JP3052340B2 - Color image reader - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color image reading apparatus capable of preventing occurrence of interference fringes (moire) when reading a color halftone original.

[Related Art] In facsimile machines, digital copiers, and the like, a line image sensor including a plurality of photoelectric conversion elements such as a CCD is often used as a reading device for reading a document image. When a halftone printing document is read using this type of reading device, stripes (moire) that do not exist in the document image may appear in the output signal. Moiré is known to occur when the original image is a halftone image and the halftone dot pitch is close to the sampling pitch of the image sensor.

As a method of suppressing such moiré, a high-frequency component is uniformly removed using, for example, an optical low-pass filter.

[Problems to be Solved by the Invention] However, as described above, in the case of using a low-pass filter to suppress moiré, uniform smoothing is performed. There was a problem that it would decrease.

SUMMARY An advantage of some aspects of the invention is to provide a color image reading apparatus capable of removing moiré without lowering the resolving power without solving the above-described problem.

Means for Solving the Problems In order to achieve the above object, the present invention relates to a color image reading apparatus for reading an original image using an image pickup means, wherein an original image signal represented in a two-dimensional discrete position coordinate system is provided. Means for converting the two-dimensional discrete correlation into a two-dimensional discrete coordinate system represented by an autocorrelation function or a spatial frequency represented by a two-dimensional discrete correlation long coordinate system; and Coordinate separating means for separating into two groups, coordinate selecting means for selecting one or a plurality of coordinates for only one of the two groups of the non-positional coordinate system, and Correction processing means for correcting the image signal value after the conversion, and re-transformation means for re-converting the image signal expressed in the non-position coordinate system to the position coordinate system after the correction processing; The selecting means selects, for each color component, a coordinate whose image signal value in the non-position coordinate system is larger than a preset threshold value as a moiré signal group. The processing for correcting the image signal values of the coordinates of the signal group for all the selected color components is performed.

As the conversion means, means for performing two-dimensional discrete Fourier transform or two-dimensional discrete cosine transform can be used.

Further, the coordinate selecting means may evaluate an image signal value of each coordinate using a plurality of thresholds, and select a coordinate having an image signal value larger than the threshold as a moiré signal group. it can.

Further, the coordinate selecting means selects the selected coordinates by dividing them into a plurality of moiré signal groups, and the correcting means uniformly corrects the image signal value of the coordinates selected by the coordinate selecting means in the group unit. You can do it.

The coordinate selecting means has a first threshold value and a second threshold value, selects coordinates having an image signal value larger than the first threshold value as a first moiré signal group, and Comparing the image signal value at coordinates that are an integral multiple of the coordinates with the second threshold based on the coordinates selected as the first moiré signal group, and determining whether the image signal value is greater than the threshold value. Coordinates larger than the value may be selected as the second moiré signal group.

Further, the coordinate selecting means can square the image signal value in the non-position coordinate system and take the absolute value thereof.

[Operation] According to the above configuration, the original image signal represented by the position coordinate system is converted to the autocorrelation function represented by the two-dimensional discrete correlation long coordinate system or the non-correlation function of the two-dimensional discrete coordinate system represented by the spatial frequency. The data is converted into a position coordinate system, and the converted non-position coordinate system is separated into two groups by a coordinate separation unit.
Next, for only one of the two groups, only coordinates that cause moiré are picked up by a coordinate selection unit using a preset threshold value, and the image signal of the coordinates is further processed by a correction processing unit. Decrease the value. The above processing is performed for all color components. afterwards,
An image signal free from moiré can be obtained by performing an inverse transformation to the position coordinate system by the reconversion means.

[Embodiment] An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of a color image reading apparatus according to an embodiment of the present invention. In FIG. 1, an image sensor 1 is an image sensor or the like, and reads a document as image information. The two-dimensional memory 2 stores red from the image sensor 1,
The original image signals of green and blue are stored as information expressed in a position coordinate system. Transformers (FFT) 3, 4, and 5 execute fast Fourier transform to convert the image signal represented in the position coordinate system into a representation in a two-dimensional discrete spatial frequency coordinate system. (Hereinafter, the spatial frequency is simply abbreviated as frequency.) The frequency separation circuits 6, 7, and 8 convert the image signal after conversion as preprocessing before correcting the image signal that forms moire (hereinafter, abbreviated as moire signal). Is separated into an image signal existing in high-frequency coordinates (hereinafter abbreviated as high-frequency part) and an image signal existing in low-frequency coordinates (hereinafter abbreviated as low-frequency part). The coordinate selection processing unit 9 selects the coordinates of the moiré signal only for the high frequency part, and the correction processing unit 10 corrects the image signal value. Frequency synthesis circuits 11, 12, and 13 are frequency separation circuits 6, 7,
The image signal of the low-frequency part from 8 and the output from the correction processing unit 10 are combined.

Re-transformation means (IFFT) 14, 15, and 16 perform high-speed inverse Fourier transform on the combined image signal and re-transform it to a position coordinate system. 2
The dimensional memory 2 stores the image signals from the re-conversion means 14, 15, and 16 as information of position coordinate expression, and this information is output to the printer 17 and other output means (not shown).

FIG. 2 is a diagram showing main processing and data states by the present apparatus. The operation of the apparatus will be described with reference to the drawing. First, an image is read by the image sensor 1 such as an image sensor and an image signal is input (step S1, hereinafter S1).
Described). The input image signal is data corresponding to (x, y) which is a two-dimensional position coordinate, and is stored in the memory 2. The image signal value at each position coordinate is a red component fr (x, y),
It is represented by a green component fg (x, y) and a blue component fb (x, y) (S2). Hereinafter, these are abbreviated as fi (x, y) i = r, g, b. Next, two-dimensional discrete Fourier transform (two-dimensional discrete cosine transform may be performed) is performed by the FETs 3, 4, and 5 (S3).
This conversion is for converting data represented by position coordinates into representation by frequency coordinates. That is, the image signal value fi (x, y) i = r, g, which was a function of the position coordinates (x, y)
Let b be the image signal value Fi (u,
v) Replace with i = r, g, b (S4).

Next, in the frequency separation circuits 6, 7, and 8, a frequency separation process is performed on the image signal after the above-mentioned conversion so that a process described later is not performed on a low-frequency portion (S5).
Specifically, for example, when the maximum value of the position coordinate x is 256 and the maximum value of y is 256, −60 <u <60 and −60 <
Filter processing that separates the frequency coordinates satisfying v <60 may be used. Regarding the low-frequency portion LOWi (u, v) i = r, g, b indicated by S7 generated by the frequency separation process, the image signal value as it is is subjected to the frequency synthesis process (S11),
The modified two-dimensional image signal value F′i (u, v) i = r,
Used as the low frequency part of g and b. HIGHi (u, u) of the high frequency part indicated by S6 generated by performing the frequency separation processing
v) For i = r, g, b, the coordinate selection processing section 9 detects the frequency (u, v) by the coordinate selection processing (S8), and corrects the image signal value of the detected coordinates. The processing section 10 corrects the image signal value by the correction processing (S9) to obtain HIGH'i (u, v) i = r, g, b shown in S10.

Next, frequency synthesis processing is performed in the frequency synthesis circuits 11, 12, and 13 (S11), and LOWr (u, v), HIGH'r (u, v), L
OWg (u, v) and HIGH'g (u, v), LOWb (u, v) and HIGH'b
(U, v) are combined to obtain a corrected image signal value F'i (u, v) i = r, g, b of the frequency coordinate shown in S12. This F'i
(U, v) The inverse transformation is performed on i = r, g, b in IFFT14,15,16, and the frequency coordinate is transformed into the position coordinate (S1
3) As a result, an image signal value f′i (x, y) i = r, g, b in which moire is suppressed as shown in S14 is obtained.

FIG. 3 is a diagram showing the details of the operation of selecting the frequency coordinate causing moire for the red component in S8. Here, empirically, the threshold TH1 is | Fr (0,
0) 1/10 of ² | and the threshold value TH2 is 1/2 of TH1. For the image signal values HIGHr (u, v) of all the high frequency parts, the obtained threshold value TH1 is compared with | HIGHr (u, v) ² |, and the coordinates (u, v) at which the latter becomes larger Is selected as the first moiré signal group (S17).

Next, a process of selecting a second moiré signal group based on the coordinates selected as the first moiré signal group is performed (S1).
8). Here, one coordinate (u,
v), the threshold TH2 is compared with | HIGHr (nu, nv) ² |
The coordinates (nu, nv) at which the latter becomes larger are selected as the second moiré signal group. In this way, the first and second moiré signal groups of the red component are selected. Further, similar processing is performed on the green component and the blue component. Here, the processing for each color component is in no particular order.

FIG. 4 is a diagram showing details of the correction processing on the selected moiré signal group in S9. First, the processing for the red component will be described. Here, with respect to the first moiré signal group of all the color components obtained by the above-described coordinate selection processing, the image signal value of the coordinates is set to 0, and this is referred to as a corrected image signal HIGH′r (u, v). (S19). Next, for the second moiré signal group of all color components, the image signal value HIGH
The corrected image signal HIGH′r (n
u, nv) (S20). Further, the image signal value is not changed for the image signal value HIGHr (u, v) of the coordinates that are not selected, and the image signal value is set to the image signal value HIGH′r (u, v) (S21). In this manner, the moire signal group of the red component is corrected. The above processing is similarly performed for the green component and the blue component. The processing for each color component is in no particular order.

Although one embodiment has been described above, the present invention can be implemented with appropriate modifications without departing from the spirit of the invention. For example, in the coordinate selection processing, it is conceivable to select peripheral coordinates of the first moiré signal group as the third moiré signal group in addition to the first and second moiré signals. Further, in the above embodiment, the conversion means (FFT) 3, 4, 5 convert the image signal expressed in the position coordinate system into the expression in the two-dimensional discrete space frequency coordinate system. Alternatively, it may be converted to an autocorrelation function expressed in a two-dimensional discrete correlation long coordinate system.

[Effects of the Invention] As described above, according to the present invention, conversion processing such as Fourier transform is performed on the position coordinates of read image information,
The moiré signal group is selected and corrected for only the image signal of the high frequency part having the power equal to or more than the predetermined value with respect to the data after the processing. Therefore, the non-position coordinate system after the conversion process is defined as an area for detecting and correcting moiré,
Since the moiré reduction processing is performed separately for the area in which no moiré is detected and corrected, the processing speed is increased. Furthermore, since a plurality of moiré signal groups are selected based on a plurality of threshold values, and the correction of the image signal value of the coordinates is uniformly performed at the moiré signal group positions, when an optical low-pass filter is used as in the related art, The signal of the moiré component existing in the original image signal can be reduced and corrected without lowering the resolving power, that is, without losing the entire image, and a color image free from moiré can be obtained even when a halftone dot document is read. . Further, since a potential moiré component has also been removed, image sharpening processing such as edge enhancement can be effectively performed. Further, since no special device is required for performing the above-described moiré reduction processing, there is an effect that generation of moiré can be efficiently and effectively prevented with a simple configuration.

[Brief description of the drawings]

FIG. 1 is a block diagram of a color image reading apparatus according to an embodiment of the present invention, FIG. 2 is a view showing processing and image signal contents in the apparatus, and FIG. FIG. 4 is a diagram showing the details of the process of selecting the frequency coordinate, and FIG. 4 is a diagram showing the details of the process of correcting the selected moiré signal group for the red component. 1 ... Image sensor, 3,4,5 ... Conversion means (FFT), 6,7,8 ...
... frequency separation circuit, 9 ... coordinate selection processing section, 10 ... correction processing section, 11, 12, 13 ... frequency synthesis circuit, 14, 15, 16 ... inverse transform means (IFFT), 17 ... printer.

Claims (6)

(57) [Claims] 1. A color image reading apparatus for reading an original image using an image pickup means, wherein an original image signal represented in a two-dimensional discrete position coordinate system is converted into an autocorrelation represented in a two-dimensional discrete correlation long coordinate system. A conversion means for converting the expression into a two-dimensional discrete coordinate system (hereinafter referred to as a non-position coordinate system) represented by a function or a spatial frequency; and a non-position coordinate system converted by the conversion means into two groups. Coordinate separating means for separating, coordinate selecting means for selecting one or a plurality of coordinates for only one of the two groups of the non-positional coordinate system, and, for the selected coordinates, Correction processing means for correcting the image signal value, and after the correction processing, re-converting means for re-converting the image signal expressed in the non-position coordinate system to the position coordinate system, the coordinate selection Means for selecting, for each color component, a coordinate having an image signal value in a non-position coordinate system larger than a preset threshold value as a moiré signal group, wherein the correction processing means comprises: A color image reading device for performing a process of correcting an image signal value of a coordinate of a signal group for all color components selected according to (1). 2. A color image reading apparatus according to claim 1, wherein said conversion means performs two-dimensional discrete Fourier transform or two-dimensional discrete cosine transform. 3. The coordinate selecting means evaluates an image signal value of each coordinate using a plurality of threshold values, and selects a coordinate having an image signal value larger than the threshold value as a moire signal group. The color image reading device according to claim 1, wherein: 4. The coordinate selecting means selects the selected coordinates by dividing them into a plurality of moiré signal groups, and the correction processing means converts the image signal value of the coordinates selected by the coordinate selecting means into a group unit. The color image reading apparatus according to claim 1, wherein the correction is performed uniformly. 5. A first moiré signal group having a first threshold value and a second threshold value, and a coordinate having an image signal value larger than the first threshold value. And, based on the coordinates selected as the first moiré signal group, comparing the image signal value at coordinates that are an integral multiple of the coordinates with the second threshold value, 5. The color image reading device according to claim 3, wherein a coordinate larger than the threshold value is selected as the second moiré signal group. 6. 6. A method according to claim 1, wherein said coordinate selecting means squares an image signal value in a non-positional coordinate system and takes an absolute value thereof as a target. The color image reading device as described in the above.