KR100220016B1 - Auto-frequency control device in no-signal state - Google Patents

Abstract

The present invention determines the display position of the OSD by controlling the frequency of the vertical and horizontal synchronization signals supplied to the microcomputer as the frequency of the voltage controlled oscillator is changed by the error of the automatic frequency control when the signal is no signal. The present invention relates to an automatic frequency control apparatus for no signal to prevent shaking. In the conventional OSD circuit, an error occurs in the automatic frequency controller (8) when a composite video signal is not input or is very unstable. Since the oscillation frequency output from 9) is changed, the frequency of the horizontal and vertical driving pulses is changed and input to the horizontal deflection portion 12 and the vertical deflection portion 13.

Therefore, the horizontal and vertical synchronization signals outputted from the deflection unit are changed and input to the microcomputer 14, which causes the display position of the OSD to be shaken, thereby preventing the recognition of an image such as a character displayed on the CRT 6.

In order to solve the conventional problem, the present invention determines whether the signal output from the synchronization separator is a synchronization signal of a normal video signal, and if it is a normal video signal, applies the signal output from the synchronization separation unit to an automatic frequency controller, If it is an image signal, the signal applied to the automatic frequency control unit is interrupted to stop the operation of the automatic frequency control unit to supply a constant horizontal and vertical synchronization signal to the microcomputer and to display 0SD at the correct position.

Description

Automatic frequency control device in no signal

The present invention determines the display position of the OSD by controlling the frequency of the vertical and horizontal synchronous signals supplied to the microcomputer as the frequency of the voltage controlled oscillator is changed by the error of the automatic frequency control when the signal is no signal. The present invention relates to an automatic frequency control apparatus for no signal to prevent shaking.

As shown in FIG. 1, the conventional OSD circuit includes an image detector 1 for detecting and outputting an input composite video signal, and a voice trap unit 2 for removing audio signals included in the detected output composite video signal. And an image processing unit 3 for receiving a synthesized video signal from which the audio signal has been removed and processing the image and outputting the image signal, an image signal processed by the image processing unit 3 and R, G output from the microcomputer 14; An OSD interface unit 4 for synthesizing and outputting a B signal, an image amplifier unit 5 for amplifying and outputting an image output from the OSD interface unit 4 and displaying the same on the CRT 6, and the audio Synchronous separation unit 7 for receiving the composite video signal and separating the synchronization signal, and after receiving the horizontal synchronous signal separated in the synchronization separation unit 7 and shaping the automatic frequency control pulse output from the flyback transformer Compared to the flyback pulse An automatic frequency control unit 8 for outputting a control voltage proportional to an abnormality, a voltage controlled oscillation unit 9 for receiving a signal output from the automatic frequency control unit 8 and outputting a variable oscillation frequency, and the voltage controlled oscillation unit (9) horizontal and vertical deflection for receiving the frequency output from the horizontal and vertical output unit 10 and 11 for outputting horizontal and vertical synchronous signals, and for applying the output horizontal and vertical synchronous signals to the microcomputer 14; The unit 12 and 13 and the microcomputer 14 which receives the horizontal and vertical synchronization signals output from the horizontal and vertical deflection units 12 and 13 and determine a position to display the OSD.

In the conventional OSD circuit configured as described above, as shown in FIG. 1, when a composite video signal is detected and output from the image detector 1 and input to the voice trap unit 2, the audio trap unit 2 inputs the synthesized image. The audio included in the signal is removed and applied to the image processor 3 and the synchronization separator 7.

At this time, when the image processor 3 receives the composite video signal from which the audio is removed and outputs the video signal, the OSD interface unit 4 synthesizes the R, G, and B signals output from the microcomputer 14 to output the video signal. 5), an image is displayed on the CRT 6.

On the other hand, the synthesized video signal output by removing the audio signal from the audio trap unit 2 is input to the synchronization separator 7 when the horizontal and vertical synchronization signal of the composite video signal is separated, the automatic frequency control unit 8 is separated After receiving the horizontal and vertical synchronous signals, the automatic frequency control pulses output from the flyback transformer are shaped, and the flyback pulses are compared with the horizontal synchronous signals. 9).

Therefore, the voltage controlled oscillator 9 changes the oscillation frequency according to the control voltage output from the automatic frequency controller 8 and outputs the horizontal output terminal 10 and the vertical output terminal 11 to receive the horizontal deflection unit 12. And the deflector applies the horizontal and vertical synchronization signals to the microcomputer 14 by outputting the signal to the vertical deflector 13.

When the horizontal and vertical synchronization signals are input to the microcomputer 14 as described above, the microcomputer 14 outputs R, G, and B signals to the OSD interface unit 4 using the respective synchronization signals. The location is determined.

However, in the conventional OSD circuit, when the composite video signal is not input or is very unstable, an error occurs in the automatic frequency controller 8, so the oscillation frequency output from the voltage controlled oscillator 9 changes, so that horizontal and vertical driving pulses are used. The frequency is changed and input to the horizontal deflection portion 12 and the vertical deflection portion 13.

Therefore, the horizontal and vertical synchronization signals output from the deflection unit are changed and input to the microcomputer 14, which causes the display position of the OSD to be shaken, thereby preventing the recognition of an image such as a character displayed on the CRT 6.

In order to solve the conventional problem, the present invention determines whether the signal output from the synchronization separator is a synchronization signal of a normal video signal, and if it is a normal video signal, applies the signal output from the synchronization separation unit to an automatic frequency controller, If it is an image signal, it cuts off the signal applied to the automatic frequency controller and stops the operation of the automatic frequency controller to supply a constant horizontal and vertical synchronization signal to the microcomputer so that the 0SD is displayed at the correct position. The configuration and effect of the invention are as follows.

1 is a block diagram showing a conventional OSD circuit.

Figure 2 is a block diagram showing the structure of the automatic frequency control device in the present invention no signal.

Figure 3 is a block circuit diagram showing a detailed structure of the automatic frequency control device in the non-signal of the present invention.

Figure 4 (a) is a waveform diagram showing a structure when the video signal of the present invention and the flyback pulse coincides.

(b) is a waveform diagram showing a correction state of an image signal and a flyback pulse by operating the automatic frequency control device of the present invention.

Figure 5 (a) to (bar) is a waveform diagram of each part of the present invention.

As shown in FIG. 2, the automatic frequency control apparatus of the non-signal according to the present invention removes an image detector 1 for detecting and outputting an input composite video signal, and removes an audio signal included in the detected output composite video signal. An audio trap unit 2, an image processor 3 for receiving a synthesized video signal from which the audio signal has been removed, and processing and outputting an image; and an image signal and a microcomputer 14 processed by the image processor 3 OSD interface unit 4 for synthesizing and outputting the R, G, and B signals outputted from the image output unit, and an image amplifier unit 5 for amplifying and outputting the image output from the OSD interface unit 4 to display on the CRT 6. And a synchronization separator 7 which receives the synthesized video signal from which the voice is removed and separates the synchronization signal, and determines whether the synchronization signal is a normal video signal by receiving the signal output from the synchronization separator 7. The automatic frequency control unit ( 8) the automatic frequency error prevention unit 15 for controlling to operate, and if the signal output from the synchronization separation unit 7 as a result of the determination of the automatic frequency error prevention unit 15 is a synchronization signal of a normal video signal synchronization unit An automatic frequency controller (8) for receiving a horizontal synchronization signal among the synchronization signals separated in (7) and outputting a control voltage proportional to the deviation from the synchronization compared with the flyback pulse output from the external flyback transformer; A voltage controlled oscillator 9 for receiving the signal outputted from (8) and outputting the oscillation frequency so as to change the oscillation frequency, and a horizontal and vertical receiving oscillation frequency output from the voltage controlled oscillator 9 for outputting horizontal and vertical synchronization signals; Vertical output units 10 and 11, horizontal and vertical deflection units 12 and 13 for applying the output horizontal and vertical synchronization signals to the microcomputer 14, and the horizontal and vertical synchronization units 12 and 13 Horizontal and vertical copper output from It receives the signal it consists of a microcomputer (14) for determining a position such that the OSD is displayed.

Meanwhile, the automatic frequency error prevention unit 15 for determining whether the signal output from the synchronization separation unit 7 is the synchronization signal of the calculated video signal and the automatic frequency control unit 8 for outputting the control voltage are shown in FIG. 3. Likewise, first, the automatic frequency error prevention unit 15 receives a synchronization signal including a noise component output from the synchronization separator 7 and a flyback pulse input from the outside, and outputs a signal input in the flyback pulse period. An AND gate 15-1, an integrator 15-2 for shaping and outputting the signal output from the AND gate 15-1, and a level shift for shifting and outputting the level of the flyback pulse input from the outside. 15-3 and a comparator 15-4 for comparing the signal output from the level shift 15-3 and the signal output from the integrator 15-2, and the comparator 15-4. On-off operation to operate the automatic frequency control unit 8 by the output comparison signal It will composed of a transistor (Q6),

The automatic frequency control section 8 includes a transistor Q5 which operates only during a horizontal synchronization signal period among the synchronization signals output from the synchronization separator 7, and a DC bias is applied by the on / off operation of the transistor Q5. The transistor Q4 is turned on to flow to the first half, and the transistor Q3 is turned on to flow from the transistor Q2.

Reference numeral R1-R13 is a resistor, C1-C6 is a capacitor, Q1 is a transistor.

2 and 3, the composite image signal is detected and output from the image detector 1 and input to the voice trap unit 2. Removes the sound included in the input composite video signal and applies it to the image processor 3 and the synchronization separator 7.

At this time, when the image processor 3 receives the composite video signal from which the audio is removed and outputs the video signal, the OSD interface unit 4 synthesizes the R, G, and B signals output from the microcomputer 14 to output the video signal. 5), an image is displayed on the CRT 6.

On the other hand, the synthesized video signal output by removing the audio signal from the audio trap unit 2 is input to the synchronization separator 7 when the horizontal and vertical synchronization signal of the composite video signal is separated, the automatic frequency control unit 8 is separated It receives horizontal and vertical synchronous signals and shapes the automatic frequency control pulses output from the flyback transformer to compare the input flyback pulses with the horizontal synchronous signals.

That is, the transistor Q5 in the automatic frequency control unit 8 is turned on during the horizontal synchronizing period, and while the DC bias is applied to the base of the transistor Q4, the transistor Q3 as shown in FIG. Since the first half of the synchronous signal flows through the transistor Q4 and the second half of the synchronous signal flows through the transistor Q2 with the transistor Q3 turned on, a constant current is always maintained in the video signal period. Will flow.

At this time, if the flyback pulse inputted through the horizontal output stage is not synchronized with the synchronization signal, as shown in (a) and (b) of FIG. 4, a pulse is generated to output a control voltage for controlling the voltage controlled oscillator 9. The oscillation frequency of the voltage controlled oscillator 9 is changed to match the synchronization signal of the video signal.

On the other hand, when a noise signal and a very unstable signal are input from the outside, the synchronization separator 7 recognizes a specific portion of the noise as a synchronization signal and applies the synchronization signal to the automatic frequency controller 8.

Therefore, the automatic frequency controller 8 receives an incorrectly recognized synchronization signal from the synchronization separator 7 to generate an error voltage, thereby changing the oscillation frequency output from the voltage controlled oscillator 9.

As such, when the oscillation frequency is changed and output by the synchronous signal incorrectly recognized by the voltage controlled oscillator 9, the horizontal deflection unit changes the horizontal and vertical synchronization signals output from the horizontal output unit 10 and the vertical output unit 11. Since the horizontal and vertical synchronizing signals are input to the microcomputer 14 after being inputted to the 12 and the vertical deflection unit 13, the microcomputer 14 cannot display the OSD at the correct position. When the specific part of the noise signal input from the signal is output as the synchronization signal, the automatic frequency error prevention unit 15 connecting the synchronization separation unit 7 and the automatic frequency control unit 8 is output from the synchronization separation unit 7. The received synchronization signal is input to the automatic frequency control unit 8 of a signal similar to the input synchronization signal.

That is, the AND gate 15-1 in the automatic frequency error prevention unit 15 is inputted from the signal output from the synchronization separating unit 7 as shown in FIG. 5A and externally as shown in FIG. 5B. The flyback pulse is received and logically multiplied to output the signal input in the flyback pulse period as shown in FIG.

Therefore, the signal output from the AND gate 15-1 is waveform-shaped as shown in FIG. 5D in the integrator 15-2 composed of the resistor R10 and the capacitor C10, thereby providing the comparator 15-4. At the same time, the flyback pulse signal is input to the level shift 15-3 made up of the resistors R11-R14 and the transistor Q7, and is connected to the negative terminal of the comparator 15-4. A signal such as is input.

The peak-to-peak value output from the level shift 15-3 may be set by the resistors R14 and R15.

When the signals output from the integrator 15-2 and the level shift 15-3 are input to the comparator 15-4, the comparator 15-4 compares the input signals to the integrator 15-2. When the output of the signal is lower than the level set by the resistors R14 and R15 in the level shift 15-3, the input synchronization signal is judged as a noise signal and the comparator 15-4 as shown in FIG. The low signal is output to turn on the transistor Q6.

At this time, the transistor Q6 is turned on, and the synchronization signal applied to the base of the transistor Q5 in the automatic frequency control unit 7 is grounded, so that the operation of the automatic frequency control unit 7 is stopped and only a constant control voltage is applied to the voltage controlled oscillator. It is applied to (9) to stabilize horizontal and vertical oscillation frequency.

Therefore, when the stable oscillation frequency is output from the voltage controlled oscillator 9, the horizontal and vertical synchronization signals supplied to the microcomputer 14 through the deflection unit are stably supplied, thereby enabling the OSD to be always displayed at a constant position.

As described above, it is determined whether the signal output from the synchronization separator is a synchronization signal of a normal video signal, and if it is a normal video signal, the signal output from the synchronization separator is applied to the automatic frequency control unit. By blocking the signal applied to stop the operation of the automatic frequency control unit to supply a constant horizontal and vertical synchronization signal to the microcomputer to display the 0SD in the correct position, so that the viewer can accurately recognize the character information displayed on the CRT It has an effect.

Claims (2)

The control voltage is detected after comparing the synchronous separator 7 separating the horizontal and vertical synchronous signals of the input video signal with the synchronous signal output from the synchronous separator 7 and the flyback pulse input from the outside. In the TV consisting of an automatic frequency control unit 8 for outputting a and a voltage controlled oscillation unit 9 for receiving a control voltage output from the automatic frequency control unit 8 and outputting a changed horizontal and vertical oscillation frequency, The automatic frequency error prevention unit 15 receives the synchronization signal of the image signal output from the synchronization separator 7 to determine whether the input synchronization signal is a normal signal, and if the synchronization signal is abnormal, the operation of the automatic frequency control unit 8 is performed. Automatic frequency control device in the no signal, characterized in that by outputting a constant horizontal and vertical oscillation frequency from the voltage controlled oscillator (9) to supply a stable horizontal and vertical synchronous signal to the microcomputer through the deflection. 2. The automatic frequency error prevention unit 15 receives a synchronization signal including a noise component output from the synchronization separator 7 and a flyback pulse input from the outside and is input in the flyback pulse period. Outputs the shifted levels of an AND gate 15-1 for outputting the signal, an integrator 15-2 for shaping and outputting a signal output from the AND gate 15-1, and an externally input flyback pulse. A level shifter 15-3, a comparator 15-4 for comparing the signal output from the level shift 15-3 and the signal output from the integrator 15-2, and the comparator 15-4 Automatic frequency control device in the no signal, characterized in that consisting of a transistor (Q6) to operate on and off to operate the automatic frequency control unit 8 by the comparison signal output from the comparison.