KR0156356B1 - Side blanking controlling apparatus of wide tv - Google Patents

Abstract

The present invention relates to a side blanking control device for a wide television, the configuration of which is a signal conversion control unit 10 for controlling the side blanking operation to match the 4: 3 screen mode as the user selects the 4: 3 screen mode ) And a pulse generation start point setting unit 15 which receives the horizontal and vertical synchronization signals from the synchronization separating unit 5 and applies a signal obtained by synchronizing the two signals to the signal conversion control unit 10 as a pulse generation start point signal. ) Receives a predetermined reset signal and a trigger signal from the signal conversion control unit 10 to generate a new side blanking signal pulse suitable for 4: 3 screen mode, and then applies the pulse to the signal conversion control unit 10. And a driver 25 for applying a new side blanking signal to the luminance output terminal of the image signal processor 4 under the control of the pulse generating means 20 and the signal conversion controller 10. When the 4: 3 screen mode is selected, the signal conversion control unit 10 non-inverts the horizontal and vertical synchronization signals from the synchronization separation unit 5 and applies them to the pulse generation start point setting unit 15. The pulse generation means 20 inverts the pulse generation start point signal input from the pulse generation start point setting unit 15 to the reset terminal of the pulse generation means 20 and inverts the horizontal synchronous signal. It is characterized in that the drive unit 25 is controlled so that the oscillation operation is performed by inputting to the trigger terminal of the control unit so that the pulse from the pulse generating means 20 is combined with the luminance signal as a new side blanking signal.

Description

Side Blanking Control Unit for Wide Television

1 is a block diagram for explaining an example of a problem which occurs during a video reproduction processing operation of a general television.

2 is a circuit diagram for explaining a side blanking control device for a wide television according to an embodiment of the present invention.

3 is a diagram showing output waveforms of respective parts of the circuit diagram shown in FIG.

* Explanation of symbols for main parts of the drawings

1: Tuner 2: Middle frequency amplifier

3: Image detector 4: Image signal processor

5: Sync separation unit 6: Horizontal sync signal detector

7: horizontal deflection circuit

8: Flyback Transformer (FBT)

10: signal conversion control unit 15: pulse generation start point setting unit

20: pulse generating means 25: drive unit

The present invention relates to a side blanking control device of a wide television, and more particularly, to control a side blanking of a wide television using a horizontal blanking pulse generation circuit so that accurate horizontal scanning is performed in a 4: 3 mode. Relates to a device.

As is well known, a television outputs a broadcast signal from an antenna to a video / audio playback process and outputs it through a CRT and a speaker. In the video / audio playback processing apparatus, as shown in FIG. It is divided into VHF and UHF according to the receiving frequency band, and consists of circuits such as input tuning, high frequency amplification, mixing, and local oscillation, respectively. By selecting and amplifying the radio wave signal for a signal, the high frequency signal f1 and the local oscillation signal f2 from the antenna A are mixed together to generate a new low frequency component f2-f1 signal (i.e., an intermediate frequency signal (video). 58.75 MHz, audio 54, 25 MHz)] and a two to three stage heavy amplifier to amplify the intermediate frequency signal output from the tuner 1 to the size required for the CRT. Not only the video intermediate frequency amplifier section (2) for amplifying the color signal transfer included in the high-band of the video signal to the faithful color reproduction without distortion; From the intermediate frequency signal amplified by the video intermediate frequency amplifier 2, the composite video signal (e.g., luminance signal, carrier color signal, synchronization signal, etc.) is faithfully extracted without distortion, and the components of the audio signal that are no longer needed are 54.25 An image detector (3) for suppressing occurrence of bite interference by removing the trap with MHz or 4.5 MHz; The composite video signal output from the image detector 3 is separated into a luminance signal and a color signal, brightness and contrast adjustments of the separated luminance signal are performed, demodulation of the separated color signal is performed, and the luminance signal (-Y And a video signal processor (4) for converting the two demodulated color difference signals into R, G, and B signals, which are display signals for color image reproduction, through a matrix circuit (not shown) and outputting them. A synchronization separator (5) for separating the horizontal and vertical synchronization signals by using a difference in amplitude between the horizontal and vertical synchronization signals and the image signals in the composite video signal detected by the image detection unit (3); The horizontal synchronizing signal and the vertical synchronizing signal have the same amplitude but different pulse widths, so that the horizontal synchronizing signal detecting unit 6 detects the horizontal synchronizing signal using this difference; A pulse of 15.75 kHz synchronized with the horizontal synchronous signal is generated and the driving pulse is used to generate a horizontal deflection current, and at the same time, a high-pressure is applied to the anode of the CRT through a flyback transformer (FBT: 8), while returning the horizontal deflection pulse. It consists of a horizontal deflection circuit portion 7 which controls the period, rectifies the retrace pulse generated during the horizontal deflection operation, creates a medium voltage DC voltage, and uses it as part of the B power supply.

Referring to the operation of the general image playback processing device configured as described above are as follows.

Once the user selects an arbitrary broadcast channel, the intermediate frequency signal for the corresponding broadcast channel tuned by the tuner 1 is applied to the image intermediate frequency amplifier 2, amplified by a predetermined value, and then the image detector 3 The video detector 3 extracts a composite video signal composed of, for example, a luminance signal, a carrier color signal, and a synchronization signal from the intermediate frequency signal, and applies the extracted video signal to the video signal processor 4. The processing unit 4 separates the composite video signal into a luminance signal and a color signal, performs a predetermined signal processing operation on each of them, and then converts the color image into an R, G, and B signal through a matrix circuit (not shown) for output. do. In addition, when the luminance signal (-Y) is output, the horizontal deflection circuit unit 7 horizontally drives the horizontal synchronous signal to control the horizontal retrace signal and the retrace period of the horizontal retrace signal through the FBT (8). A signal (hereinafter referred to as a BLK signal) is generated and output, and the BLK signal is combined with the luminance signal (-Y) and sent to the CRT. Based on the BLK signal, the front point (Front Point) during the 1H scanning period is ), Accurate horizontal scanning is performed.

The image reproduction processing apparatus operating as described above is adopted in most wide televisions. In such a wide television, the state of the BLK signal output from the FBT when switching from the 16: 9 mode to the 4: 3 mode, Because of the instability of the horizontal retrace signal, it is not easy to adjust the horizontal retrace signal. Therefore, an accurate horizontal scan is not performed in the horizontal retrace period. Therefore, an unclean screen such as a distorted screen is displayed on the left and right of the 4: 3 screen. The viewing satisfaction of the viewer is reduced.

Accordingly, the present invention has been made in view of the above-described circumstances, and its object is to perform a horizontal scan operation at an accurate horizontal scan position using a horizontal blanking pulse generation circuit when switching from 16: 9 screen mode to 4: 3 screen mode. The present invention provides a side blanking control device for a wide television which eliminates the occurrence of excessive scanning dose.

In order to achieve the above object, a side blanking control apparatus for a wide television according to the present invention is a signal conversion for controlling a side blanking operation suitable for a 4: 3 screen mode as a 4: 3 screen mode is selected by a user. A pulse generation start point setting unit for receiving a horizontal and vertical synchronization signal from the synchronization separating unit and applying a synchronization signal between the two signals as a pulse generation start point signal to the signal conversion control unit; Pulse generation means for receiving a reset signal and a trigger signal to generate a new side blanking signal pulse suitable for 4: 3 screen mode, and then applying the pulse to the signal conversion controller; and new side blanking under the control of the signal conversion controller. And a driver for applying a signal to the luminance output terminal of the video signal processor. When the 4: 3 screen mode is selected, the fisherman inverts the horizontal and vertical synchronous signals from the synchronous separation unit, applies the pulse generation start point setting unit, and inverts the pulse generation start point signal inputted from the pulse generation start point setting unit. The oscillating operation is performed by inputting a signal in which the horizontal synchronizing signal is inverted into the trigger terminal of the pulse generating means, and applying a pulse from the pulse generating means to a new side. The driving unit is controlled to be combined with the luminance signal as a blanking signal, wherein the pulse generating unit is configured to perform an oscillation operation when a predetermined signal is input to a trigger terminal based on a reset signal applied from the signal conversion control unit. When the oscillation signal from the first oscillator is input to the trigger terminal, the reset signal is written. That the oscillator consists of a second oscillator for outputting a predetermined oscillation frequency to the signal conversion control unit is characterized.

According to the present invention configured as described above, when the user switches from the 16: 9 screen mode to 4: 3 screen mode, the horizontal and vertical synchronous signal from the synchronization separator is signal-processed in the pulse generation start point setting section and then pulse generating means. Is supplied to a signal conversion control unit to provide a pulse generation start point of the pulse generation unit, the signal conversion control unit inverts the pulse generation start point signal and applies it to the reset terminal of the pulse generation unit, and inverts the horizontal synchronous signal. The pulse generated according to the pulse generation operation of the pulse generating means is applied to the signal conversion control unit, and is output as a new side blanking signal through the driving unit.

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

2 is a circuit diagram for explaining a side blanking control apparatus for a wide television according to an embodiment of the present invention. The embodiment of the present invention includes a signal conversion control unit 10, a pulse generation start point setting unit 15, and a pulse generation unit. 20, the drive unit 25 is included.

The signal conversion control unit 10 is connected to receive the horizontal synchronizing signal and the vertical synchronizing signal from the synchronizing separator 5, so that when the 4; 3 screen mode is selected by the user among the 16: 9 screen mode and the 4: 3 screen mode. It is a control element composed of, for example, an inverter and a buffer for controlling a generation operation of a new side blanking signal suitable for the 4: 3 screen mode.

Here, the signal conversion control section 10 is circuit-connected so as to non-invert the horizontal and vertical synchronization signals from the synchronization separation section 5 and to transmit them to the pulse generation start point setting section 15 which will be described later. It is connected in circuit so as to invert the signal from the generation start point setting section 15 and apply it to the reset terminal of the pulse generating means 20 which will be described later, and the horizontal synchronous signal (inverted output from the signal conversion control section 10) H 'signal) is connected in circuit so as to be inputted to the input terminal IN of the first oscillator 22 of the pulse generating means 20. In addition, the pulse input terminal IN of the signal conversion control unit 10 is connected to the circuit so that the output pulse signal of the second oscillator 24 of the pulse generating means 20 is inputted, the signal conversion control unit 10 Output terminal (OUT) is connected to the driving unit (25).

In particular, the reason for inverting the signal from the pulse generation start point setting unit 15 during the operation of the signal conversion control unit 10 is low active (Low) of the reset terminals of the first and second oscillators 22 and 24 which will be described later. This is to match the Active status.

The pulse generation start point setting unit 15 receives the horizontal and vertical synchronous signals from the synchronous separation unit 5 inputted through the signal conversion control unit 10 to generate the pulse generation start point of the pulse generation unit 20. After the AND processing, the signal (i.e., the (HV) signal) is applied to the signal conversion control section 10.

The pulse generating means 20 is composed of first and second oscillators 22 and 24 each of which is a monostable multivibrator.

The first oscillator 22 receives another signal from the signal conversion control unit 10 while receiving the reset signal (that is, the (HV) 'signal) from the signal conversion control unit 10 as the reset terminal. The trigger terminal IN of the second oscillator 24 is performed through the output stage Q by performing a predetermined oscillation operation from the time when the inverted horizontal synchronizing signal H 'signal is input to the trigger terminal IN. A predetermined pulse is transmitted to the. In particular, the output pulse width of the first oscillator 22 is adjusted as a time constant by the sum of the resistor R1 and the capacitor C1.

Here, at one end of the first oscillator 22, a capacitor C2 for filtering (bypassing in the circuit diagram of the present invention), for example, jitter generated by the pulse generating operation of the first oscillator 22. Is preferably connected.

The second oscillator 24 outputs from the first oscillator 22 in a state in which a reset signal (that is, a (HV) 'signal) from the signal conversion control unit 10 is received as a reset terminal. From the time when the pulse is input to the trigger terminal IN, a predetermined oscillation operation is performed to input a predetermined pulse to the pulse input terminal IN of the signal conversion controller 10 through the output terminal Q. In particular, the output pulse width of the second oscillator 24 is adjusted as a time constant by the sum of the resistor R2 and the capacitor C3.

Here, a capacitor C4 is connected to one end of the second oscillator 24. For example, the capacitor C4 is used to generate jitter due to the pulse generation operation of the second oscillator 24. Filtered.

In particular, the first and second oscillators 22 and 24 are provided from the signal conversion control unit 10 which is input to the reset terminal when the user presses the screen mode selection switch SW to select a 16: 9 screen mode. Signal (i.e., the inverted horizontal synchronizing signal) is bypassed and becomes inoperable.

On the other hand, the driving unit 25 has a base connected to the output terminal OUT of the signal conversion control unit 10 via the resistor R3, while the collector has a predetermined operating power supply terminal Vcc: A first transistor Q1 connected to about 12V); The base is connected to the collector of the first transistor Q1 while the collector is connected to the operating power supply terminal Vcc via the resistor R5 and the emitter is grounded via the resistor R6 and the emitter The second transistor Q2 is formed between the resistor R6 and the diode D connected to the luminance output terminal of the image signal processor 4 to generate a new horizontal blanking signal output from the signal conversion controller 10. The pulse is driven based on a new horizontal blanking signal.

Next, the operation of the side blanking control device of the wide television according to the present invention configured as described above will be described with reference to FIG. 2 and FIG.

In the description of the embodiment of the present invention, the horizontal synchronous signal from the synchronous separator 5 input to the horizontal synchronous signal input terminal Hin of the signal conversion controller 10 has a square wave shape as shown in FIG. It will be set to be described as follows, and the vertical synchronous signal from the synchronous separation unit 5 input to the vertical synchronous signal input terminal Vin is set and described as having the form as shown in FIG.

In the description of the embodiment of the present invention, only the case of switching from the 16: 9 screen mode to the 4: 3 screen mode will be described.

As the screen width is reduced, phases of the horizontal and vertical synchronous signals inputted to the signal conversion control unit 10 are easily shifted from each other. In this case, the signal conversion control unit is prevented because it becomes a scattered screen in the display operation. (10) non-inverts the horizontal and vertical synchronous signals and inputs them to the pulse generation start point setting unit 15, and the pulse generation start point setting unit 15 processes the two signals and performs a phase matched signal (first 3 (c)) is input to the signal conversion controller 10.

Subsequently, the signal (see FIG. 3 (c)) should be input to the reset terminals of the first and second oscillators 22 and 24 under the control of the signal conversion control unit 10. The reset terminal is low-active. Since it is a state, the signal (see FIG. 3 (c)) is inputted inverted by the signal conversion control section 10 (see FIG. 3 (d)). Subsequently, the signal conversion control unit 10 inverts the horizontal synchronizing signal among the horizontal and vertical synchronizing signals from the synchronizing separator 5 and inputs it to the trigger terminal IN of the first oscillator 22 (the second). 3 (d)).

Accordingly, the first oscillator 22 performs the oscillation operation for 1H at the pulse generation start point synchronized with the horizontal synchronous signal, and the first oscillator 22 is the sum of the resistor R1 and the capacitor C1. The second oscillator 24 receives a signal (see FIG. 3 (e)) for setting the front point of the horizontal blanking signal (ie, the BLK signal) while adjusting the width W1 of the pulse by the time constant of the second oscillator 24. Input to trigger terminal (IN) of.

Subsequently, the second oscillator 24 is triggered at a time delayed by W1 from the start point of the signal (see FIG. 3 (e)) applied from the output terminal Q of the first oscillator 22. The signal conversion control unit outputs a signal (see FIG. 3 (f)) oscillating with a predetermined pulse width W2 based on the time constant obtained by the sum of the resistor R2 and the capacitor C3. To (10).

Accordingly, the signal conversion control unit 10 receives a new horizontal blanking signal generation pulse having the same frequency as the horizontal synchronization signal and the synchronous width is changed to W2, so that the signal conversion control unit 10 outputs the output terminal OUT. The new horizontal blanking signal is applied to the driver 25 as a drive control signal, and the driver 25 changes the front point of the horizontal blanking signal by W2 in the 16: 9 mode and the new horizontal blanking signal. Is inverted to the luminance signal (-Y) output terminal of the video signal processing section 4.

Accordingly, the new horizontal blanking signal is applied to the CRT in combination with the luminance signal (-Y), so that a horizontal scan suitable for 4: 3 screen mode is performed.

According to the present invention as described above, when the user switches from the 16: 9 screen mode to the 4: 3 screen mode, a new horizontal blanking signal is generated in which the front point of the horizontal blanking signal output from the flyback transformer is changed to a predetermined value. Since the signal is combined with the signal (-Y) and then applied to the CRT, an accurate horizontal blanking operation is performed according to the screen mode switching, so that the overscan amount in the 4: 3 screen mode is compensated.

Claims (1)

When the 4: 3 screen mode is selected by the user, the horizontal and vertical synchronous signals from the synchronization conversion unit 5 and the signal conversion control unit 10 for controlling the side blanking operation for the 4: 3 screen mode are performed. The pulse generation start point setting unit 15 and a predetermined reset signal and the trigger from the signal conversion control unit 10 are applied to the signal conversion control unit 10 as a pulse generation start point signal that receives the input signal in synchronization with the two signals. The pulse generating means 20 and the signal conversion control unit 10 which generate a new side blanking signal pulse suitable for 4: 3 screen mode and then apply the signal to the signal conversion control unit 10 by receiving the signal. And a driving unit 25 for applying a new side blanking signal to the luminance output terminal of the image signal processing unit 4, wherein the signal conversion control unit 10 is selected as the 4: 3 screen mode. in Non-inverting the horizontal and vertical synchronous signals of the data source, apply the pulse generation start point setting unit 15, and then invert the pulse generation start point signal inputted from the pulse generation start point setting unit 15 to generate the pulse generation means 20. The oscillation operation is performed by inputting a signal in which the horizontal synchronizing signal is inverted and a signal generated by inverting the horizontal synchronizing signal to the trigger terminal of the pulse generating means 20, and the pulse from the pulse generating means 20 The driving unit 25 is controlled to be coupled to the luminance signal as a new side blanking signal, wherein the pulse generator 20 is connected to a trigger terminal based on a reset signal applied from the signal conversion control unit 10. When a predetermined signal is input, the first oscillator 22 performing the oscillation operation and the oscillation signal from the first oscillator 22 are input to the trigger terminal, and thus the oscillation signal is generated based on the reset signal. And a second oscillator (24) for outputting a predetermined oscillation frequency to the signal conversion control section (10).