JP3600678B2 - Television signal processing method and television signal processing device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a signal processing method and a television signal processing device for converting data such as characters and graphics into a television signal (hereinafter, referred to as a television signal), and particularly to data such as fine chromatic characters and graphics. The present invention relates to a technology that is effective when applied to a technology for converting a TV signal into a television signal with little deterioration.
[0002]
[Prior art]
The television signal processing system used in Japan is called an NTSC (National Television System Committee) system, and includes a luminance signal (Y) indicating the brightness of black and white, and two color difference signals (Cr, Cb) indicating color signals. Is modulated by a color (chroma) signal (C). A composite video signal obtained by adding a synchronization signal (SYNC) to these signals is generally used. In other countries of the world, methods referred to as PAL and SECAM are also used, but the following discussion applies as well.
[0003]
The NTSC system can handle both black and white television signals and color signals. Normally, a color signal is represented by three signals of red (R), green (G), and blue (B). In the NTSC system, a luminance signal component having a wide band is used by skillfully utilizing human visual characteristics. (Approximately 4.2 MHz) and a narrow band chroma signal component (approximately 1.5 MHz) are multiplexed and are represented by one signal, which is a very efficient method. In particular, this method is suitable for processing a signal obtained by capturing a natural image using a television camera.
[0004]
FIG. 12 shows a color on a screen of a signal called a color bar and its luminance (Y) signal level (E) for reference of the following discussion. _Y : Amplitude).
[0005]
Further, while the amplitude of the luminance signal of the 100% white signal is 0.7 V, for example, the amplitude of the 100% red signal is about 0.21 V, and the amplitude of the 100% blue signal is about 0.08 V. ing.
[0006]
Further, FIG. 13 shows waveforms of a luminance (Y) signal, a color difference (Pr) signal, a color difference (Pb) signal, and a color (C) signal with respect to the color bar signal. The color (C) signal is a signal modulated by a 3.58 MHz subcarrier signal.
[0007]
In the NTSC system, the frequency band of the luminance signal is different from the frequency band of the chrominance signal, so that a black-and-white image of only the luminance signal can clearly see small parts. The part has a drawback that the color is blurred.
[0008]
On the other hand, color signals handled by personal computers (Personal Computers) are primary color signals of R, G, and B and the frequency band is not restricted, so that fine colored portions can be clearly displayed. it can.
[0009]
Further, in recent television receivers, in order to sharpen the outline of a video signal, an outline emphasis process is often performed at a portion where a signal changes sharply (boundary portion). FIG. 14 shows an example of the waveform of the contour enhancement processing. In order to extract the contour portion of the input signal (A), a first differential signal 1 (B) and a second differential signal 2 (C) are created, and these signals are inverted to create an edge emphasis signal (D). I do. The contour-emphasized signal (D) is added to the time-adjusted original signal to emphasize the contour of the original signal to obtain an output signal (E).
[0010]
As a result, at the boundary portion (edge portion) between black and white, black is further black, white is further white, and the outline is clearly visible. As a means for generating the contour emphasis signal, there is a method using a delay line other than the above-described differential processing.
[0011]
The NTSC system is described in, for example, "Television Image Information Engineering Handbook" published by Ohmsha on November 30, 1990, pp. 588-591.
[0012]
[Problems to be solved by the invention]
Recently, with the advancement of video processing, characters (graphics data) and the like are often combined (superimposed) with video signals. In the NTSC system, it is assumed that the frequency band of an input signal is limited to about 4.2 MHz. However, when adding text and graphics data to an image, such a frequency band is not limited. Often.
[0013]
Further, when such a frequency band is restricted, there is a disadvantage that a boundary portion is blurred and characters are difficult to read.
[0014]
It has been found that the following problems occur when converting characters, graphics data, and the like that are not restricted in such a frequency band into NTSC signals. In the following, a case of a character of a highly saturated color that is conspicuous will be described as an example. Although this problem occurs in all signals, it is not so noticeable in the case of an achromatic color, but has a large luminance change, and becomes a serious problem visually in a vertical or oblique line portion of a color with high saturation.
[0015]
FIGS. 15 and 16 schematically show a television screen and signal waveforms when the outline enhancement processing is not performed. FIG. 15 shows fine characters 1 (for example, "T") of vivid red (highly saturated red) on a white background, on a television screen 2. A and B are two horizontal scanning lines of the television. It shows a part. The (A) scanning line scans a wide horizontal line portion of the character 1 as T, and the (B) scanning line scans a narrow vertical line portion of the T character 1. .
[0016]
FIG. 17 and FIG. 18 show a television screen and a signal waveform diagram when the outline emphasis processing is performed. Considering the case where the width of the vertical line (B) of the character 1 of T shown in FIG. 17 is small, images with (A ′) and (B ′) are obtained when the outline emphasis processing is performed. That is, as shown in FIG. 18, the brightness of the vertical line (B ') having a large influence of the outline emphasis becomes darker than the center of the horizontal line (A') having no influence of the outline emphasis, and the vertical line becomes a horizontal line. It looks darker in comparison to red. In FIG. 17, a hatched portion is a dark red image 3.
[0017]
This phenomenon is not so noticeable in the case of an achromatic color without a color, but there is a problem that the image quality is degraded in the case of a character having a high color saturation. Also, when the background is a black background, the signal level is small and hard to see, so that it is not so noticeable.
[0018]
For this reason, until now, when combining data such as characters with a video signal, (1) display characters in black and white, (2) increase the width of character lines, and (3) luminance level around the (4) A method of restricting data, such as using a color having a small difference between the two, such as (4) bordering an outline portion with an achromatic color, is often used.
[0019]
An object of the present invention is to provide a television signal processing method and a television signal processing apparatus capable of clearly displaying a composite image such as colored characters and graphics without limiting input data. is there.
[0020]
The above and other objects and novel features of the present invention will become apparent from the description of the present specification and the accompanying drawings.
[0021]
[Means for Solving the Problems]
The outline of a typical invention among the inventions disclosed in the present application will be briefly described as follows.
[0022]
(1) A television signal processing method for converting a data signal such as characters and graphics into a television signal (NTSC signal) by performing an outline emphasis process, wherein a data signal at a boundary portion of chromatic data is detected. Based on the detection result, a change in the signal amplitude at the boundary of the data signal is controlled. Detecting that the width of the chromatic color data is equal to or smaller than a setting, and controlling a change in a luminance signal amplitude at a data boundary based on the detection result. The signal amplitude at the boundary of the data signal is subjected to an inverse correction process opposite to the outline emphasis process.
[0023]
(2) In the configuration of the means (1), a level change of a color difference signal of the data signal is detected, and a change in a luminance signal amplitude at a data boundary is controlled based on the detection result.
[0024]
(3) In the configuration of the means (1), a level change of a color signal of the data signal is detected, and a change in a luminance signal amplitude at a data boundary is controlled based on the detection result.
[0025]
(4) detecting a change in the level of a color signal or a color difference signal in a television signal (NTSC signal) in which a video signal includes a data signal on which contour enhancement processing such as characters and graphics has been performed, and performing the detection; The change of the luminance signal amplitude at the contour of the data is controlled based on the result.
[0026]
(5) A television signal processing apparatus for converting a data signal such as characters and graphics into a television signal (NTSC signal) by performing an outline emphasis process, and detects a data signal at a boundary between chromatic data. Means for controlling a change in signal amplitude at a boundary of the data signal based on the detection means. Specifically, the television signal processing device includes a video signal generation unit, a delay circuit, an addition circuit, a luminance / color difference conversion circuit, a circuit sequentially connected to an NTSC modulation circuit, a data signal generation unit, a boundary determination circuit. , An inverse correction signal generation circuit, and a circuit sequentially connected thereto. The output signal of the inverse correction signal generation circuit is input to the addition circuit, and the television signal is output from the NTSC modulation circuit. I have.
[0027]
The boundary portion determination circuit is configured to detect a data signal at a boundary portion of chromatic data and output a signal of a portion where a change in a color difference signal level is equal to or greater than a set value to the inverse correction signal generation circuit. .
[0028]
The inverse correction signal generation circuit receives a data signal (A) and outputs the output signal (B), and receives and outputs an output signal (B) of the first delay circuit. A second delay circuit for [output signal (C)], and a first for inputting and outputting the data signal (A) and the output signal (B) of the first delay circuit [output signal (D)]. An operation (subtraction) circuit, and a second operation (subtraction) circuit that receives and outputs [output signal (E)] the output signals (B) and (C) of the first delay circuit and the second delay circuit. And the output signals (D), (E) and (B) of the first operation (subtraction) circuit, the second operation (subtraction) circuit, and the first delay circuit are input and output [output signal (F)].
[0029]
(6) In the configuration of the means (5), the reverse correction signal generation circuit receives a data signal (A) and outputs the output signal [output signal (B)], and the first delay circuit. A second delay circuit for receiving an output signal (B) of the circuit and outputting the output signal (C), and receiving the data signal (A) and the output signal (B) of the first delay circuit A first operation (subtraction) circuit for outputting [output signal (D)], and output signals (B) and (C) of the first delay circuit and the second delay circuit are input and output [output signal (D). E)) a second operation (subtraction) circuit, a first limiter circuit that receives and outputs an output signal (G) of the output signal (D) of the first operation (subtraction) circuit, A second limiter circuit for inputting and outputting an output signal (H) of the output signal (E) of the second operation (subtraction) circuit; An adder circuit for receiving and outputting the output signals (G), (H), and (B) of the first limiter circuit, the second limiter circuit, and the first delay circuit (output signal (F)); Is provided.
[0030]
(7) A television signal processing device for performing a contour enhancement process on a data signal such as characters and graphics to convert the data signal into a television signal (NTSC signal), comprising a video signal generator, a luminance / color difference conversion circuit, and a delay circuit. , An addition circuit, an NTSC modulation circuit, and a circuit connected to a data signal generation unit, a luminance / color difference conversion circuit, a boundary part judgment circuit, and an inverse correction signal generation circuit. An output signal of the correction signal generation circuit is input to the addition circuit, and a television signal is output from the NTSC modulation circuit.
[0031]
(8) A television signal processing device for performing a contour emphasis process on a data signal such as characters and graphics to convert it into a television signal (NTSC signal), comprising a video signal generator for outputting an NTSC signal, a delay circuit, The NTSC circuit includes a circuit sequentially connected to the adder circuit, and a circuit sequentially connected to a data signal generator, a luminance / color difference converter, a boundary determination circuit, an inverse correction signal generator, and an NTSC modulation circuit. The output signal of the modulation circuit is input to the addition circuit, and the addition circuit outputs a television signal.
[0032]
(9) A television signal processing device for controlling a television signal in which a video signal includes a data signal on which contour enhancement processing of characters, graphics, and the like has been performed, and a video signal generation unit that outputs an NTSC signal , A delay circuit, and an adder circuit, and each circuit sequentially connected to an NTSC demodulation circuit, a boundary determination circuit, an inverse correction signal generation circuit, and an NTSC modulation circuit. The output signal of the video signal generator is used as an input signal, the output signal of the NTSC modulation circuit is input to the addition circuit, and the addition circuit outputs a television signal.
[0033]
According to the means of (1), when it is detected that the width of the chromatic data is equal to or smaller than the set value (set value), the signal amplitude at the boundary of the data signal is opposite to the contour emphasis processing. Since the reverse correction processing is performed, the boundary on which the reverse correction processing has been performed is not darkened, and the data image is clearly displayed.
[0034]
In other words, when converting chromatic fine characters or graphics data into an NTSC television signal, by performing the inverse processing of the outline emphasis processing on the vertical lines (oblique lines), the vertical lines of the fine data can be converted. It is possible to prevent the problem that the color of the (hatched) part and the part of the horizontal line look unnatural. Further, by controlling the magnitude of the inverse processing of the outline emphasis processing based on the horizontal width of the data, it is possible to prevent the excessive correction processing from being performed on wide data.
[0035]
According to the means (2), the level change of the color difference signal of the data signal is detected, and the change of the luminance signal amplitude at the data boundary is controlled based on the detection result. When the amplitude of the luminance signal is larger than the setting, inverse correction processing opposite to the outline emphasis processing can be performed so that the boundary of the data image is not darkened, and the data image can be displayed clearly.
[0036]
According to the means of (3), the level change of the color signal of the data signal is detected, and the change of the luminance signal amplitude at the data boundary is controlled based on the detection result. When the amplitude of the luminance signal is larger than the setting, inverse correction processing opposite to the outline emphasis processing can be performed so that the boundary of the data image is not darkened, and the data image can be displayed clearly.
[0037]
According to the means (4), the level of a color signal or a color difference signal in a television signal (NTSC signal) in which a video signal includes a data signal on which contour enhancement processing such as characters and graphics has been performed is included. Since the height is detected and the change in the luminance signal amplitude at the data outline is controlled based on the detection result, when the luminance signal amplitude at the boundary of the data is larger than the setting, the opposite of the outline emphasis processing is performed. By performing the inverse correction process, the boundary of the data image can be prevented from being darkened, and the data image can be displayed clearly.
[0038]
According to the means of the above (5), in a television signal processing apparatus for converting a data signal such as a character or graphics into a television signal (NTSC signal) by performing an outline emphasis process, a boundary portion of chromatic data is provided. Since the data signal is detected and the change in the signal amplitude at the boundary of the data signal is controlled based on the detection means, when the luminance signal amplitude at the data boundary is larger than the setting, the outline emphasis processing is performed. By performing the opposite reverse correction processing, the boundary of the data image can be prevented from being darkened, and the data image can be displayed clearly.
[0039]
Specifically, the boundary determination circuit detects a data signal at the boundary of the chromatic data, and outputs a signal of a portion where the change in the color difference signal level is equal to or greater than a set value to the inverse correction signal generation circuit. The inverse correction signal generating circuit subtracts the data signal (A) from the output signal (B) of the delay circuit by an operation (subtraction) circuit and outputs an output signal (D). Further, the output signal (B) and the output signal (C) of the delay circuit are subtracted by an operation (subtraction) circuit to output an output signal (E). Then, the output signals (B), (D), and (E) are input to an adding circuit and added, and the output signal (F) subjected to the inverse correction processing is added to the adding circuit to obtain a television signal. As a result, it is possible to prevent the boundary of the data image from deteriorating.
[0040]
According to the means (6), similarly to the means (5), the data signal at the boundary of the chromatic data is detected, and the change in the signal amplitude at the boundary of the data signal is detected based on the detection means. When the luminance signal amplitude at the boundary of the data is larger than the set value, the inverse correction processing opposite to the outline enhancement processing can be performed so that the boundary of the data image is not darkened. Images can be displayed clearly.
[0041]
Specifically, the boundary determination circuit detects a data signal at the boundary of the chromatic data, and outputs a signal of a portion where the change in the color difference signal level is equal to or greater than a set value to the inverse correction signal generation circuit. The inverse correction signal generating circuit subtracts the data signal (A) from the output signal (B) of the delay circuit by an operation (subtraction) circuit and outputs an output signal (D). Further, the output signal (B) and the output signal (C) of the delay circuit are subtracted by an operation (subtraction) circuit to output an output signal (E). Further, the output signals (D) and (E) are output as positive-polarity only output signals (G) and (H) through separate limiter circuits. Then, the output signals (B), (G), and (H) are input to an addition circuit, added, and the output signal (I) subjected to the inverse correction processing is added to the addition circuit to obtain a television signal. As a result, it is possible to prevent the boundary of the data image from deteriorating.
[0042]
According to the means of (7), each circuit sequentially connected to the video signal generation unit, the luminance / color difference conversion circuit, the delay circuit, the addition circuit, the NTSC modulation circuit, the data signal generation unit, the luminance / color difference conversion circuit, A television having a boundary portion determination circuit and respective circuits connected to an inverse correction signal generation circuit, wherein an output signal of the inverse correction signal generation circuit is input to the addition circuit, and a television signal subjected to inverse correction processing from the NTSC modulation circuit; Since the signal is output, it is possible to prevent deterioration of the boundary of the data image.
[0043]
According to the means of the above (8), each circuit sequentially connected to the video signal generator, the delay circuit, and the addition circuit for outputting the NTSC signal, the data signal generator, the luminance / color difference conversion circuit, the boundary determination circuit, An inverse correction signal generating circuit, and circuits sequentially connected to the NTSC modulation circuit, wherein an output signal of the NTSC modulation circuit is input to the addition circuit, and a television signal subjected to reverse correction processing is output from the addition circuit. Therefore, it is possible to prevent the boundary portion of the data image from deteriorating.
[0044]
According to the means of the above (9), each of the circuits sequentially connected to the video signal generating section, the delay circuit, and the adding circuit for outputting the NTSC signal, the NTSC demodulating circuit, the boundary determining circuit, the inverse correction signal generating circuit, the NTSC signal The NTSC demodulation circuit receives the output signal of the video signal generation unit as an input signal, and inputs the output signal of the NTSC modulation circuit to the addition circuit; Since the television signal subjected to the inverse correction processing is output from, the deterioration of the boundary portion of the data image can be prevented.
[0045]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In all the drawings for describing the embodiments of the present invention, components having the same functions are denoted by the same reference numerals, and their repeated description will be omitted.
[0046]
(Embodiment 1)
1 to 4 are diagrams relating to a television signal processing method and a television signal processing device according to an embodiment (Embodiment 1) of the present invention, and FIG. 1 shows image processing constituting the television signal processing device. FIG. 2 is a block diagram illustrating a circuit, FIG. 2 is a circuit diagram illustrating an inverse correction signal generation circuit included in the image processing circuit, FIG. 3 is a timing chart illustrating signal waveforms of the inverse correction signal generation circuit, and FIG. 4 is a schematic diagram illustrating a television screen. It is.
[0047]
In the first embodiment, a case will be described in which a fine image data portion such as a colored character can be recognized in advance. Further, a case will be described in which an RGB signal of a data signal generation unit such as a character or graphics data is added (or synthesized) to an RGB signal of a video signal generation unit such as a video camera.
[0048]
The television signal processing device of the first embodiment has an image processing circuit as shown in FIG. The image processing circuit includes a video signal generator 11, a delay circuit 12, an adder 13, a luminance / color difference converter 17, an NTSC modulator 18, a data signal generator 14, and a boundary determination circuit 15. , A circuit sequentially connected to the inverse correction signal generation circuit 16, and the signal of the inverse correction signal generation circuit 16 is sent to the addition circuit 13, and the NTSC modulation circuit 18 sharpens the boundary of data. Is output to the output terminal 19.
[0049]
In this image processing circuit, when converting a data signal such as characters and graphics into a television signal, a boundary portion of a chromatic data signal is determined, an inverse correction signal is generated and added to a video signal of a video camera or the like. This is one of the features of the present invention.
[0050]
That is, the signal of the data signal generator 14 is input to the boundary determination circuit 15 to determine whether or not the signal includes a chromatic boundary. The boundary portion determination circuit 15 creates a color difference signal (Pr, Pb), for example, as in the NTSC system, and outputs a signal of a portion where the change in the color difference signal level exceeds a set value to the inverse correction signal generation circuit 16. It has a configuration.
[0051]
The data signal generation unit 14 controls the magnitude of the inverse processing of the outline emphasis processing according to the horizontal width of the data, so that excessive correction processing is not performed on wide data.
[0052]
In other words, in the case of chromatic color data such as characters and graphics, inverse processing of the outline emphasis processing is performed for data having narrow vertical and diagonal lines. The set value serving as a reference for this determination is, for example, 100 ns to 300 ns.
[0053]
The data signal determined by the boundary determination circuit 15 is sent to the inverse correction signal generation circuit 16.
[0054]
The inverse correction signal generating circuit 16 has a configuration as shown in FIG. 2, and has a circuit configuration using a delay circuit. That is, the inverse correction signal generation circuit includes the delay circuits 161 and 162 (the first delay circuit 161 and the second delay circuit 162) and the operation (subtraction) circuits 163 and 164 (the first operation (subtraction) circuit 163, 2 operation (subtraction) circuit 164) and an addition circuit 165.
[0055]
Hereinafter, a description will be given using a simple example of a red signal on a white background.
[0056]
The output signal (A) of the data signal generator 14 is determined by the boundary determination circuit 15, and the delay circuit 161 (first delay circuit 161) and the operation circuit 163 (first operation (subtraction) of the inverse correction signal generation circuit 16 are determined. ) Is input to the circuit 163). The output signal (B) of the delay circuit 161 is input to the operation circuits 163 and 164 and the addition circuit 165. The output signal (C) of the delay circuit 162 (second delay circuit 162) is input to the arithmetic circuit 164 (second arithmetic (subtraction) circuit 164). The output signals (D) and (E) of the operation circuits 163 and 164 are also input to the addition circuit 165. The output signal (F) of the adding circuit 165 is input to the adding circuit 13.
[0057]
FIG. 3 is a timing chart showing signal waveform examples of output signals (A) to (F) output from each circuit of FIG.
[0058]
As the input waveform in FIG. 3, it is assumed that there is a red thick line (X) and a thin line (Y) on a white background, and only the processing of the R signal is shown. The output signal (A) of the data signal generator 14 is delayed by the delay circuits 161 and 162 to become output signals (B) and (C), respectively. The delay time of these delay circuits differs depending on the amount to be added, but may be set to a value of about several hundred ns.
[0059]
The output signals (B) and (C) are detected by the arithmetic circuits 163 and 164 at the rising and falling edges of the boundary, and output signals (D) and (E) are created.
[0060]
When the output signals (D) and (E) and the output signal (B) obtained by delaying the input signal by one stage of the delay circuit are added by an adder 165, an output signal (F) whose boundary portion is inversely corrected is obtained. Can be
[0061]
Note that these processes can also be realized by a differentiating circuit and a delay circuit. This embodiment will be described with reference to FIGS.
[0062]
FIG. 5 is a diagram showing another example of the inverse correction signal generating circuit 16. This circuit includes a delay circuit 161, differentiating circuits 168 and 169 (a first differentiating circuit 168 and a second differentiating circuit 169), and an adder. It comprises a circuit 165. FIG. 6 is a timing chart showing signal waveforms at various parts of these circuits. As an input waveform, an example of the above-described red signal on a white background is shown.
[0063]
The output signal (A) of the data signal generation unit 14 is determined by the boundary determination circuit 15 and input to the delay circuit 161 and the differentiation circuit 168 of the inverse correction signal generation circuit 16. The output signal (B) of the delay circuit 161 is input to the addition circuit 165. The output signal (D) of the differentiating circuit 168 is further input to the differentiating circuit 169. The output signal (E) of the differentiating circuit 169 is input to the adding circuit 165.
[0064]
When the output signal (B) of the delay circuit 161 and the output signal (E) of the differentiating circuit 169 are added by the adding circuit 165, an output signal (F) in which the boundary is inversely corrected is obtained.
[0065]
Therefore, the output signal (F) that has been inversely corrected by the inverse correction signal generation circuit 16 is input to the addition circuit (or combination) 13 shown in FIG. 1 and the signal of the video signal generation unit 11 is delayed by the delay circuit 12. (The same delay amount as the delay circuit 161).
[0066]
After that, it is converted into an NTSC signal by a luminance / color difference conversion circuit 17 and an NTSC modulation circuit 18 and output to an output terminal 19.
[0067]
As a result, it is possible to prevent image quality deterioration of the image data portion such as a chromatic color boundary portion and a fine vertical line due to the outline enhancement process of the television receiver.
[0068]
For example, FIG. 4 shows the character 1 of T displayed on the television screen 2, and the portion of the character T extending in the horizontal direction is a thick red line (X) on a white background. Is a portion where a thin red line (Y) is formed on a white background, and the boundary portion of the image is sharp and clear.
[0069]
In the above description, the red (R) data signal is described on a white background, but the same processing is performed for green (G) and blue (B).
[0070]
In the television signal processing method and the television signal processing apparatus according to the first embodiment, when a data signal such as fine chromatic characters or graphics is converted into an NTSC television signal, the inverse correction signal generation circuit 16 generates the vertical signal. By performing the inverse processing of the outline emphasis processing on the line (diagonal line) part, it is possible to prevent the problem that the color of the vertical line (diagonal line) part and the horizontal line part of the fine data looks unnatural.
[0071]
In the television signal processing method and the television signal processing apparatus according to the first embodiment, when converting a data signal such as chromatic fine characters or graphics into an NTSC television signal, the boundary part determination circuit 15 performs data conversion. By controlling the magnitude of the inverse processing of the outline emphasis processing based on the horizontal width, it is possible to prevent excessive correction processing for wide data.
[0072]
(Embodiment 2)
FIG. 7 is a circuit diagram showing an inverse correction signal generation circuit constituting a television signal processing device according to another embodiment (Embodiment 2) of the present invention, and FIG. 6 is a timing chart illustrating a signal waveform of a correction signal generation circuit.
[0073]
In the second embodiment, as a correction signal, only a portion that changes from a signal having a large luminance level such as white, which is particularly noticeable, to a signal having a small luminance level such as red is added to the original signal, and fine correction is performed. This prevents the problem that the colors of vertical lines (diagonal lines) and horizontal lines of unusual data look unnatural.
[0074]
In order to perform such processing, the television signal processing apparatus according to the second embodiment includes an inverse correction signal generation circuit 16 using a delay circuit, as shown in FIG.
[0075]
The inverse correction signal generation circuit 16 includes delay circuits 161, 162 (first delay circuit 161, second delay circuit 162), operation (subtraction) circuits 163, 164 (first operation (subtraction) circuit 163, 2 (a subtraction circuit 164), limiter circuits 166 and 167 (a first limiter circuit 166 and a second limiter circuit 167) and an adder circuit 165. This inverse correction signal generation circuit 16 has a structure in which limiter circuits 166 and 167 are incorporated between the delay circuits 161 and 162 and the addition circuit 165 in the inverse correction signal generation circuit 16 of the first embodiment shown in FIG. I have.
[0076]
FIG. 8 is a timing chart showing an example of signal waveforms of output signals (A) to (I) of each section of the inverse correction signal generation circuit 16.
[0077]
As the input waveform in the inverse correction signal generation circuit 16 of the television signal processing device of the second embodiment, a thick red line (X) and a thin line (Y) on a white background, as in the case of the first embodiment. Assuming that there is, only the processing of the R signal is shown.
[0078]
The output signal (A) of the data signal generator 14 is delayed by the delay circuits 161 and 162 to become output signals (B) and (C), respectively. The delay time of these delay circuits differs depending on the amount to be added, but may be set to a value of about several hundred ns.
[0079]
The output signals (B) and (C) are detected by the arithmetic circuits 163 and 164 to detect the rising and falling portions of the boundary, and generate signals such as the output signals (D) and (E).
[0080]
Further, the output signals (D) and (E) are passed through limiter circuits 166 and 167 to generate output signals (G) and (H) of only positive polarity, and these output signals (G) and (H) and the input signals are input. When the output signal (B) obtained by delaying the signal by one stage of the delay circuit is added by the adding circuit 165, the output signal (I) whose boundary portion is inversely corrected is obtained.
[0081]
This output signal (I) is input to the adding circuit (or combining) 13 shown in FIG. 1, and the signal of the video signal generating unit 11 is added to the signal delayed by the delay circuit 12 (the same delay amount as the delay circuit 161). .
[0082]
Thus, it is possible to prevent a problem that the color of the vertical line (oblique line) portion and the horizontal line portion of the fine data looks unnatural.
[0083]
Note that these processes can be realized by a differentiating circuit instead of a delay circuit.
[0084]
(Embodiment 3)
FIG. 9 is a block diagram showing an image processing circuit constituting a television signal processing device according to another embodiment (Embodiment 3) of the present invention.
[0085]
The television signal processing method according to the first embodiment is an image processing method for RGB signals. In the third embodiment, the present invention is applied to a television signal processing method and a television signal processing device using a luminance signal and a color difference signal. An example of application will be described.
[0086]
The television signal processing apparatus according to the third embodiment does not process each of the RGB signals, but processes the data signal by the inverse correction signal generation circuit after converting the data into a luminance signal and a color difference signal.
[0087]
Accordingly, as shown in FIG. 9, the inverse correction signal generation circuit 16 of the third embodiment does not need to arrange the luminance / color difference conversion circuit next to the addition circuit in the inverse correction signal generation circuit 16 of the first embodiment. A luminance / color difference conversion circuit 41 is disposed between the video signal generation unit 11 and the delay circuit 12 and a luminance / color difference conversion circuit 42 is disposed between the data signal generation unit 14 and the boundary determination circuit 15. Has become.
[0088]
Hereinafter, as in the case of the first embodiment, a case will be described in which the RGB signals of the data signal generation unit 12 such as characters and graphics data are added (or synthesized) to the RGB signals of the video signal generation unit 11.
[0089]
In the third embodiment, the output signal of the video signal generator 11 is input to the luminance / color difference conversion circuit 41. The output signal of the data signal generator 14 is input to the luminance / color difference conversion circuit 42.
[0090]
The luminance / color difference conversion circuits 41 and 42 generate a luminance signal (Y) of the NTSC system and two color difference signals (Cr, Cb) from the RGB signals.
[0091]
The output of the luminance / color difference conversion circuit 42 is input to the boundary determination circuit 15 to determine whether the signal is a chromatic signal. For example, a signal in a portion where the color difference signal level is equal to or higher than the set value may be determined as a chromatic signal and output to the inverse correction generation signal circuit 16.
[0092]
The inverse correction generation signal circuit 16 performs the same processing on the luminance signal as performed on the R signal in the case of the first embodiment. Note that the color difference signal also needs to be delayed by the same delay amount as the delay circuit 161 for time adjustment.
[0093]
The inversely corrected luminance signal and chrominance signal are input to an addition circuit 13 and added to a signal obtained by delaying the luminance signal and chrominance signal of the video signal generation unit 11 by the delay circuit 12 (the same delay amount as the delay circuit 161). I do.
[0094]
Then, the luminance signal and the color difference signal are modulated and synthesized into an NTSC signal by the NTSC modulation circuit 17 and output to the output terminal 19.
[0095]
As a result, it is possible to prevent image quality deterioration of the image data portion such as a chromatic color boundary portion and a fine vertical line due to the outline enhancement process of the television receiver.
[0096]
(Embodiment 4)
FIG. 10 is a block diagram showing an image processing circuit in a television signal processing device according to another embodiment (Embodiment 4) of the present invention.
[0097]
The fourth embodiment is an example showing a method for performing a signal reverse correction process on an NTSC signal. The image processing circuit according to the fourth embodiment is different from the image processing circuit according to the third embodiment in that the NTSC modulation circuit 18 is not disposed downstream of the addition circuit 13 and is provided between the luminance / color difference conversion circuit 41 and the delay circuit 12. An NTSC modulation circuit 51 is arranged, an NTSC modulation circuit 52 is arranged at a stage subsequent to the inverse correction signal generation circuit 16, and an output signal of the NTSC modulation circuit 52 is input to the addition circuit 13.
[0098]
In the fourth embodiment, the RGB signal of the video signal generation unit 11 is converted into an NTSC signal by the luminance / color difference conversion circuit 41 and the NTSC modulation circuit 51. If the output signal of the video signal generator 11 is an NTSC signal, the dotted frame portion becomes the video signal generator 11, and the luminance / color difference conversion circuit 41 and the NTSC modulation circuit 51 are omitted.
[0099]
In the fourth embodiment, first, the RGB signals of the data signal generation unit 14 are input to the luminance / color difference conversion circuit 42, and the output signal is input to the boundary determination circuit 15 to determine whether the signal is a chromatic color signal. .
[0100]
The signal portion determined to be a chromatic signal is processed by the inverse correction signal generation circuit 16 as in the first and second embodiments.
[0101]
After the signal inversely corrected by the inverse correction signal generation circuit 16 is converted into an NTSC signal by the NTSC modulation circuit 52, the NTSC output signal of the NTSC modulation circuit 51 (or the NTSC output signal of the video signal generation unit 11) is delayed by the delay circuit 12. The obtained signal is added to the added signal by the adding circuit 13 and output.
[0102]
It is also possible to similarly determine and process whether a color (chroma) signal modulated by a subcarrier signal instead of the color difference signal is a chromatic signal.
[0103]
As a result, it is possible to prevent image quality deterioration of the image data portion such as a chromatic color boundary portion and a fine vertical line due to the outline enhancement process of the television receiver.
[0104]
(Embodiment 5)
FIG. 11 is a block diagram showing an image processing circuit in a television signal processing device according to another embodiment (Embodiment 5) of the present invention.
[0105]
The television signal processing apparatus according to the fifth embodiment is an inverse signal processing method for a signal in the case where a problematic chromatic fine image data portion cannot be recognized in advance.
[0106]
That is, this is a reverse correction processing method when the NTSC signal output from the video signal generation unit 11 includes a data signal such as characters and graphics. In this case, it is necessary to determine in which part of the image signal the problem of image quality degradation occurs.
[0107]
One method of this determination is to perform differentiation on the color difference signal in the horizontal direction, and determine that there is a vertical line when the amplitude after differentiation becomes a certain value or more.
[0108]
Alternatively, the signal may be delayed by a delay line (delay circuit), and when the amplitude of the difference from the original signal becomes a certain value or more, it may be determined that there is a vertical line. These determinations are made by the boundary portion determination circuit 15.
[0109]
In the fifth embodiment, a case where the target input signal is a television signal that has already been subjected to NTSC modulation will be described.
[0110]
The image processing circuit is connected to the video signal generation unit 11, the delay circuit 12, and the addition circuit 13, and the video signal generation unit 11, the NTSC demodulation circuit 61, the boundary determination circuit 15, the inverse correction signal generation circuit 16, the NTSC modulation. The circuit 52 and the addition circuit 13 are connected and arranged. Video signal generator 11 outputs an NTSC signal.
[0111]
The signal of the video signal generator 11 is input to the NTSC demodulation circuit 61, and detects the color difference signal C. This color difference signal is input to the boundary determination circuit 15 to determine whether the signal is a chromatic signal.
[0112]
The signal portion determined to be a chromatic signal is subjected to the same processing by the inverse correction signal generation circuit 16 as in the first embodiment. After the inversely corrected signal is converted into an NTSC signal by the NTSC modulation circuit 52, the signal of the video signal generation unit 11 is added to the signal delayed by the delay circuit 12 by the addition circuit 13 and output.
[0113]
It is also possible to similarly determine and process whether a color (chroma) signal modulated by a subcarrier signal instead of the color difference signal is a chromatic signal.
[0114]
According to the above-described processing, it is possible to prevent image quality deterioration of an image data portion such as a chromatic boundary portion and a fine vertical line due to a contour enhancement process of the television receiver.
[0115]
Although the invention made by the inventor has been specifically described based on the embodiment, the present invention is not limited to the above embodiment, and various changes can be made without departing from the gist of the invention. Nor.
[0116]
In the above description, the case where the invention made by the present inventor is mainly applied to a television signal processing system using NTSC signals, which is a background of application, has been described. However, the present invention is not limited to this. The present invention can be similarly applied to a signal processing method for separating and processing a luminance signal and a modulated chrominance signal called a terminal correspondence signal. Further, the present invention can be similarly applied to a system called a PAL system or a SECAM system other than the NTSC system.
[0117]
The present invention is applicable to at least a television signal processing technique for synthesizing a data signal.
[0118]
【The invention's effect】
The effects obtained by the typical inventions among the inventions disclosed in the present application will be briefly described as follows.
[0119]
(1) According to the television signal processing technique of the present invention, by controlling (suppressing) the amplitude of the contour portion of the chromatic fine image data portion, the chromatic color of the television receiver is enhanced by the contour enhancement process. It is possible to prevent visual image quality deterioration due to a color change occurring at a boundary portion, a fine vertical line, or the like.
[0120]
(2) Even when small image data portions such as colored characters can be recognized in advance and when they cannot be recognized in advance, the amplitude of the outline portion of the chromatic fine image data portion should be controlled (suppressed). Accordingly, it is possible to prevent visual image quality deterioration due to a color change occurring at a chromatic color boundary portion, a fine vertical line, or the like due to the outline enhancement processing of the television receiver.
[0121]
(3) Even in a television signal processing and a television signal processing device using a luminance signal and a color difference signal, it is possible to prevent visual image quality degradation of chromatic fine image data.
[0122]
(4) Also in a television signal processing method and a television signal processing apparatus for converting an RGB signal into an NTSC signal by a luminance / color difference conversion circuit and an NTSC modulation circuit, visual quality deterioration of chromatic fine image data is prevented. be able to. In this case, the color (chroma) signal modulated by the subcarrier signal instead of the color difference signal is similarly determined and processed as to whether or not the signal is a chromatic signal. Image quality degradation can be prevented.
[0123]
(5) According to the television signal processing method and the television signal processing device of the present invention, since excessive correction processing is not performed on wide data, a sharp image with enhanced contours can be obtained.
[0124]
(6) According to the television signal processing method and the television signal processing device of the present invention, when combining data such as characters and graphics with a video, the characters are displayed in black and white, and the width of the character lines is increased. There is no need to restrict data, such as using a color with a small difference in luminance level from the surroundings. Therefore, it is possible to clearly display a synthesized image such as colored characters and graphics without limiting input data.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an image processing circuit in a television signal processing device according to an embodiment (Embodiment 1) of the present invention.
FIG. 2 is a circuit diagram illustrating an inverse correction signal generation circuit included in the image processing circuit according to the first embodiment.
FIG. 3 is a timing chart showing signal waveforms of the inverse correction signal generation circuit according to the first embodiment.
FIG. 4 is a schematic diagram showing a television screen by the television signal processing device of the first embodiment.
FIG. 5 is a circuit diagram showing another inverse correction signal generation circuit constituting the image processing circuit according to the first embodiment.
FIG. 6 is a timing chart showing signal waveforms of another inverse correction signal generation circuit according to the first embodiment.
FIG. 7 is a circuit diagram showing an inverse correction signal generation circuit in a television signal processing device according to another embodiment (Embodiment 2) of the present invention.
FIG. 8 is a timing chart showing signal waveforms of an inverse correction signal generation circuit in the television signal processing device according to the second embodiment.
FIG. 9 is a block diagram showing an image processing circuit in a television signal processing device according to another embodiment (Embodiment 3) of the present invention.
FIG. 10 is a block diagram showing an image processing circuit in a television signal processing device according to another embodiment (Embodiment 4) of the present invention.
FIG. 11 is a block diagram illustrating an image processing circuit in a television signal processing device according to another embodiment (Embodiment 5) of the present invention.
FIG. 12 is a diagram showing a color bar screen and a luminance signal level.
FIG. 13 is a waveform diagram showing a waveform of a color bar signal.
FIG. 14 is a timing chart showing a signal waveform for performing contour enhancement in a conventional television signal processing method.
FIG. 15 is a schematic diagram showing a television screen on which contour enhancement is not performed.
FIG. 16 is a signal waveform diagram when contour enhancement is not performed.
FIG. 17 is a schematic diagram showing a television screen on which contour enhancement is performed in a conventional television signal processing method.
FIG. 18 is a signal waveform diagram when contour enhancement is performed.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Character, 2 ... Television screen, 3 ... Dark red image, 11 # Video signal generation part, 12 ... Delay circuit, 13 ... Addition circuit, 14 ... Data signal generation part, 15 ... Boundary part judgment circuit, 16 ... Inverse correction signal generation circuit, 17, 41, 42 ... luminance / color difference conversion circuit, 18, 51, 52 ... NTSC modulation circuit, 19 ... output terminal, 61 ... NTSC demodulation circuit, 161 ... delay circuit (first delay circuit) , 162... Delay circuit (second delay circuit), 163... Operation (subtraction) circuit (first operation (subtraction) circuit), 164... Operation (subtraction) circuit (second operation (subtraction) circuit), 165 ... addition circuit, 166 ... limiter circuit (first limiter circuit), 167 ... limiter circuit (second limiter circuit), 168 ... differentiation circuit (first differentiation circuit), 169 ... differentiation circuit (second differentiation circuit) ).

Claims (2)

The RGB signal of the video signal generation unit is combined with the data signal of characters and graphics composed of the RGB signal of the data signal generation unit , and the boundary between the chromatic data including the color difference signal and the color signal in the data signal. detecting a horizontal width of the data, a television signal processing method characterized by controlling the change in the signal amplitude of the boundary portion of the data signal based on the result of that,
A delay circuit, an addition circuit, a luminance / color difference conversion circuit, and an NTSC modulation circuit are sequentially connected to the video signal generation section, and a boundary determination circuit, an inverse correction signal generation circuit, and a sequential circuit are connected to the data signal generation section. Is connected, and the boundary portion determination circuit has a first delay circuit, a second delay circuit, a first subtraction circuit, a second subtraction circuit, and an addition circuit. Using an image processing circuit configured to input an output signal to the addition circuit connected to the video signal generation unit,
An output signal (A) of the data signal generation unit is determined by a boundary portion determination circuit, and is input to a first delay circuit and a first subtraction circuit of an inverse correction signal generation circuit, and an output signal of the first delay circuit is output. (B) is input to the first subtraction circuit, the second subtraction circuit, and the second delay circuit, and the output signal (C) of the second delay circuit is input to the second subtraction circuit. An output signal (D) of the first subtraction circuit, an output signal (E) of the second subtraction circuit, and an output signal (B) of the first delay circuit are input to an addition circuit, and a boundary of a data signal is input. Obtaining an output signal (F) whose part is inversely corrected, and inputting the output signal (F) to the addition circuit connected to the video signal generation unit;
Thereafter, the luminance / color difference conversion circuit and the NTSC modulation circuit convert the signal into an NTSC signal and output the signal.
The set value of the presence / absence of the reverse correction at the boundary portion of the data signal is such that the horizontal width of the data is 100 ns to 300 ns, and when the width is larger than this set value, the reverse corrected output signal (F) is obtained. A television signal processing method characterized by being configured as described above. 2. The television signal processing method according to claim 1, wherein a delay time of each of the first and second delay circuits is about several hundred ns .

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