JPH0130347B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a device for improving the image quality of a color television receiver, particularly a projection display device for high definition television.

Conventional technology High-definition television displays high-definition television images on a large screen to give viewers a sense of impact and realism that cannot be obtained with existing television receivers. It is something.

A CRT projection display device is being developed as one of such high-definition television display devices. For details of such a CRT projection display device, please refer to the paper by Kubo et al. entitled ``Development of CRT type display for high-definition television'', lecture number SP1-15 of the 1982 National Conference of the Television Society.

In the above-mentioned CRT projection display device, it is considered essential to perform contour correction between the camera and the image receiver in order to compensate for the decrease in resolution due to the increase in the size of the optical system. For more information on this type of contour correction, see
Television Society 1983 National Conference Lecture No. 12-2
"Digital contour corrector for high-quality television cameras"
Please refer to the paper by Okada et al.

Further, in the above-mentioned projection display device, large flare interference occurs due to reflected components caused by the projection light passing through the lens multiple times and the finite thickness of the screen. A video signal with large flare is accompanied by an increase in low frequency components. For more information on such flare disturbances, please refer to the Television Society
Please refer to the paper by Kanazawa et al. titled 1982 National Convention Lecture No. SP-14, "Improvement of Image Quality of High-Definition Television Projection Displays - Removal of Flare Interference by SAW Filter."

Problems to be Solved by the Invention An attempt was made to improve the image quality of a color television receiver such as a projection display device for high-definition color television by performing contour correction and flare correction in the horizontal and vertical directions. In this case, it is necessary to extract the following various problems and provide answers to each one, taking into account the relationship with other problems.

[A] The question of whether to implement it with analog circuits or digital circuits Video signals are supplied as analog signals, with some special exceptions, and analog circuits are generally simpler and simpler than digital circuits. It's cheap. Therefore, in terms of circuit scale and cost, it is desirable to implement the above image quality improvement device using an analog circuit.

On the other hand, analog
Considerable difficulty is expected in realizing the filter.

For example, according to the paper by Kanazawa et al. mentioned above, by amplitude modulating a video signal with a high frequency carrier frequency, it is first converted into a high frequency, wideband video signal of about 150 MHz ± 20 MHz, and the converted video signal is A method has been attempted in which horizontal flare correction is performed by attenuating only the frequency components of 1 MHz above and below 150 MHz by about 6 dB using a SAW filter and then demodulating them.

According to the above method, a reliable effect is achieved in that a simple and inexpensive analog circuit can be used. On the other hand, with this method, at least 100M
There is a problem in that high-frequency signal processing at Hz or higher is required. Another problem is that if this method is applied not only to the horizontal component of flare but also to the vertical component, a large number of one-line delay circuits with extremely high precision, which is close to the limit of analog circuits, will be required. There is also.

[B] The question of whether to implement everything with a digital circuit If the image quality improvement device is implemented with a digital circuit, it is related to the issue of whether or not to perform correction for each of the three primary colors, which will be discussed later. There is a question of whether or not to allow the analog part to coexist.

The above-mentioned paper by Okada et al. discloses a digital contour corrector based on a combined analog method. That is, of the analog video signals of the three primary colors R, G, and B, only the G signal is converted into a digital signal, and a digital contour correction signal is created based on this. The above-mentioned digital G signal is digitally added by the above-mentioned digital contour correction signal, and then converted into a corrected analog G signal.
Restored to signal. On the other hand, the digital contour correction signal is converted into an analog signal and then added to the original R signal and B signal as analog signals to obtain corrected analog R and B signals.

In this way, if the analog part coexists,
There is a certain effect that the circuit becomes simpler and cheaper. On the other hand, such a combined analog method has the problem that a delay compensation circuit and the like for compensating the processing time must be implemented using an analog circuit such as an LC circuit.
In other words, this type of analog circuit has lower adjustment accuracy than a digital circuit, and is more susceptible to temperature fluctuations, so unless high-precision stabilization measures are taken for such analog systems, the characteristics will not stabilize. There is a problem that a difference in delay time occurs between the digital system and the digital system, which may even deteriorate the image quality.

[C] The issue of whether or not to perform correction for each of the three primary colors The appearance of outlines in the screen and the occurrence of flare interference are
It is thought that there is a considerable degree of correlation between the three primary color signals. Therefore, by correcting the three primary color signals with the correction signal created only from the luminance signal, the scale of the correction signal creation circuit can be reduced to one-third.

In addition, as described in the paper by Okada et al. mentioned above, if a correction signal is generated from the G signal that contributes most to the luminance signal, and the three primary color signals are corrected with this correction signal, the luminance signal is converted from the three primary color signals. The matrix circuit for creating the matrix can be omitted, and the circuit scale can be further reduced.

Although the above method has the advantage of being able to significantly reduce the circuit scale, it has the problem that the image quality immediately deteriorates when the correlation between the contours between the three primary colors is lost. There are many cases in which the correlation between the three primary colors is lost due to the appearance of a monochromatic outline on the screen, and the degree of flare interference is thought to differ for each of the three primary colors with different wavelengths.

[D] The issue of whether contour compensation and flare compensation should be processed simultaneously by the same circuit Contour compensation is performed by extracting a contour signal from the high-frequency components of the image and adding it to the original image. . Flare correction is performed by suppressing low frequency components of the video signal. Therefore, both contour correction and flare correction have a common aspect of emphasizing high-frequency components of a video signal. Therefore, if both correction processes are performed simultaneously by the same circuit, the number of stages of processing circuits can be halved.

On the other hand, the frequency range and frequency characteristics to be processed are quite different between the two, and processing both in the same circuit at the same time is expected to make the design of the processing circuit difficult and increase the scale of the processing circuit. Ru. Furthermore, the above simultaneous processing method is expected to have a problem in that it becomes difficult to independently adjust the characteristics of contour correction and flare correction during assembly or use.

[E] The question of whether to process contour correction and flare correction in the horizontal and vertical directions in parallel If contour correction and flare correction are not performed simultaneously in the same circuit, contour correction and flare correction in the horizontal direction , vertical contour correction, and flare correction are required.

Assuming digital processing, a configuration in which all of the above four types of processing are performed in parallel has the greatest effect in improving the average image quality of the screen in that rounding errors do not accumulate.

On the other hand, if you perform horizontal and vertical processing in parallel, you will end up with an angular window.
In patterns etc., the four corners are no longer processed,
It is expected that the image quality of that part will be relatively degraded compared to other parts, and that the uniformity of the image quality of the entire screen will be impaired.

Also, since the time required for the above four types of processing is different, if all of these processes are performed in parallel, the processing will be completed until the vertical flare processing (creating the flare correction signal), which takes the longest time, is completed. The other three types of correction processing must be delayed, and there is also the problem that the scale of the delay compensation circuit within the correction signal generation circuit becomes large.

[F] The question of whether or not to process contour correction and flare correction in the horizontal and vertical directions all in series If the above four types of correction processing are all carried out in series, as soon as one correction process is completed, the next one will be processed immediately. Since processing can be started, there is an advantage that a delay compensation circuit in the correction circuit is not required.

On the other hand, whether horizontally or vertically,
If the configuration is such that contour correction and flare correction are performed in series, there are disadvantages in that the design of the processing circuit becomes difficult and the scale of the processing circuit becomes large, as in the case of simultaneous processing using the same circuit described above.

Another disadvantage is that rounding errors associated with the four types of processing are accumulated.

[G] The question of whether or not to use a high-pass filter circuit As mentioned above, contour correction and flare correction are processes that suppress low frequencies and emphasize high frequencies, so a configuration that uses a high-pass filter circuit is straightforward. It is true.

However, in order to prevent the problem that the four corners are not processed as described in (E) above, horizontal processing and vertical processing are performed in series, and in this case, if a high-pass filter circuit is used, A new four-corner problem arises due to a different cause. In other words, the level of the four outer corners of the window, whose level has decreased due to horizontal contour correction, increases in level due to the next vertical contour correction, and the image quality improvement effect of only the four corners becomes relatively A problem arises in that it deteriorates and becomes an eyesore.

[H] The question of what kind of filtering circuit to use Especially when performing digital processing, an acyclic filter (transversal filter) should be used, regardless of whether it is a high-pass filtering circuit or not. The problem is whether to use a recursive filter or a recursive filter.

[I] The issue of whether to create a correction signal from the original signal that has been γ-corrected The video signal is subjected to γ-correction to compensate for the nonlinearity of the voltage/current characteristics of the CRT cathode. . If a correction signal is created from a video signal that has been subjected to this γ correction, the linearity of the correction signal itself will be lost, causing dark areas (low brightness areas) on the screen.
There is a possibility that the S/N ratio in the image will deteriorate and the effectiveness of the correction will decrease.

The main problems encountered in improving image quality by performing contour correction and flare correction in the horizontal and vertical directions have been listed above. According to the inventor's estimates, thousands of different configurations will be reached depending on the answers to the various problems mentioned above.

Means for Solving the Constituent Problems of the Invention The image quality improving device of the present invention, which solves the problems of the prior art described above, uses digital video signals each consisting of an R, G, B or luminance signal and two types of color signals. A three-system image quality improvement correction signal generation circuit that generates image quality improvement signals including a contour correction signal and a flare correction signal; a delay compensation circuit that delays each of the A/D converted digital video signals by a predetermined time; It is configured to include a digital addition circuit that adds the image quality improvement correction signal to each of the delayed digital video signals, and a D/A conversion circuit that converts the video signal after the digital addition into a corresponding analog video signal. ing.

The above three systems of image quality improvement correction signal generation circuits are composed of separate contour correction signal generation means and flare correction signal generation means, and each correction signal generation means is a low-pass filter circuit that low-pass filters a digital luminance signal. , a delay circuit that delays the digital luminance signal by a predetermined amount, and a digital subtraction circuit that subtracts the low-pass filtered digital video signal from the delayed digital video signal.

The contour correction signal creation means and the flare correction signal creation means are installed in parallel with each other, and each correction signal creation means includes a low-pass filter circuit for creating a vertical correction signal and a horizontal correction signal installed in series with each other. It is configured to include a low-pass filter circuit for signal generation.

In a preferred embodiment of the present invention, each low-pass filtering circuit of the contour correction signal generating section comprises a transversal filter, and each low-pass filtering circuit of the flare correction signal generating section comprises a recursive filter. .

In a further preferred embodiment of the present invention, the contour correction signal generation section and the flare correction signal generation section are configured to include an inverse γ correction circuit at the front stage and a γ correction circuit at the rear stage.

Hereinafter, the effects of the present invention will be explained in detail by way of examples.

Embodiment FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

In the image quality improvement device of this embodiment, 1a to 1c
is an input terminal, 2a to 2c are A/D conversion circuits, 3a
~3c are correction signal generation circuits, 4a~4c are frame delay circuits, 5a~5c are line delay circuits, 6a
-6c are adder circuits, 7a-7c are D/A conversion circuits, and 8a-8c are output terminals.

High-definition television analog video signals R, G, and B are supplied to the input terminals 1a to 1c, respectively. These analog video signals R, G, and B are
After being sampled at a predetermined sampling frequency by the A/D conversion circuits 2a to 2c, the signals are converted into, for example, 8-bit digital video signals R, G, and B. The video signals R, G, and B converted into digital signals are respectively sent to correction signal generation circuits 3a to 3a.
One input terminal 3a-2, 3b-2, 3c of 3c
-2. On the other hand, each of the digital video signals R, G, and B is sent to a frame delay circuit 4a.
4c and line delay circuits 5a to 5c, the correction signal generation circuits 3a to 3c are delayed by approximately one frame and several lines of time required to generate the correction signal. At this time, the digital video signals R, G, and B delayed by approximately one frame time in the frame delay circuits 4a to 4c are sent to the other input terminals 3a-1 and 3b of the correction signal generation circuits 3a to 3c, respectively.
-1,3c-1.

The delayed digital video signals R, G, and B are
In the digital addition circuits 6a to 6c, the output terminals 3a-3 and 3b of the correction signal generation circuits 3a to 3c
-3 and 3c-3, and are digitally added to the contour correction signal and flare correction signal supplied from each of the signals. Through this digital addition, digital video signals R, G,
B is restored to analog video signals R, G, and B in the D/A conversion circuits 7a to 7c, and output to the output terminal 8.
It is output to a to 8c.

In the device of this embodiment, both frame delay circuits 4a to 4c and line delay circuits 5a to 5c are RAM
The input digital video signal is sent to a correction signal generation circuit 3A/D conversion circuit 3A/D conversion circuit 3
c is delayed by one frame and several lines required to create a correction signal and is supplied to one input terminal of the adder circuits 6a to 6c.

All three correction signal generation circuits 3a to 3c have the same configuration. Therefore, below, the configuration of the three correction signal generation circuits will be described as correction signal generation circuit 3.
This will be explained using a as a representative example.

FIG. 2 is a block diagram showing the configuration of the correction signal generating circuit 3a.

The correction signal generation circuit 3a includes a contour correction signal generation circuit 20 and a flare correction signal generation circuit 30 connected in parallel, and a digital addition circuit 40 that digitally adds both correction signals.

The contour correction signal creation circuit 20 includes an inverse γ circuit 21 that cancels γ correction of the digital R signal, and a series-connected low-pass filter circuit (LPF) for vertical contour correction.
22 and a low-pass filter circuit 23 for horizontal contour correction
, a subtraction circuit 26, and a delay compensation circuit 41 that delays the R signal extracted from the center tap 22a of the vertical contour correction low-pass filter circuit 22 to match the phases of the two inputs of the subtraction circuit 26; The coring circuit 27 includes a coring circuit 27 having a γ correction function.

Similarly, the flare correction signal generation circuit 30 also has an inverse γ
It consists of a circuit 31, a vertical flare correction low-pass filter circuit 32 and a horizontal flare correction low-pass filter circuit 33 connected in series, a subtraction circuit 36, and a coring circuit 37 having a γ correction function.

The correction signal generation circuit 3a of this embodiment temporarily extracts the low-frequency components of the digital video signal R using the low-pass filter circuits 22 and 23 for contour correction and the low-pass filter circuits 32 and 33 for flare correction. Then, by subtracting this extracted low-frequency component from the digital video signal R delayed by a predetermined time, a contour correction signal and a flare correction signal are created.

The reason for this configuration, which extracts low-frequency components and subtracts them from the original signal, is to prevent image quality deterioration at the four corners that occurs when each correction signal is extracted from the video signal R using a high-pass filter circuit. This is to do so.

Each video signal R supplied to the input terminals 3a-1 and 3a-2 is subjected to γ correction to compensate for the nonlinearity of the voltage/current characteristics of the cathode of the CRT. If a correction signal is created from the luminance signal Y that has been subjected to this γ correction, the linearity of the correction signal itself may be lost, the S/N ratio in dark areas of the screen may deteriorate, and the effect of the correction may be reduced.

Therefore, as shown in FIG. 2, the γ-corrected video signal R is stored in an inverted γ
After the correction circuits 21 and 31 cancel the γ correction and restore it to a value having a linear relationship with the amount of light received by the imaging device, the low-pass filter circuits 22 and 23 for contour correction and flare correction are applied, respectively. The signal is supplied to low-pass filter circuits 32 and 33 for use. The outputs of the low-pass filter circuit 23 for horizontal contour correction and the low-pass filter circuit 33 for horizontal flare correction are extracted from the center tap 22a of the low-pass filter circuit 22 for vertical contour correction in subtraction circuits 26 and 36, respectively. It is subtracted from the digital video signal R which has been delayed by the delay compensation circuit 41 and has the same phase.

Each of the coring circuits 27 and 37 also has a γ correction function, and when each of the created contour correction signal and flare correction signal is below a predetermined level, the output of each of them is set to zero, thereby correcting the correction signal. This suppresses high-frequency noise that mixes into the screen and prevents S/N deterioration in dark areas of the screen. An example of the predetermined levels is levels 2 to 6 with respect to the maximum level 256 expressed in 8 bits.

The adder circuit 40 includes each coring circuit 27, 37.
The contour correction signal and flare correction signal that have passed through are added and synthesized.

The vertical contour correction low-pass filter circuit 22 and the horizontal contour correction low-pass filter circuit 23 are both constructed of transversal filters as shown in FIG. This transversal filter includes delay circuits 51a to 51d connected in series to delay the digital video signal R supplied to the input terminal 50 by a predetermined amount, and delay circuits 51a to 51d connected in series to delay each digital video signal R by a predetermined amount. It is composed of coefficient circuits 52a to 52e that multiply values, and an adder group 53 that adds the outputs of each coefficient circuit according to a predetermined algorithm, and outputs a low frequency component for contour correction extracted from the digital video signal R to an output terminal 54. Output to.

In the vertical contour correction low-pass filter circuit 22, the delay circuits 51a to 51d are composed of line memories that delay the digital video signal R by one line. On the other hand, in the horizontal contour correction low-pass filter circuit 23, the delay circuits 51a to
51d is composed of a dot memory that delays the digital video signal R by one sampling period.

The vertical flare correction low-pass filter circuit 32 and the horizontal flare correction low-pass filter circuit 33 each include two recursive filters 61 and 63 of the same configuration and two recursive filters 61 and 63 of the same configuration, as shown in FIG. The time axis reversing circuit 62 and 64 are configured.

In the above-mentioned contour correction, it is sufficient to perform signal processing between several adjacent sampling points, but the influence of flare generally extends to a very large number of adjacent sampling points. Therefore, if flare processing were to be performed by a transversal filter, an extremely large number of delay circuits, coefficient circuits, and adder circuits would be required, and the scale of the filter would be extremely large. Therefore, a recursive filter is used for flare correction.

In the vertical flare correction low-pass filtering circuit 32, the time axis inversion circuits 62 and 64 perform field inversion that writes the digital video signal R for one field and then reads it out in the reverse order of the writing. Consists of memory. On the other hand, in the horizontal contour correction low-pass filter circuit 33, the time axis inverting circuits 62 and 64 write the digital video signal R for one line, and then write the digital video signal R in the reverse order of the writing. It consists of a line inversion memory that is read out. The phase characteristics are improved by inverting the time axis of the digital video signal R passed through the recursive filter 61 and passing it through the recursive filter 63 again to achieve a linear phase.

The recursive filters 61 and 62 are, as exemplified by the recursive filter 61, adder circuits 70a to 70c and delay circuits 71a to 71.
c, and coefficient circuits 72a to 72c. The delay circuits 71a to 71c are recursive filters for vertical flare correction, and are composed of line memories that provide one line of delay to the digital video signal R. On the other hand, the recursive filters for horizontal flare correction are configured to delay the digital video signal R. It consists of a dot memory that provides a delay of one sampling period.

FIG. 5 shows an example of the contour correction signal output from the coring circuit 27 as a spatial frequency characteristic (MTF).
This is shown in . The level of the contour correction signal is
It is zero up to 100 TV books, and from 100 TV books
Up to 300 TV lines, as the spatial frequency increases,
Can increase linearly at a rate of 12dB/200 lines, 300TV
The signal can increase to a level 12 dB higher than the original luminance signal.

FIG. 6 shows an example of the flare correction signal output from the coring circuit 37 as a spatial frequency characteristic (MTF).
This is shown in . The level of the flare correction signal is
It is zero up to 15 TV lines, and from 12 TV lines to 30 TV lines it decreases by approximately 6 dB/ as the spatial frequency increases.
It can increase linearly at a rate of 15 TV lines, and over 30 TV lines it can increase to a level 6 dB greater than the original luminance signal.

FIG. 7 is a block diagram showing an example of the configuration of a coefficient circuit used in the transversal filter of FIG. 3 and the recursive filter of FIG. 4.

This coefficient circuit is composed of a selector 81 and a RAM 82.

For example, the CPU selects the selector 81 during the vertical blanking period when the screen is not displayed.
A CPU that commands the selection of a CPU address and multiplies the CPU address whose value increases gradually by a predetermined coefficient to be set to this CPU address.
Output DATA repeatedly. This CPU DATA
is supplied to the data write terminal Din of the RAM 82 and written into 256 areas specified by the CPU address. When the CPU finishes writing the coefficients, it instructs the selector 81 to select DATA (digital video signal R). After this, when the RAM 82 is addressed by the digital video signal R,
The digital video signal R that has been multiplied by the coefficient is output as DATAout from the data output terminal Dout.

In this way, by configuring the coefficient circuit with RAM, calculation speed is improved compared to configuring it with ROM or multipliers, etc., and correction can be made by changing the coefficient value at the adjustment stage during manufacturing or during use. Characteristics can be adjusted.

Although a configuration has been exemplified above in which the R, G, and B video signals are independently corrected, a configuration in which the video signal consisting of a luminance signal and two types of color signals is independently corrected may also be used. However, the above two types of color signals are appropriate signals that can restore the three primary color signals of R, G, and B from these and the luminance signal, and in the case of high-definition television signals, they are each a wideband color signal (CW). , narrowband color signal (C _N ), etc., and in the case of NTSC signals, these are (RY) and (B-Y) signals, or I and Q signals, respectively.

In addition, although we have illustrated a configuration in which image quality is improved by converting an analog video signal into a digital video signal using an A/D conversion circuit, if the video signal has already been digitized, the above A/D conversion circuit can be used. Of course, it is not necessary.

Effects of the Invention As explained in detail above, the image quality improvement device of the present invention is configured to perform contour correction and flare correction independently for three systems: video signals R, G, B or luminance signals and two color signals. Therefore, the effect of improving image quality can be further enhanced compared to the case where the above correction is performed only using the luminance signal or the G signal.

Since the image quality improvement device of the present invention is entirely composed of digital circuits, it is possible to improve image quality with high accuracy and stability.

Furthermore, since the image quality improvement device of the present invention is composed of separate contour correction signal generation means and flare correction signal generation means in which each of the three correction signal generation circuits is arranged in parallel, the design of each correction signal generation means is This makes it easier to operate, and the scale of each circuit can also be reduced.

Furthermore, in the image quality improvement device of the present invention, the filter circuits for vertical correction and horizontal correction in each correction signal generating means are connected in series, and these are not high-pass filter circuits but low-pass filter circuits. As a result, there is no deterioration in image quality at the four corners of the angular window.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention, FIG. 2 is a block diagram showing an example of the configuration of the correction signal generation circuit 3a in FIG. FIG. 4 is a block diagram showing an example of the configuration of the low-pass filter circuit 22 for vertical flare correction and the low-pass filter circuit 23 for horizontal contour correction shown in FIG. 2. A block diagram showing an example of the configuration of the low-pass filter circuit 33,
Fig. 5 is a characteristic diagram showing an example of the contour correction signal;
The figure is a block diagram showing an example of a flare correction signal, and FIG. 7 is a block diagram showing an example of the configuration of a coefficient circuit in a low-pass filter circuit. 1a-1c...input terminal, 2a-2c...A/
D conversion circuit, 3a to 3c...correction signal creation circuit,
4a to 4c...frame delay circuit, 5a to 5c...
...Line delay circuit, 6a-6c... Addition circuit, 7
a to 7c...D/A conversion circuit, 8a to 8c...output terminal, 20...contour correction signal creation circuit, 21,
31... Inverse γ correction circuit, 22... Low pass filter circuit for vertical contour correction, 23... Low pass filter circuit for horizontal contour correction, 30... Flare correction signal creation circuit, 32... For vertical flare correction Low pass filter circuit, 33... Low pass filter circuit for horizontal flare correction, 26, 36... Subtraction circuit, 27, 37... Coring circuit, 40... Addition circuit, 41... Delay compensation circuit.

Claims (1)

[Claims] 1. Image quality improvement correction for creating a digital image quality improvement signal including a contour correction signal and a flare correction signal from each digital video signal consisting of an R, G, B or luminance signal and two types of color signals. a signal generation circuit; a delay circuit that delays each of the digital video signals by a predetermined time; a digital addition circuit that digitally adds the image quality improvement correction signal to each of the delayed digital video signals; a digital-to-analog conversion circuit that converts a digital video signal into a corresponding analog video signal; each of the image quality improvement correction signal generation circuits includes a low-pass filtering circuit that performs low-pass filtering of one of the digital video signals; , a delay circuit for delaying one of the digital video signals for a predetermined time, and a subtraction circuit for subtracting one of the low-pass filtered digital video signals from one of the delayed digital video signals, respectively. The contour correction signal generating means and the flare correction signal generating means in each of the image quality improvement correction signal generating circuits are connected in parallel to each other, and each of the correction signal generating means A color television image quality improvement device characterized in that the means comprises a low-pass filter circuit for creating a vertical correction signal and a low-pass filter circuit for creating a horizontal correction signal, which are connected in series with each other. 2. Claims characterized in that each low-pass filtering circuit of the contour correction signal generating means consists of a transversal filter, and each low-pass filtering circuit of the flare correction signal generating means consists of a recursive filter. 2. The color television image quality improvement device according to claim 1. 3. The contour correction signal generating means and the flare correction signal generating means are each equipped with an inverse γ correction circuit at a preceding stage, and a γ correction circuit at a subsequent stage thereof. 2. The color television image quality improvement device according to item 2.