown in FIG. 2 (c), the standard deviation sigma _x,
Rectangular region k centered on the center of gravity (G _x , G _y ) 21 determined by the length k _x , k _y (parameter) that is a constant multiple of σ _y
x · sigma _x, with k _y · σ _y cut out the character image, resetting the area of the circumscribed rectangle 22a. The data of the cut out character image is sent to the normalized size calculation device 14, and the normalized size calculation device 14 determines the aspect ratio of the cut out character image and a standardized image size that is a predetermined normalized image size. Compare with the aspect ratio of the normalized image size,
Calculate the normalized image size.

Here, the aspect ratio of the clipped character image is r _o , the aspect ratio of the standard normalized image size is r _n , and a criterion for determining whether the clipped character image is vertically long or horizontally long. Assuming that the threshold value is T _h , an example of the calculation method is as follows.

R _o / r _n > T _h (1) r _o / r _n <T _h (2) When the result of the equation (1) is obtained, the normalized size calculation device 1
4 determines that the cut out input character image is vertically long, and suppresses the enlargement ratio in the horizontal direction. Further, when the result of the expression (2) is obtained, the normalized size calculation device 14 determines that the input character image is horizontally long, and suppresses the enlargement ratio in the vertical direction.

Next, the character image data cut out by the standard deviation image cutout device 13 is also output to the projection device 11b via the normalized size calculation device 14, and the horizontal projection feature amount and the vertical projection feature of the character image are projected. The feature amount is calculated and sent to the first / second moment calculating device 12b. The primary / secondary moment calculation device 12b obtains the center of gravity of the cut-out character image, and sends the data of the center of gravity to the affine transformation device 2. The affine transformation device 2 is
A rectangular image as shown in FIG. 2 (d) is generated by expanding / contracting each rectangular area obtained by dividing the cut out character image determined by the center of gravity of the character image and the circumscribed rectangle 22a.

The process of expanding and contracting the rectangular region divided into four by the affine transformation device 2 will be described in more detail with reference to FIG. As shown in FIG. 3 (a), the character image "main" which is the original image is cut out according to the method described above and the circumscribed rectangle 22b is reset, and the center of gravity ( _G'x , _G'y ) 23 is required. The affine transformation device 2 has four rectangular regions (A, B, C, and C) defined by the center of gravity 23 and the circumscribing rectangle 22b.
Each of the areas D) is a rectangular area (A ', B', which is obtained by dividing the rectangle calculated by the normalized size calculation device 14 into four equal parts).
C ', D') are expanded and contracted so that the center of gravity (G '
_x , _G'y ) 23 is transformed into the center of the normalized image, and
The normalized image shown in (b) is generated.

As described above, the character image to be identified is cut out in the rectangular area determined by the lengths k _x and k _y that are constant times the standard deviations σ _x and σ _y of the character image.
When cutting out a character image, it is less likely to be adversely affected by minute noise around the image, and has an effect of shortening or cutting an excessive stroke. Further, the calculation of the normalized size is performed by comparing the aspect ratio r _o of the cut out image with the aspect ratio r _n of the normalized size. This allows
A normalized image that is not unnatural when viewed by a person is generated, facilitating the subsequent identification. For example, "1", "one", "one"
This is effective when normalizing a character with an extremely large aspect ratio such as. In addition, as shown in FIG.
The rectangular area (A ', B', C ', D'is divided into four rectangular areas (A, B, C, D), and the rectangle calculated by the normalized size calculation device 14 for each area is divided into four. )
By performing the expansion / contraction operation so as to have the effect of contracting the stroke extending away from the center of gravity, the adverse effect of the excessive stroke is mitigated.

FIG. 4 is a block diagram showing the structure of a normalization device for normalizing standard characters. As shown in FIG. 4, a normalization size calculation device is added to a conventional normalization device. It is possible to execute the normalization process with the configuration in which 14 is added. That is, for the standard character image input by the image data input device 1, the normalized size calculation device 14 compares the aspect ratio of the standard character image with the aspect ratio of the standard normalized image size to obtain the normalized image size. Is calculated. Next, the standard character image is divided into regions by the affine transformation device 2, and each region is expanded / contracted based on the normalized image size calculated by the normalized size calculation device 14 to generate a normalized image.

[0018]

As described above, according to the present invention,
The identification target image is cut out based on the center of gravity and the standard deviation of the identification target image, and each rectangular region obtained by dividing the cut out identification target image into regions is expanded / contracted based on the calculation result of the normalized image size. Since a normalized image is generated by this method, it is possible to perform the normalization processing without being affected by relative displacement of the input pattern, variation in size, and excessive stroke, as compared with the conventional normalization device. This makes it possible to easily identify the latter stage.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of a normalization device according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining the effect of the present invention by the standard deviation image cropping device according to the embodiment.

FIG. 3 is a diagram illustrating an image normalized by a normalization device according to the present invention.

FIG. 4 is a block diagram showing a configuration of a normalization device when normalizing a standard character.

FIG. 5 is a block diagram showing a configuration of a normalization device in a conventional example.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 image data input device 2 affine transformation device 11a, 11b projection device 12a, 12b first / second moment calculation device 13 standard deviation image cutting device 14 normalized size calculation device 21 center of gravity (G _x , G _y ) 22a, 22b circumscribed rectangle 23 Center of gravity ( _G'x , _G'y )

Front Page Continuation (72) Inventor Shintaro Kumano 1-1-1, Wadasaki-cho, Hyogo-ku, Kobe-shi, Hyogo Prefecture Mitsubishi Heavy Industries, Ltd. Kobe Shipyard (72) Inventor Kayoko Kawada, Wadazaki-cho, Hyogo-ku, Kobe-shi, Hyogo No. 1-1, Mitsubishi Heavy Industries, Ltd. Kobe Shipyard

Claims (1)

[Claims] 1. A normalization device comprising an image data input device for inputting an identification target image, and an affine transformation device for dividing the input identification target image into regions and performing linear transformation for each region. A projection device that projects the identification target image in the horizontal and vertical directions, and based on the projection feature amount output from this projection device, a first-order moment that is the center of gravity and a second-order moment that is the standard deviation are calculated. A second moment calculation device, a standard deviation image cutout device that cuts out an image based on the standard deviation calculated by the first and second moment calculation devices, and an image size and a standard normalized image cut out by this standard deviation image cutout device A normalized size calculation device for calculating a normalized size from a size.