KR870001610B1 - Step sign producing apparatus - Google Patents

Abstract

The invention relates to a unit for generating step signals, separate from horizontal and vertical synchronous sugnals, for step scanning to bouble flying scanning so as to obtain the function of high resolution in conventional televisions and monitors of flying scanning type.

Description

Step signal generator

1 is a circuit diagram of an apparatus of the present invention.

2a and 2b are waveform diagrams generated inside the circuit of FIG.

3A and 3B are views for explaining step scanning.

The present invention relates to a step signal generator that is separate from horizontal and vertical synchronization signals by step injection for doubling interlaced scanning to maintain a high resolution function while maintaining interlaced scanning of existing TV receivers and monitors of interlaced scanning. will be.

In conventional high-definition digital TVs, the number of injection players has doubled, so it is very difficult to apply interlaced scan method, and the interlaced scan method has been avoided. This becomes necessary and becomes a cost increase factor of a product.

The relationship between the vertical and horizontal synchronization signals for the conventional 525 scan line and the scanning line displayed on the screen is shown in a, c, and e of FIG. 3a, respectively. The points (a), (b), (c) and (d) shown in a of FIG. 3a are shown in consideration of the phase relationship between the vertical deflection signal and the horizontal deflection signal in c and e of FIG. 3a. The solid line in a of FIG. 3A represents field 1, and the dotted line represents field 2. FIG.

The vertical and horizontal deflection signals of field 1 are shown in c of FIG. 3a and the vertical and horizontal deflection signals of field 2 are shown in e of FIG. 3a.

B of FIG. 3a shows the scanning line displayed on the screen when the interlaced scanning 525 scan line, such as a and c of FIG. 3a, is doubled to 1050 scan line, and the solid line also shows the field 2 dotted line.

The first scanning line shown in a of FIG. 3a is represented by two scanning lines 1 in b of FIG. 3a, and the second scanning line is represented by two scanning lines 2 in b of FIG. 3a. Here, it can be seen that the first and second scan lines shown in b of FIG. 3a have to jump by a certain step after the first scan line to allow the first scan line to enter the field 2.

In order to leap this step, the vertical deflection signal must also be suddenly increased by the step, and the vertical deflection signal shown in d of FIG. 3a reflects this. In order for the vertical deflection signal to be as in d in FIG. 3a, a step signal is also required as shown in d in FIG. 3a.

F in FIG. 3A shows the vertical and horizontal deflection signals and the step signal of the field 2, in which the step signal must first exist at the time point 0 at the start of scanning, which is different from the step signal of the field 1 (FIG. 1D). Is the point.

When the step signal shown in FIG. 3A is enlarged, it is the same as FIG. 3B. The step signal shown in d of FIG. 3b has the same frequency as the horizontal synchronization pulse of the composite video signal (shown in 0 of FIG. 3b), and is half the frequency of the horizontal deflection signal (c in FIG. 3b). This is because 1050 scans, which is double the conventional 525 scans. In addition, the step signal is in a high state in the retrace section of the horizontal deflection signal, and the vertical deflection signal (e in FIG. 3b) shows that the step signal jumps only during the high section of the step signal.

The present invention provides a step-injection step signal to maintain the interlacing method and to double the interlaced scan of the existing interlaced scan method to have a high resolution function, while maintaining the effect of the existing interlaced scan, the resolution of the TV screen is very high. An object of the present invention is to provide a step signal generation circuit, and the present invention will be described in detail with reference to the accompanying drawings.

The waveform of each part when the circuit of FIG. 1 operates is shown in FIGS. 2A and 2B, and is shown in each part of the circuit. The clamp circuit 1 binds the DC level of the composite video signal continuously. This is to stably obtain a signal as shown in (b) of FIG. 2A from the comparator 2. The output of the comparator 2 is monostable multi ( This monostable multi is applied to 3) and it has a duration of about 0.7H (H = 63.5㎲) and is retriggerable, so it provides the same output as c of FIG. This signal is applied to the retriggerable monostable mulberry 4, and the duration of this monostable multi is about 5H, resulting in an output such as d in FIG. 2a. The outputs of the monostable multistage 3 and the monostable multistage 4 have a waveform such as e in FIG. 2a at the output of the OR gate 5.

This output is applied to the reset input of the counter 6, and the coefficient value of the counter 6 shown in f of FIG. 2a reflects this.

On the other hand, a in FIG. 2a represents a composite video signal in field 1, and FIG. 2a represents a composite video signal in field 2. In addition, h in FIG. 2A is the output of the monostable multi 3 in the field 2, and i in FIG. 2A shows the count value of the counter 6 in the field 2. FIG. Here, comparing the count value (f in FIG. 2a) of the counter 6 in field 1 with the counter value (i in FIG. 2a) in the counter 6 in field 2, the counter 6 in field 1 It can be seen that the count value reaches 254, and the field 2 only reaches 253.

Therefore, field 1 and field 2 can be distinguished by checking the count value of this counter 6, and it is used to determine whether or not to insert a step pulse at the beginning of the vertical deflection signal. (I.e., as shown in d of FIG. 3a, there is no step pulse at the beginning of the vertical deflection signal in field 1, and there is a step pulse in field 2 as in f of FIG. 3a)

If the current composite video signal is field 1, the output of the NAND gate 7 appears as shown by the solid line in b of FIG. 2b, which is applied to the monostable multi-media 8 and has the same waveform as the solid line of d in FIG. To appear. This signal is applied to the CLR input of the monostable multi 9 and the vertical synchronization signal applied to the B input of the monostable multi 9 (triggered by a in FIG. 2b) is enabled.

Therefore, at the output of the monostable multi 9, a waveform such as e in FIG. 2b appears and is input to the AND gate 15 together with the output of the AND gate 14 as in c in FIG. 2b, and the same step as f in FIG. I am getting a signal. On the other hand, when the composite video signal is field 2, a waveform as shown by a dotted line in FIG. 2B appears in each circuit portion, and as a result, a vertical deflection signal such as g in FIG. 2B can be obtained.

In the vertical deflection signal shown in g of FIG. 2b, after the vertical synchronization signal becomes high, the first scan line overlaps the field 1 and the field 2, but from then on, the field 2 is continuously scanned below a certain step (horizontal deflection). The signal is always larger in field 2 by a certain step than in field 1).

On the other hand, the vertical synchronizing signal as shown in FIG. 2B compares the output of the counter 6 with the vertical synchronizing start reference signal and the vertical synchronizing end reference signal at the comparator 10 and the comparator 11, respectively, and outputs the AND gate 12. Getting in.

As described above, according to the present invention, the effect of interlacing is still applied by applying to a system for double scanning in order to increase the output resolution of a high resolution digital TV or a monitor which doubles the scanning player using a conventional TV signal. You can increase the resolution of the playback screen while saving.

Claims (1)

The output of the clamp circuit 1 to which the composite video signal is input is connected to the variable input (+) of the comparator 2 to be compared with the reference voltage Vref, and the inverted output of the comparator 2 is compared with the starting point of the vertical synchronization signal. Connect the output of the AND gate 12 with the output of the comparator 10, 11, to which the endpoint reference signal is input, to the input of the AND gate 14, and the output of the AND gate 14 to monostable multivibration. The output of the AND gate 15 is inputted to the AND gate 15 together with the output Q of (9) as a step signal, and the monostable multivibrator 4 is output to the output Q of the monostable multivibrator 3. ) And the counter 6, the common output of the counter 6 is connected to the comparators 10 and 11, and the entire output of the counter 6 is input to the NAND gate 7 so that the output of the NAND gate 7 is controlled. It is characterized by being connected to the clear input (CLR) of the monostable multivibration (9) through the monostable multivibrator (8). Step injectable step signal generator.

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