JPH0856316A - Image processor - Google Patents

Abstract

PURPOSE:To emphasize a luminance signal which is inferior in S/N without emphasizing a high-frequency noise by emphasizing the contrast of a low-frequency luminance signal by an LPF, putting it together with the difference between a source luminance signal and the low-frequency luminance signal, and outputting the composite signal. CONSTITUTION:The low-frequency luminance signal is separated by the LPF 10 from the input luminance signal and a contrast emphasizing circuit 12 emphasizes the contrast. This emphasized signal, and the input luminance signal and low-frequency luminance signal passed through a subtracter 11 are put together by an adder 13, and the resulting signal is outputted. This constitution emphasizes the luminance signal which is inferior in S/N while preventing the high frequency noise from being emphasized, and the resolution of an image signal can be improved.

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 outputting a color image such as a color television monitor or a color printer.

[0002]

2. Description of the Related Art Conventionally, as a brightness level conversion method for a color television, for example, an auto pedestal circuit having an input / output characteristic as shown in FIG. The method is such that feedback is applied to reduce the level to the pedestal level. In the auto pedestal circuit, the brightness level conversion characteristic changes as shown by the arrow in FIG. 9 according to the blackest level of the input brightness signal Y,
By stretching the black portion, a subjectively pleasing image is obtained.

Further, processing for increasing the brightness contrast of an image, such as histogram conversion and linear density conversion, has been conventionally known.

In the conventional auto pedestal circuit, the input luminance signal level Y ₀ in FIG. 9 is fixed,
Since the range of the level for lowering the brightness is fixed, it is not possible to perform truly adaptive processing on the input image. For example, an image with a low average brightness level originally requires the gradation of the black part. However, black shadows occur. Further, since the input luminance signal is not converted from the intermediate portion to the highlight portion, the dynamic range is not effectively used. Furthermore, since temporal continuity is not taken into consideration in Japanese Patent Laid-Open Publication No. Sho, even if the previous image and the current image are the same, if the blackest level suddenly changes, the input-output characteristics will suddenly change. The change causes flickering such as flicker on the entire screen, which causes deterioration of image quality.

[0005]

In order to solve the problems of the conventional auto-pedestal circuit, the applicant of the present invention calculates the cumulative distribution of pixels with respect to the brightness level for each predetermined image processing unit. An image processing apparatus that obtains a brightness conversion curve representing an output brightness level based on the cumulative distribution and converts the brightness level of an output brightness signal based on the value of the brightness conversion curve is disclosed in, for example, Japanese Patent Application No.
Proposed as No. 253459.

In this image processing apparatus, for example, as shown in FIG. 10, the input original luminance signal Y is converted into an A / D converter 50.
It is stored in the frame memory 51 as a luminance signal quantized by and is sent to the cumulative distribution calculator 52 at the same time. The cumulative distribution calculator 52 samples the original luminance signal for each predetermined image processing unit, and calculates a cumulative distribution A ^{NEW of} pixels with respect to the luminance L.
Calculate (L). The cumulative distribution of brightness obtained by the cumulative distribution calculator 52 is sent to the scene change detector 53 and the level detector 54. The scene change detector 53 obtains a difference ΔA between the cumulative distribution A ^NEW (L) obtained from the current image and the cumulative distribution A ^OLD (L) of the previous image by the equation (1) and sets the threshold value. When the difference is larger than the threshold value, a flag F indicating that a scene change has occurred is output.

[0007]

[Equation 1]

The current cumulative distribution is stored in memory so that it can be compared with the cumulative distribution determined from the next image. The level detector 54 uses the cumulative distribution of the current image and uses the brightness level L exceeding a predetermined frequency NS, NM, NH.
S (black level), LM (intermediate level), LH (white level) are detected. The time smoothing circuit 55 outputs the input levels LS, LM, and LH as they are when the output flag F of the scene change detector indicates that the scene has changed, and when it indicates that they are the same scene. , Black / intermediate / white level L obtained from the cumulative distribution of the current image
_X (X = S, M, H) and the level L _X ″ (X = S, M, H) used to construct the conversion curve of the previous image are linearly added by the equation (2). The level L _X '(x = S, M, H) smoothed in time is output.

[0009]

[Equation 2]

Further, the limiter 56 prevents the difference between the black level and the intermediate level and the difference between the intermediate level and the white level from becoming smaller than a predetermined value in order to prevent the inclination of the luminance conversion curve from becoming extremely steep. Restrict. The conversion curve calculator 57 calculates (3) from the time-smoothed and limited black / middle / white levels.
The brightness conversion curve X (L) is calculated by the formula and is output to the brightness conversion table 58.

[0011]

(Equation 3)

The brightness signal stored in the frame memory 51 is converted into a brightness-enhanced signal Y'by referring to the brightness conversion table 58. This process is also a process for increasing the brightness contrast, and this process is hereinafter referred to as adaptive brightness gradation conversion.

By the way, if brightness contrast enhancement processing such as histogram conversion, linear density conversion, and adaptive brightness gradation conversion is applied to an image with poor S / N, the contrast is increased but high-frequency noise is also emphasized at the same time. The image quality may be impaired.

Therefore, it is an object of the present invention to provide an image processing apparatus capable of preventing noise in a high frequency band from being emphasized when contrast enhancement of a luminance signal having a poor S / N is performed. It is in.

[0015]

An image processing apparatus according to the present invention comprises a filter means for extracting a low frequency component from an original luminance signal of an input image, a low frequency luminance obtained by the original luminance signal and the filter. Difference detection means for detecting a difference from the signal, contrast enhancement processing means for enhancing the brightness contrast of the low-frequency luminance signal, difference brightness signal obtained by the difference detection means, and contrast enhancement processing means The present invention is characterized by having a synthesizing means for synthesizing a low-frequency luminance signal whose contrast is enhanced by.

The image processing apparatus according to the present invention further comprises a contour enhancement processing means for subjecting the difference luminance signal obtained by the difference detection means to a contour enhancement processing, and the contour enhancement processing means performs contour enhancement. The differential luminance signal and the low-frequency luminance signal whose contrast is enhanced by the contrast enhancing processing means are combined by the combining means.

Further, the image processing apparatus according to the present invention comprises a filter means for extracting a low frequency component from the quantized original luminance signal of the input image, a low frequency range obtained by the original luminance signal and the filter means. From a difference detecting means for detecting a difference from a luminance signal, a cumulative distribution calculating means for sampling the low-frequency luminance signal and calculating a cumulative distribution of pixels with respect to a luminance level, and a cumulative distribution calculated by the cumulative distribution calculating means. The level detection means for obtaining the black / middle / white levels of the image, the scene change detection means for detecting a scene change using the cumulative distribution obtained by the cumulative distribution calculation means, and the detection output by the level detection means Level smoothing that applies processing to suppress sudden changes in black, middle, and white levels based on the output detected by the scene change detection means Step, a limiting means for limiting the level difference between the black, intermediate, and white levels with respect to the output of the level smoothing means, and a brightness gradation corresponding to the black, intermediate, and white levels obtained through the limiting means. The conversion curve calculation means for obtaining the conversion curve, the level conversion means for performing the level conversion processing on the low-frequency luminance signal using the luminance gradation conversion curve obtained by the conversion curve calculation means, and the difference detection means are obtained. It is characterized in that it has a synthesizing means for synthesizing the differential luminance signal and the low-frequency luminance signal whose contrast is enhanced by the level converting means.

Furthermore, the image processing apparatus according to the present invention comprises a contour enhancement processing means for subjecting the difference luminance signal obtained by the difference detection means to a contour enhancement processing, and the contour enhancement processing means performs contour enhancement. The differential luminance signal and the low-frequency luminance signal whose contrast is enhanced by the level converting means are combined by the combining means.

Further, the filter means includes an edge area detecting means for detecting an edge area of the original luminance signal of the input image, an extracting means for extracting a low frequency component from the original luminance signal of the input image, and the edge area detecting means. The present invention is characterized by further comprising: switching selection means for switching and selecting between the original luminance signal of the input image and the low-frequency luminance signal obtained by the extraction means based on the detection result of (1).

[0020]

The image processing apparatus according to the present invention separates the original luminance signal of the input image into the low-frequency luminance signal and the differential luminance signal,
Luminance contrast enhancement processing is applied to this low-frequency luminance signal,
Further, the differential luminance signal and the contrast-enhanced low-frequency luminance signal are added and combined and output. Furthermore, the difference luminance signal is subjected to processing such as noise removal and then subjected to contour enhancement, and then added to the contrast enhanced low-frequency luminance signal.

Further, in the image processing apparatus according to the present invention, the original luminance signal of the input image is separated into the low-frequency luminance signal and the differential luminance signal, and the cumulative distribution of luminance is obtained from the low-frequency luminance signal to calculate the luminance. Obtain the black / intermediate / white level from the cumulative distribution, detect the scene change from the temporal change of the cumulative distribution, perform the temporal smoothing of the black / intermediate / white level, and then limit the black / intermediate / white level. In addition, a brightness conversion curve is calculated from these levels, the level conversion of the low band brightness signal is performed by this brightness conversion curve, and the converted low band brightness signal and the differential brightness signal are combined and output. Further, the difference luminance signal is subjected to processing such as noise removal and then subjected to contour enhancement and then added to the contrast-enhanced low frequency component.

Further, in the image processing apparatus according to the present invention, in the filter means, the edge area detecting means detects the edge area of the original luminance signal of the input image. Further, the extraction means extracts a low frequency component from the original luminance signal of the input image. Then, the switching selecting means switches and selects the original luminance signal of the input image and the low-frequency luminance signal obtained by the extracting means based on the detection result of the edge area detecting means, and outputs the signal.

[0023]

Embodiments of the image processing apparatus according to the present invention will be described below in detail with reference to the drawings.

An image processing apparatus according to the present invention is shown in FIG.
It is configured as in the first embodiment shown in FIG.

The image processing apparatus of the first embodiment shown in FIG. 1 has a low-pass filter 10 and a subtractor 11 to which an original luminance signal is supplied, and contrast enhancement to which the output of the low-pass filter 10 is supplied. A circuit 12 and an adder 13 to which the output of the contrast enhancement circuit 12 is supplied are provided, and the output of the low-pass filter 10 is supplied to the subtractor 11.
The output of the subtractor 11 is supplied to the adder 13.

In this image processing apparatus, the original luminance signal of the input image is filtered by the low-pass filter 10 only for its low frequency components and is sent to the subtractor 11. The subtractor 11 obtains a differential luminance signal by subtracting the low-frequency luminance signal obtained by the low-pass filter 10 from the original luminance signal. In the contrast emphasizing circuit 12, the low-frequency luminance signal is subjected to contrast emphasizing processing by histogram conversion, linear density conversion, or the like. Then, the adder 13 adds and synthesizes the differential luminance signal obtained by the subtractor 11 and the low-frequency luminance signal subjected to the contrast enhancement processing by the contrast enhancement circuit 12 and outputs the result.

In the image processing apparatus of the first embodiment having such a configuration, the original luminance signal of the input image is separated into its low-frequency luminance signal and differential luminance signal, and the low-frequency luminance signal is subjected to luminance contrast enhancement processing. Since the differential luminance signal and the contrast-enhanced low-frequency luminance signal are added and combined and output, the high-frequency noise is not emphasized. Therefore, high-frequency noise is not emphasized when the contrast of a luminance signal having a poor S / N is emphasized.

The image processing apparatus according to the present invention is constructed, for example, as in the second embodiment shown in FIG.

The image processing apparatus according to the second embodiment shown in FIG. 3 has a contour enhancer 14 provided between the subtractor 11 and the adder 13 in the above-described first embodiment. Bandpass filter 10, subtractor 11, contrast enhancement circuit 12,
The structure and operation of the adder 13 are similar to those of the first embodiment.

In this image processing apparatus, the difference luminance signal obtained by the subtractor 11 is combined with the low-frequency luminance signal whose contour component is emphasized by the contour enhancer 33 and contrast enhanced by the adder 13 and output. It The contour enhancer 33 includes noise removal processing such as coring.

In the image processing apparatus of the second embodiment having such a configuration, the original luminance signal of the input image is separated into its low-frequency luminance signal and differential luminance signal, and the low-frequency luminance signal is subjected to luminance contrast enhancement processing. By adding and combining the differential luminance signal and the contrast-enhanced low-frequency luminance signal, the high-frequency noise is not emphasized when the contrast enhancement of the luminance signal with poor S / N is performed. Instead, by adding a process such as noise removal to the difference luminance signal and then applying contour enhancement to the contrast-enhanced low-frequency luminance signal, it is possible to form an image with enhanced resolution. .

The image processing apparatus according to the present invention is constructed, for example, as in the third embodiment shown in FIG.

The image processing apparatus of the second embodiment shown in FIG. 2 comprises an A / D converter 20 to which the original luminance signal Y is supplied, and the luminance signal quantized by this A / D converter 20. Is supplied to the low-pass filter 21 and the subtractor 22.

The low pass filter 21 obtains a low pass luminance signal by filtering low frequency components from the original luminance signal Y. The low-pass luminance signal obtained by the low-pass filter 21 is supplied to the subtractor 22 and the cumulative distribution detector 23, and further to the luminance conversion table 31 via the frame memory 26.

In the subtractor 22, the low-pass filter 2
The difference luminance signal is obtained by subtracting the low-frequency luminance signal obtained by 1 from the original luminance signal. Then, the low-pass luminance signal obtained by the low-pass filter 21 is supplied to the adder 32 via the frame memory 27.

The frame memories 26 and 27 can be omitted for reasons such as cost. in this case,
There is a delay between the luminance signal and the conversion curve that converts it.

The cumulative distribution calculator 23 samples the low-frequency luminance signal for each predetermined image processing unit, and calculates a cumulative distribution A ^NEW (L) of pixels with respect to the luminance L. The luminance cumulative distribution A ^NEW (L) obtained by the cumulative distribution calculator 23 is sent to the scene change detector 24 and the level detector 25. The scene change detector 24 calculates the difference ΔA between the cumulative distribution A ^NEW (L) obtained from the current image and the cumulative distribution A ^OLD (L) obtained from the previous image as described in (4) above.
Calculated from the formula and compared with the threshold value, and if the difference is greater than the threshold value, a flag F indicating that a scene change has occurred
Is output.

[0038]

[Equation 4]

The current cumulative distribution is stored in memory so that it can be compared with the cumulative distribution determined from the next image. As shown in FIG. 4, the level detector 25 uses the cumulative distribution of the current image to determine a predetermined frequency N _S , N _M , N _H.
Brightness levels L _S (black level), L _M (intermediate level), and L _H (white level) that exceed the threshold are detected. Time smoothing circuit 2
8 indicates the input level L _S when the output flag F of the scene change detector 24 indicates that the scene has changed.
When L _M and L _H are output as they are, indicating that the scenes are the same, the black, intermediate, and white levels L _X (X = S, M, H) obtained from the cumulative distribution of the current image Level L _X ″ used to construct the transformation curve of the previous image
(X = S, M, H) is linearly added by the equation (5):
Temporally smoothed level L _X '(X = S, M, H)
Is output.

[0040]

(Equation 5)

Further, the limiter 29 prevents the difference between the black level and the intermediate level and the difference between the intermediate level and the white level from becoming smaller than a predetermined value in order to prevent the inclination of the brightness conversion curve from becoming extremely steep. Restrict. The conversion curve calculator 30 calculates (6) from the time-smoothed and limited black / middle / white levels.
The brightness conversion curve X (L) is calculated by the formula and is output to the brightness conversion table 31. The relationship between the black / middle / white level and the brightness conversion curve is shown in FIG.

[0042]

(Equation 6)

The low-frequency component of the luminance signal stored in the frame memory 26 is converted into a luminance-emphasized signal by referring to the luminance conversion table 31, and is added to the differential luminance signal stored in the frame memory 27. A luminance signal Y'combined by the device 32 and subjected to desired luminance enhancement is obtained.

In the image processing apparatus of the third embodiment having such a configuration, the original luminance signal of the input image is separated into its low-frequency luminance signal and differential luminance signal, and the cumulative luminance distribution is calculated from this low-frequency luminance signal. Then, the black / intermediate / white level is obtained from the cumulative distribution of brightness, the scene change is detected from the temporal change of the cumulative distribution, and the black / intermediate / white level is temporally smoothed before the black / intermediate / white level. By limiting the white level, a brightness conversion curve is calculated from these levels, the low-frequency brightness signal is level-converted by this brightness conversion curve, and the converted low-frequency brightness signal and the differential brightness signal are combined. The noise in the high frequency range is not emphasized.

The image processing apparatus according to the present invention is constructed, for example, as in the fourth embodiment shown in FIG.

The image processing apparatus according to the fourth embodiment shown in FIG. 6 has a contour enhancer 40 provided between the subtractor 22 and the frame memory 27 in the above-mentioned second embodiment. / D converter 20, low-pass filter 21, subtractor 2
2, frame memories 26 and 27, cumulative distribution calculator 23,
Scene change detector 24, level detector 25, time smoothing circuit 28, limiter 29, conversion curve calculator 30,
The configurations and operations of the brightness conversion table 31 and the adder 32 are the same as those in the third embodiment.

In this image processing apparatus, the contour component of the differential luminance signal obtained by the subtractor 22 is enhanced by the contour enhancer 40, and the difference luminance signal is supplied to the adder 32 via the frame memory 27. Then, in the adder 32, the edge-enhanced differential luminance signal is combined with the contrast-enhanced low-frequency luminance signal and output as the luminance signal Y ′. The contour enhancer 33 includes noise removal processing such as coring. In the image processing apparatus of the fourth embodiment having such a configuration, the original luminance signal of the input image is separated into the low frequency luminance signal and the differential luminance signal, and the low frequency luminance signal is subjected to the luminance contrast enhancement processing, Further, by adding and synthesizing the differential luminance signal and the contrast-enhanced low-frequency luminance signal, not only the high-frequency noise is not enhanced when the contrast enhancement of the luminance signal with poor S / N is performed, An image with a high sense of resolution can be configured by adding the contour-enhanced signal to the difference luminance signal after performing processing such as noise removal on the contrast-enhanced low-frequency luminance signal.

The low-pass filter 1 shown in FIGS.
0 and the low-pass filter 21 shown in FIGS.
As shown in FIG. 7, filter means 8 may be used to detect a region near a luminance edge from an original luminance signal of an input image and to extract low frequency components in a region other than the edge region.

That is, the filter means 8 has the edge area detector 8 to which the original luminance signals of the input image are respectively supplied.
0, a low-pass filter 82, and a selector 81,
The output of the low-pass filter 82 and the output of the edge area detector 80 are also supplied to the selector 81.

The edge area detector 80 is a circuit for detecting the edge area of the supplied original luminance signal, and sends a select signal corresponding to the detection result to the selector 81. The low-pass filter 82 is the low-pass filter 10 described above, and
Similar to the low-pass filter 21, the low-pass filter 21 filters only the low-frequency components of the supplied original luminance signal.

Therefore, the selector 81 is supplied with the original luminance signal of the input image, the select signal from the edge area detector 80, and the low-pass luminance signal obtained by the low-pass filter 82. It The selector 81 is
Based on the select signal from the edge area detector 80, the original luminance signal and the low frequency luminance signal are switched and selected and output. Specifically, when the select signal from the edge area detector 80 indicates an edge area, the original luminance signal is selected and output, and when it does not indicate the edge area, a low-frequency luminance signal is selected and output. .

Here, in FIG. 8, the dotted line A in the drawing is
A low-pass filter 10 or a low-pass luminance signal obtained by the low-pass filter 21 shows a luminance change near an edge E of an image whose luminance is converted by gradation conversion.
Indicates a change in brightness near the edge E of an image whose brightness is converted by gradation conversion for the signal obtained by the filter means 8.

As shown in FIG. 8 above, in the solid line A, the bluntness of the edge is seen in the vicinity E of the edge, while in the solid line B.
Then, near the edge E, a steep slope is held like the original luminance signal. This indicates that the low pass filter 82 of the filter means 8 is effectively operating.

Therefore, by applying the low-pass filter to the area other than the edge area as described above, the brightness contrast is not impaired without deteriorating the sense of resolution near the edge and without deteriorating the S / N ratio. Can be emphasized.

[0055]

As described above, in the image processing apparatus according to the present invention, the original luminance signal of the input image is separated into the low-frequency luminance signal and the differential luminance signal, and the low-frequency luminance signal is subjected to luminance contrast enhancement. Since the processing is performed, and the differential luminance signal and the contrast-enhanced low-frequency luminance signal are added and combined and output, high-frequency noise is not emphasized. Further, an image with enhanced resolution can be configured by adding contour-enhanced information to the differential luminance signal after processing such as noise removal and the like to the contrast-enhanced low-frequency luminance signal.

Further, in the image processing apparatus according to the present invention, the original luminance signal of the input image is separated into the low-frequency luminance signal and the differential luminance signal, and the cumulative distribution of luminance is obtained from this low-frequency luminance signal to calculate the luminance. Obtain the black / intermediate / white level from the cumulative distribution, detect the scene change from the temporal change of the cumulative distribution, perform the temporal smoothing of the black / intermediate / white level, and then limit the black / intermediate / white level. In addition, the brightness conversion curve is calculated from these levels, the level conversion of the low band brightness signal is performed by this brightness conversion curve, and the converted low band brightness signal and the differential brightness signal are combined and output. , High frequency noise is not emphasized. Further, an image with enhanced resolution can be configured by adding a contour-enhanced signal to the differential luminance signal after processing such as noise removal and the like to the contrast-enhanced low frequency component.

Furthermore, in the image processing apparatus according to the present invention, in the filter means, the edge area detecting means detects the edge area of the original luminance signal of the input image. Further, the extraction means extracts a low frequency component from the original luminance signal of the input image. Then, the switching selecting means switches and selects the original luminance signal of the input image and the low-frequency luminance signal obtained by the extracting means based on the detection result of the edge area detecting means, and outputs the signal. Thereby, the low-pass filter can be applied to the area other than the edge area. For this reason,
S / N without sacrificing resolution near the edges
Brightness contrast enhancement processing can be performed without deteriorating the ratio.

As described above, according to the present invention, in the image processing apparatus for displaying the input image, the enhancement processing such as the histogram conversion, the linear density conversion, and the adaptive brightness gradation conversion is applied to the input brightness signal. At this time, by limiting the luminance enhancement processing only to the low frequency component of the input luminance signal, it is possible to prevent the high frequency noise from being emphasized when the contrast enhancement of the luminance signal having a poor S / N is performed. You can Also, without impairing the resolution near the edge,
Further, the brightness contrast enhancement process can be performed without deteriorating the S / N ratio.

[Brief description of drawings]

FIG. 1 is a block circuit diagram showing a configuration of a first embodiment of an image processing apparatus according to the present invention.

FIG. 2 is a block circuit diagram showing a configuration of a second embodiment of the image processing apparatus according to the present invention.

FIG. 3 is a block circuit diagram showing the configuration of a third embodiment of the image processing apparatus according to the present invention.

FIG. 4 is a diagram illustrating a relationship between a cumulative distribution of brightness of an input image and black / intermediate / white levels in the image processing apparatus according to the third embodiment.

FIG. 5 is a diagram showing a relationship between a cumulative distribution of luminance of an input image and black / intermediate / white levels in the image processing apparatus of the third embodiment.

FIG. 6 is a block circuit diagram showing a configuration of a fourth embodiment of the image processing apparatus according to the present invention.

FIG. 7 is a block circuit diagram showing a configuration of a filter unit that applies a low-pass filter to a region of the input image other than the vicinity of the luminance edge.

FIG. 8 is a diagram illustrating a luminance change near an edge of an image.

FIG. 9 is a diagram showing input / output characteristics of an auto pedestal circuit.

FIG. 10 is a block circuit diagram showing a configuration of an image processing apparatus that performs adaptive luminance gradation conversion.

[Explanation of Codes] 10,21 Low-pass filter 11,22 Subtractor 12 Contrast enhancement circuit 13,32 Adder 14 Edge enhancement circuit 20 A / D converter 23 Cumulative distribution calculator 24 Scene change detector 25 Level detector 26 , 27 frame memory 28 time smoothing circuit 29 limiter 30 curve detector 31 brightness conversion table 40 contour enhancement circuit

Claims (5)

[Claims] 1. A filter means for extracting a low frequency component of an original luminance signal of an input image, a difference detecting means for detecting a difference between the original luminance signal and a low-frequency luminance signal obtained by the filter, Contrast enhancement processing means for enhancing the luminance contrast of the low-frequency luminance signal, and synthesis for synthesizing the differential luminance signal obtained by the difference detection means and the low-frequency luminance signal contrast-enhanced by the contrast enhancement processing means. An image processing apparatus comprising means. 2. A contour enhancement processing means for performing contour enhancement processing on the differential luminance signal obtained by the difference detection means, the differential luminance signal contour enhanced by the contour enhancement processing means and the contrast enhancement processing means. 2. The image processing apparatus according to claim 1, wherein the low-frequency luminance signal having the contrast enhanced by the above is combined by the combining means. 3. A filter means for extracting a low frequency component from a quantized original luminance signal of an input image, and a difference for detecting a difference between the original luminance signal and a low-frequency luminance signal obtained by the filter means. A detection means, a cumulative distribution calculating means for sampling the low-frequency luminance signal, and calculating a cumulative distribution of pixels with respect to the luminance level, and a black / intermediate / white level of the image from the cumulative distribution calculated by the cumulative distribution calculating means. Based on the detection output of the scene change detection means with respect to the detection output of the level detection means, the scene change detection means for detecting a scene change using the cumulative distribution obtained by the cumulative distribution calculation means, Black, middle,
Level smoothing means for suppressing abrupt changes in the white level, limiting means for limiting the level difference between the black, intermediate and white levels with respect to the output of the level smoothing means, and the limiting means. Level conversion processing to the low-frequency luminance signal using a conversion curve calculation means for obtaining a brightness gradation conversion curve corresponding to the black, intermediate, and white levels obtained by the above, and a brightness gradation conversion curve obtained by the conversion curve calculation means. An image processing apparatus comprising: a level converting means for performing the above; and a synthesizing means for synthesizing the difference luminance signal obtained by the difference detecting means and the low-frequency luminance luminance signal whose contrast is emphasized by the level converting means. 4. A contour enhancement processing means for subjecting the difference luminance signal obtained by the difference detection means to a contour enhancement processing, the difference luminance signal being contour enhanced by the contour enhancement processing means, and the level conversion means. 4. An image processing apparatus according to claim 3, wherein the contrast enhancing low-frequency luminance signal is synthesized by the synthesizing means. 5. The filter means includes an edge area detecting means for detecting an edge area of an original luminance signal of an input image, an extracting means for extracting a low frequency component from the original luminance signal of the input image, and the edge area detecting means. 4. The switching selection means for switching and selecting between the original luminance signal of the input image and the low-frequency luminance signal obtained by the extraction means based on the detection result of 1. Image processing device.