KR960007647B1 - Character generation circuit for secam image processing apparatus - Google Patents

Abstract

The device for generating characteristics in an SECAM type video processing system for displaying video signals using a cathode ray tube includes: a switching signal output circuit 10 for outputting a switching signal according to the line on which an input composite video signal CS is scanned; a white frequency output circuit 20 for outputting a white frequency of the line switched according to the switching signal outputted from the switching signal output circuit 10 and being scanned; and a character generator circuit 30 for generating a predetermined character signal in order to display the character signal in a predetermined interval of the cathode ray tube with the white frequency outputted from the white frequency output circuit 20.

Description

Character Generator in SECAM Image Processing System

1 is a block diagram of a character generator in a SECAM image processing system according to the present invention.

2 is an operational waveform diagram of a main part of the character generator shown in FIG.

* Explanation of symbols for main parts of the drawings

10: switching signal output circuit 11: separation unit

12 delay unit 13 detection unit

14 low pass filter 15 comparison unit

20: white frequency output circuit 21: the first oscillator

22: second oscillation unit 23: switch

30: character generator circuit 31: character generator

32: character frequency setting unit 33: switch

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing system of a sequential color and memory (SEAM) type, and more particularly to a character generating device for adding a desired character to an image displayed on a cathode ray tube in a SECAM type image processing system. .

The SECAM broadcasting method is a television broadcasting method in which two color difference signals are alternately frequency-modulated for each scan line, and then the modulated color difference signals are superimposed on the luminance signal for transmission. Since the SECAM method uses FM modulation, it has a strong characteristic against amplitude distortion and phase distortion occurring in the channel. As described above, the SECAM broadcasting method uses FM modulation as the color signal differently from the PAL or NTSC method so that all colors have their own frequencies. Therefore, in order to display white and black, a signal having a unique frequency is added to the light and dark of the luminance signal. Therefore, in order to display white and black, it is composed of a signal obtained by adding a unique frequency to the light and dark of the luminance signal. In addition, the SECAM method has various color subcarriers having different frequency bands between two consecutive scanning lines, which are divided into D'R and D'B. The white frequencies of D'R and D'B are fixed at 4.406MHz and 4.25MHz, respectively. In this case, the color carrier is pre-emphasis to emphasize the high frequency components in order to improve the frequency characteristics before FM modulation, and the bell filter (Bell Filter) to vary the degree of amplification according to the frequency after FM modulation ), The waveform of the color carrier is complicated. However, since the white frequencies of 4.406 MHz and 4.25 MHz serve as reference frequencies in the pre-emphasis of the color carrier and the filtering of the bell filter, there is no change in frequency.

In the SECAM method, since the color carrier is frequency-modulated, when a character signal is generated and inserted into a part of the video signal like the NTSC or PAL method, the color carrier is lost when the color information due to frequency is lost. Is generated and the color is drawn behind the characters displayed on the cathode ray tube, so that the user cannot distinguish between the characters and the images. Therefore, the SECAM image processing system does not have a character generation function for displaying a desired character while the user watches a predetermined image using a television or a video cassette recorder.

SUMMARY OF THE INVENTION An object of the present invention is to display a character desired by a user on a cathode ray tube by inserting a text signal into a composite video signal using a white frequency signal having a constant frequency in order to compensate for the shortcomings of the SECAM image processing system. The present invention provides a character generator in a SECAM image processing system.

An apparatus according to the present invention is a character generator of a SECAM type image processing system for displaying an image signal using a cathode ray tube, the switching signal outputting a switching signal according to the line from which the input composite image signal (CS) is scanned Output circuit; A white frequency output circuit which outputs the white frequency of the line which is switched and scanned according to the switching signal output from the switching signal output circuit; And a character generating circuit for generating a character signal so that the predetermined character signal generated by being controlled by the user is displayed at a predetermined section of the cathode ray tube at the white frequency output from the white frequency output circuit.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of a character generator in a SECAM image processing system according to the present invention, and includes a switching signal output circuit 10, a white frequency output circuit 20, and a character generator circuit 30. As shown in FIG.

More specifically, the switching signal output circuit 10 is for outputting a switching signal according to a line on which the input composite video signal CS is scanned, and separating the horizontal synchronous signal from the composite video signal CS. The separation unit 11 is connected to the delay unit 12. At this time, the delay unit 12 is configured to delay the horizontal synchronization signal until the color carrier band interval. The switching signal output circuit 10 connects the delay unit 12 to a detection unit 13 for detecting a color carrier by a predetermined pulse signal. The detection unit 13 is connected to the low pass filter unit 14 for filtering the input signal to the DC level to a predetermined level, the low pass filter unit 14 is connected to the comparison unit 15. At this time, the comparing unit 15 compares the input voltage with a predetermined reference voltage and outputs a high level switching signal for one horizontal scanning time when the input voltage is greater than the reference voltage, and then the high level switching signal is It is configured to output a low level switching signal until input.

The white frequency output circuit 20 outputs the white frequency of the line that is switched and scanned according to the switching signal output from the switching signal output circuit 10. The white frequency output circuit 20 and the first oscillator 21 oscillating at 4.25 MHz and 4.4 are output. The second oscillation unit 22 that oscillates MHz is connected to the switch 23. At this time, the switch 23 applies the output of the first oscillator 21 to the character generator circuit 30 when a high level switching signal is applied, and when the low level switching signal is applied, the second oscillator ( It is configured to apply the output of 22 to the character generating circuit 30.

The character generator circuit 30 is for applying a predetermined character signal to a predetermined section of the cathode ray tube at a white frequency output from the white frequency output circuit 20. The character generator 31 and the character frequency setter 32 And a switch 33. At this time, the character generator 31 outputs a predetermined character signal and a position signal of a position of the cathode ray tube to the switch 33 according to the user's control. The character frequency setting unit 32 is configured to output the character signal of the character generator 31 at the white frequency applied by the white frequency output circuit 20. The switch 33 is switched in accordance with the position signal of the character generator 31 so as to apply the composite image signal or the character signal of the character frequency setting unit 32 to the cathode ray tube CRT.

The character generator of the SECAM image processing system according to the present invention configured as described above has the horizontal synchronizing signal separated from the composite image signal CS received from the discharge pole or the composite image signal CS reproduced from the video tape. Is separated like the pulse P1 of FIG.

The separated horizontal synchronization signal P1 is delayed by the delay unit 12 as a predetermined time pulse P2, but the delay time is until the separated horizontal synchronization signal reaches the color carrier region. In this case, when the horizontal synchronization signal is applied from the delay unit 12, the detector 13 detects the color carrier included in the composite image signal CS as shown by the pulse p3 shown in FIG. 2.

The detected color carrier P3 is once a color carrier having a white frequency of 4.4 MHz according to the characteristics of the SECAM method, and then the detected color carrier may be a color carrier having a white frequency of 4.2 MHz. At this time, the detected color carrier is not always a white frequency, but the white frequency plays a basic frequency, so even if a color carrier of any color is detected, it does not greatly deviate from the 4.4MHz or 4.2MHZ band. Therefore, if the color carrier carrier of 4.4MHz or 4.2MHz is passed through the low pass filter unit 14, the band frequency of 4.4MHz becomes a DC voltage that can be recognized as high or low level like the pulse P4 of FIG. The frequency in the 4.2MHz band is a DC voltage that can be recognized as a high level. In this way, a color carrier of 4.4 MHz or 4.2 MHz, which has become a DC voltage, is applied to the comparator 15. The comparator 15 outputs a switching signal such as the pulse P5 of FIG. 2 since the reference voltage is set lower than the DC voltage recognized as the high level and higher than the DC voltage recognized as the low level. That is, the comparator 15 outputs a high level switching signal for one horizontal period because the comparator 15 is higher than the reference voltage when a high level DC voltage is input, that is, one DC voltage is input until the next high level DC voltage is input. The low level switching signal is output during the horizontal scanning period. In this case, when the high level switching signal is applied from the comparator 15, the switch 23 applies a 4.25 MHz white frequency signal oscillated by the first oscillator 21 to the character generation circuit 30, and then the low level. When the switching signal is applied, the white frequency of 4.4 MHz oscillated by the second oscillator 22 is applied to the character generator circuit 30. Therefore, the white frequency output from the switch 23 corresponds to the scan line in the composite image signal CS input to the detector 13.

For example, if the color carrier carrier detected by the detector 13 is a scan line signal having a white frequency of 4.4 MHz, the low pass filter unit 21 becomes a low level DC voltage, and the comparison unit 15 Accordingly, a low level switching signal is output. Therefore, the switch 23 applies the white frequency of 4.4 MHz of the second oscillator 22 to the character generator circuit 30. However, if the color carrier carrier detected by the detection unit 13 is a signal of a scanning line having a white frequency of 4.25 MHz, the switch 23 converts the white frequency of 4.25 MHz of the first oscillator 21 to the character generator circuit ( 30).

At this time, the character generator 31 applies the character signal to be displayed on a predetermined portion of the cathode ray tube (CRT) to the character frequency setting unit 32 under the control of the user, while the cathode ray tube (CRT) to the switch 33 A position signal specifying the scanning line position of the characters displayed on the screen is applied. The character frequency setting unit 32 outputs the character signal of the character generator 31 at a 4.25 MHz white frequency or 4.4 MHz white frequency applied from the switch 23, and the switch 33 is connected to the position signal. Therefore, instead of the composite video signal CS, a white frequency text signal is applied to the cathode ray tube at the scanning line position where the text signal is to be placed, and a composite video signal is applied to the cathode ray tube at the scanning line where the text signal is not located. Therefore, in the cathode ray tube, characters under the control of the user can be displayed on the display besides the image by the composite video signal CS transmitted from a broadcasting station. At this time, when the character signal is scanned in the cathode ray tube (CRT), the line on which the color carrier should be scanned in the 4.25 MHz frequency band is applied with a white frequency of 4.25 MHz by the switch 23, and the color carrier in the 4.4 MHz band. Since a white frequency of 4.4 MHz is applied to the line to be scanned, the text signal displayed on the cathode ray tube can be displayed in white without color distortion.

As described above, the present invention has the effect of enabling the user to perform the character display function in the SECAM image processing system by applying the desired character signal to the cathode ray tube as a white frequency.

Claims (4)

A character generating apparatus of a SECAM type image processing system for displaying an image signal using a cathode ray tube, comprising: a switching signal output circuit (10) for outputting a switching signal corresponding to a line on which an input composite image signal (CS) is scanned; A white frequency output circuit 20 outputting a white frequency of a line that is switched and scanned according to a switching signal output from the switching signal output circuit 10; And a character generation circuit 30 for generating the character signal so that a predetermined character signal generated by being controlled by a user is displayed at a predetermined section of the cathode ray tube at a white frequency output from the white frequency output circuit 20. Character generator of SECAM image processing system, characterized in that. The switching signal output circuit (10) of claim 1, further comprising: a separation unit (11) for separating a horizontal synchronization signal from the composite video signal (CS); A delay unit 12 for delaying the horizontal synchronization signal output from the separation unit 11 for a predetermined time and outputting the delayed signal; A detector (13) for detecting a color carrier region of the composite video signal (CS) by using a delayed horizontal synchronization signal output from the delay unit (12); A low pass filter (4) for filtering the output of the detector (13); And a comparator (15) for outputting the switching signal by comparing the output of the low pass filter (14) with a reference voltage. 2. The white frequency output circuit (20) according to claim 1, further comprising: a first oscillator (21) for oscillating a white frequency having a first predetermined frequency; A second oscillation unit 22 oscillating a white frequency having a second predetermined frequency; And a switch 23 for selectively outputting the outputs of the first oscillator 21 and the second oscillator 22 according to the switching signal output from the switching signal output circuit 10. Character generator of video system. The character generating circuit (30) according to claim 1, wherein said character generating circuit (30) comprises: a character generating portion (31) which is controlled by a user and outputs a position signal specifying a position at which said character signal and said character signal are to be displayed on said cathode ray tube; A character frequency setting unit 32 outputting a white frequency provided from the white frequency output circuit 20 to the character output from the character generating unit 31; And a switch (33) for selectively outputting a text signal output from the text generator (31).