JPH0657048B2 - Image signal processing method - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image signal processing method for binarizing an image signal obtained by scanning a film projection image with an image sensor and then binarizing the image signal. It is a thing.

(Technical background of the invention) A film projection image is read by an image sensor such as a CCD line sensor or a CCD area sensor, and after this image signal is defocused, it is binarized at a constant binarization level or floating according to the image signal. A method of comparing with the level has already been proposed (see JP-A-62-130068).

The blur correction here emphasizes the edges of the image by emphasizing the high frequency components of the image, and a high-frequency emphasis filter using first-order differentiation or Laplacian (second-order differentiation) is used. However, since such a high-frequency emphasis filter essentially uses differentiation, it is vulnerable to noise, and especially noise in the background region of the image signal is also emphasized, which significantly improves the image quality after binarization processing. There was a problem of lowering it. This problem becomes particularly important when reading a projected image of a film which is easily damaged by dust, dust or scratches. Therefore, it has been considered by the applicant of the present application that the image signal is sliced at a predetermined background noise cut level close to the background level to remove noise included in the background. However, in this case, the background density level differs depending on the image,
The problem is how to determine the background noise cut level. That is, if this setting is wrong, background noise cannot be sufficiently removed, or the fluctuation range (dynamic range) of the effective signal level of the image signal is narrowed, resulting in deterioration of image quality.

Therefore, it is conceivable to determine the background noise cut level using a histogram. In this case, if an image includes an area other than the original, for example, an image of an original table around the original, the area other than the original ( (Hereinafter referred to as a frame area) may create a mountain different from the background mountain in the histogram. FIG. 8A shows a film projection image when the document table 1 on which the negative document 2 is placed or the mount 1 is darker than the background of the document 2, and FIG. 8B shows the histogram X at that time. FIG. 9A shows a film projection image in which a positive original 4 is placed on a white or transparent original table 3, and FIG. 9B shows a histogram Y at that time. Thus, in each of the histograms X and Y, the peaks Q of the manuscript tables 1 and 3 that are close to the background peaks P (X) and P (Y), that is, the peaks Q corresponding to the frame area are provided.
(X) and Q (Y) occur. Therefore, if the background noise cut level is calculated using such histograms X and Y, an incorrect level may be set.

(Object of the Invention) The present invention has been made in view of the above circumstances, and while a projection image of a film is read to obtain an image signal, the image signal is sliced at a background noise cut level close to the background level. When noise in the ground is removed, blurring is corrected by high-frequency emphasis, and then binarization processing is performed, the background noise cut level can always be set appropriately without being affected by the image signal for areas other than the original. It is an object of the present invention to provide an image signal processing method capable of improving the image quality after binarizing the image.

(Construction of the Invention) According to the present invention, an object of the present invention is to provide an image signal obtained by scanning a projected image of a film having a frame area around an original image with an image sensor by a background noise cut level close to the background level. After removing the background noise by slicing, the image signal processing method of sharpening the image signal by performing blur correction and further binarizing it by a predetermined binarization level detects the frame area and detects the frame area. After trimming processing for removing the image signal for the original image, a histogram of the image signal of the original image is obtained, and a histogram of the total number of pixels of the histogram is provided in the vicinity of the skirt on the signal level side including the original image of the highest frequency peak of the histogram. Based on the height which becomes the constant frequency ratio, the height which becomes the constant frequency ratio of all the pixels of the background noise cut level And an image signal processing method characterized by setting the background noise cut level.

(Embodiment) FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a conceptual diagram of a part of a concrete example thereof, and FIGS. 3A to 3C are diagrams showing signal waveforms during processing, and FIG. Shows a 3 × 3 matrix, and FIG. 5 shows a histogram for a negative film.

In FIG. 1, reference numeral 10 is a light source. Light from the light source 10 is guided to an image sensor 20 via a condenser lens 12, a film 14, a projection lens 16 and a mirror 18, and a projected image of the film 14 is directed to the image sensor 20. Form an image. The image sensor 20 is a CCD line sensor or C
It is formed of a CD area sensor or the like and is driven by a pulse supplied from a pulse circuit (not shown) to scan an image and output a time-series image signal a ₀ .

In the trimming circuit 21, the image signal a ₀ is converted into an image signal a by removing the portion of the document table image appearing around the image of the document. The trimming circuit 21 can have various configurations. For example, a method of obtaining the coordinates of the four corners of the original from the read image signal a ₀ and validating only the signals in the area surrounded by these four corners and removing the others is possible. is there.

The image signal a after trimming the original table portion in this manner has an output waveform as shown in FIG. 3A when the film 14 is negative. 3A to 3C, the horizontal axis represents time or pixel order, and the vertical axis represents voltage.

The image signal a for one scanning line or one screen is primarily stored in the semiconductor memory 22 such as a line memory or a frame memory. This image signal a is input to the histogram means 24 composed of a CPU (not shown), and the histogram A shown in FIG. 5 is obtained here. The CPU obtains the background noise cut level b from the histogram A by the background noise cut level detection means 26 of the CPU itself.

In the histogram A, the horizontal axis represents the output level V of the image signal a and the vertical axis represents the frequency H. For the negative film 14, the peak B corresponding to the background appears on the low output level side. The CPU determines the background noise cut level b near the skirt on the right side (high output level side) of the mountain B of the histogram A. For example, if the total number of pixels of this histogram b is N
As a result, the output level having a high frequency of N / 100 can be determined as the background noise cut level b. The frequency N / 100 with respect to the background noise cut level b is obtained as a result of various experiments with respect to the film original. The background noise cut level b is the distance D (the fifth point) from the intersection C at which the peak B of the histogram A intersects with a certain frequency.
It is possible to set by various setting methods using ().

The image signal a and the background noise cut level C are input to the background noise cut circuit 28, where noise included in the background region is removed. That is, this circuit 28
Is, for example, a comparator 30 and a switch 32 as shown in FIG.
The comparator 30 compares the image signal a with the background cut level b. Also, the switch 32 is the comparator 3
When 0 is judged to be a <b, the background cut level b is selected, and when a ≧ b, the image signal a is selected. As a result, the output C of this circuit 28 is sliced at the background noise cut level b, and the noise in the background region is cut, as shown in FIG. 3B. In this way, the background cut level b is close to the background level d (Fig. 3A),
It is set to a level slightly higher than this.

A blur correction circuit 34 emphasizes the high-frequency component of the signal c by using a high-frequency emphasis filter 36 as a high-frequency emphasis filter to perform edge emphasis of the image.

The high-frequency emphasis filter 36 functions to emphasize the center pixel when the image space is an odd matrix in which the center pixel appears. As the high-frequency emphasis filter 36, for example, when each pixel data of a 3 × 3 matrix is set to a to i as shown in FIG. 4, the data e for the central pixel is obtained by using the data of the four pixels around it. = 5e- (b + d + h + f), and E is used as a new image signal. In this case, the high-frequency emphasis filter 36 is set as shown in FIG. 2, and each element of this matrix has a perimeter 4 centered on the central pixel.
The image data of one pixel is integrated and the sum E of the integrated values is obtained. The image signal e thus emphasized is compared with the binarization level f in the comparator 38 to obtain the binarization signal g.
Is obtained.

As described above, before the background noise is removed by the background noise cut level b, the image signal of the portion other than the image of the original, that is, the frame area is removed by the trimming circuit 21, so that the background peaks in the histogram can be correctly identified. After that, the background noise cut level b can be correctly determined from the peak of the maximum frequency indicating the background of the histogram.

FIG. 6 is a block diagram of another embodiment, and FIGS. 7A to 7D are output waveform diagrams of respective parts.

In this embodiment, the binarization level is changed by using the image signal a. That is, the image sensor 20
Image signal a ₀ is trimmed and stored as an image signal a, and is smoothed by a smoothing circuit 50 into a smoothed signal h (FIG. 7A).
Compressed at 2. The voltage level of the compressed signal i (FIG. 7B) is further raised by k in the level shift circuit 54. This level-shifted signal j (FIG. 7C) is compared by the comparator 38 with the signal d whose blur correction has already been completed, and the binarized signal 1 is obtained.

As the smoothing circuit 50 of this embodiment, it is possible to use, for example, a median filter that adopts an intermediate value (median) of a 3 × 3 matrix centered on the center pixel as image data of the center pixel.

According to this embodiment, since the binarization level j itself varies depending on the image signal a, the high precision of an image with a low contrast is suitable for the binarization process.

In each of the above embodiments, the high-frequency emphasis filter 3 is provided in the blur correction circuit.
However, the present invention is not limited to this.

Further, the background noise cut level b is set to be slightly higher than the background d when the image of the negative film is used, but when the positive film is used, it is slightly lower than the background d. Of course, in this case, the height is set to a certain frequency ratio near the skirt on the left side (low output level side) of the highest frequency peak in the histogram.

(Effects of the Invention) As described above, the present invention trims and removes a signal of a portion other than a document included in a projected image of a film, for example, a portion of a document table, and then removes the signal from the peak of the background of the histogram. Since the background noise cut level is set based on the height that has a constant frequency in the vicinity, the background peaks can be correctly discriminated even when parts other than the original are included in the film projection image, and the film projection image changes Can always set the background noise cut level to an appropriate level. Therefore, in the binarization process after blur correction, the background noise cut level is too close to the background to remove noise sufficiently, or conversely, it is too far from the background level to sacrifice the dynamic range of the image signal. , Such as inconvenience does not occur,
High-quality binarization processing becomes possible.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a conceptual diagram of a specific example thereof, FIGS. 3A to 3C are diagrams showing signal waveforms in a processing process, and FIG. FIG. 5, FIG. 5 is a diagram showing a histogram, FIG. 6 is a block diagram of another embodiment, FIGS. 7A to 7D are output waveform diagrams of respective parts, and FIG.
FIGS. 9A and 9B and FIGS. 9A and 9B are diagrams showing a film projection image and a histogram for a negative and a positive original, respectively. 20 ... Image sensor, 21 ... Trimming circuit, 24 ... Histogram means, 28 ... Underground noise cut circuit, 34 ... Blurring correction circuit, 36 ... High frequency enhancement filter, 38 ... Comparator, a ... Image signal, b ... Underground noise cut Level, d ... Background level, f, j ... Binary level, A ... Histogram.

Claims (6)

[Claims] 1. A background noise is removed by slicing an image signal obtained by scanning a projected image of a film having a frame area around an original image with an image sensor at a background noise cut level close to the background level. After that, the image signal is sharpened by performing blur correction and further binarized by a predetermined binarization level, and in the image signal processing method, the frame area is detected and trimming processing is performed to remove the image signal for this frame area. After that, a histogram of the image signal of the original image is obtained, and based on the height which is a constant frequency ratio of the total number of pixels of the histogram in the vicinity of the skirt of the signal level side including the original image of the highest frequency peak of the histogram. And setting the background noise cut level. 2. The image signal processing method according to claim 1, wherein the blur correction is performed by using a high-frequency emphasis filter. 3. The binarization level is obtained by smoothing the image signal, compressing the smoothed signal, and further performing level shift. Image signal processing method. 4. The image signal processing method according to claim 3, wherein the smoothing is performed by using a median filter. 5. The film projection image is obtained by a negative film, and the background noise cut level is set near the high output level side skirt of the highest frequency peak of the histogram. The image signal processing method according to item 1. 6. A film projection image is obtained by a positive film, and the background noise cut level is set in the vicinity of the low output level side skirt of the highest frequency peak of the histogram. The image signal processing method described in the item.