JPH02301373A - Horizontal deflection width detection circuit - Google Patents

Abstract

PURPOSE:To detect a screen size of a received picture in excellent way regardless of a change in the horizontal frequency by connecting a current source for discharge proportional to a horizontal frequency of an input video signal to a peak rectifier circuit of a horizontal deflection pulse. CONSTITUTION:A current source 5 for discharge proportional to the horizontal frequency of an input video signal connects to peak rectifier circuits 3, 4 in a horizontal deflection width detection circuit detecting the horizontal deflection width of a television receiver of the multi-scan system corresponding to plural horizontal frequencies with peak rectification of the horizontal deflection pulse outputted from a horizontal output circuit 2. Since the discharge quantity of the peak rectified value is controlled in response to the horizontal frequency, the change in the discharge is set so that the mean value of the peak rectified values is unchanged with the change in the horizontal frequency to attain it that the detected deflection width is unchanged even with a change in the horizontal frequency and no error is generated in the detection value. Thus, the deflection width of a received picture is detected in an excellent way without being affected by the fluctuation in the horizontal frequency.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a horizontal deflection width detection circuit for a multi-scan television receiver that supports a plurality of horizontal frequencies.

[Summary of the invention]

The present invention provides a horizontal deflection width detection circuit for a multi-scan television receiver that is compatible with a plurality of horizontal frequencies. The screen size of the received image can be detected well regardless of changes in the horizontal frequency.

[Conventional technology]

In recent years, multi-scan type television receivers that are compatible with video signals of a plurality of horizontal frequencies have been developed (see Japanese Patent Laid-Open No. 74463/1983). This multi-scan type television receiver maintains the horizontal deflection width of the beam constant even if the horizontal frequency changes.
The beam deflection width is detected and controlled so that the detected deflection width approaches a reference value.

In this case, the deflection width detection circuit has a configuration that performs peak rectification of the horizontal deflection pulse signal outputted by the horizontal output circuit for horizontal deflection, and detects the deflection width from the rectified value.

[Problem to be solved by the invention]

However, the method of detecting the deflection width by peak rectifying the horizontal deflection pulse has the disadvantage that when the horizontal frequency fluctuates, the detected value fluctuates, resulting in an error in the detected value. That is, assuming that the horizontal deflection pulse signal is output from the horizontal output circuit as shown by the broken line in FIG. 5, the peak rectified value P1 of this horizontal deflection pulse signal is equal to the pulse signal It changes within a certain range around the peak value of .

At this time, the average value of the peak rectification values P is set as al. For example, if the horizontal frequency of the input video signal changes to a frequency of 172, the interval between the horizontal deflection pulse signals will be doubled, so the width of change of the peak rectified value P2 at this time will be the peak rectified value P1 mentioned above. , and the average value a2 at this time becomes lower than the average value a. If the average value decreases in this way, it will be detected that the deflection width has changed even though the actual deflection width has not changed, resulting in an error in the detected value.

In particular, in recent years, the horizontal frequency of video signals is several times higher than the normal broadcasting standard (15, 75kHz, etc.)5.
If such a high-frequency horizontal frequency video signal is input, the error in detecting the deflection width will increase.

In view of the above, it is an object of the present invention to provide a circuit that can accurately detect the deflection width without error.

[Means to solve the problem]

The horizontal deflection width detection circuit of the present invention, as shown in FIG.
), a discharge current source proportional to the horizontal frequency of the input video signal [5] is connected to the peak rectifier circuits (3) and (4). This is what I did.

[Effect]

According to such a configuration, since the discharge amount of the peak rectified value is controlled according to the horizontal frequency, by setting the amount of change in the discharge amount so that the average value of the peak rectified value does not change due to a change in the horizontal frequency, Even if there is a change in the horizontal frequency, the detected value of the deflection width does not change, and no error occurs in the detected value.

〔Example〕

Hereinafter, one embodiment of the horizontal deflection width detection circuit of the present invention will be described in the first embodiment.
Let's explain with reference to FIGS.

This example is a horizontal deflection width detection circuit applied to a multi-scan type television receiver, and detects the deflection width by peak rectification of horizontal deflection pulses. First, Fig. 1 shows the basic principle of the configuration of this example. In the figure, (1) shows the horizontal synchronizing signal input terminal, and this input terminal (1) is used to input the input image to this television receiver. A horizontal synchronization signal of the signal is provided. The horizontal synchronizing signal obtained at this input terminal (1) is then supplied to a horizontal output circuit (2), and the horizontal output circuit (2) outputs a horizontal deflection pulse signal that is in phase with this horizontal synchronizing signal. This horizontal deflection pulse signal is then supplied to a horizontal deflection coil (not shown) to horizontally deflect the electron beam, and the horizontal deflection pulse signal is supplied to a circuit for detecting a deflection width.

That is, a horizontal deflection pulse signal is supplied to the anode of a diode (3), the cathode of this diode (3) is connected to one end of a charging capacitor (4), and this capacitor (
4) Ground the other end. In addition, the cathode of the diode (3) is connected to the current source (5), and the signal obtained at the cathode of this diode (3) is transmitted to the deflection width detection signal output terminal (6).
Monthly supply. Then, the deflection width is detected based on the voltage value of the signal obtained at this output terminal (6). In this case, in this example, the current value of the current source (5) is controlled from the frequency/voltage converter (7).
) is supplied with a horizontal synchronizing signal from a horizontal synchronizing signal input terminal (1) as a control signal, and the output voltage is controlled by the frequency of the horizontal synchronizing signal.

The value of the current flowing through the current source (5) is controlled by the output voltage signal of the frequency/voltage converter (7).

Therefore, depending on the frequency of the horizontal synchronization signal, this current source (5
) is controlled.

To explain the process of detecting the horizontal deflection width using such a configuration, the horizontal deflection pulse signal outputted by the horizontal output circuit (2) corresponds to the interval of the horizontal synchronizing signal, as shown by the broken line in Fig. 2. With a pulse signal, the peak rectification of the peak value of this pulse signal is performed by the diode (3) and capacitor (4).
It is carried out with. That is, the capacitor (4) is charged with this pulse signal, and the current flowing through the current source (5) becomes the discharge current of this capacitor (4).

The voltage value of the peak rectified signal obtained at the deflection width detection signal output terminal (6) is determined by the amount of discharge controlled by this discharge current. The peak rectified value P1 of the horizontal deflection pulse signal determined in this way is shown by a solid line in FIG.

For example, if the horizontal frequency of the input video signal changes to a frequency of 172, the interval between the horizontal deflection pulse signals will expand twice, and if the discharge current is constant, the average value will decrease as shown in Figure 5. However, in this example, when the horizontal frequency changes, the discharge current of the current source (5) changes in proportion to the change in frequency, as shown by the dashed line in Figure 2. Thus, the peak rectification value P3 at this horizontal frequency changes with a gentle slope. Therefore, the peak rectification value P1. By setting the amount of change in the discharge current so that the average value of P3 is constant at a, as long as the deflection width is constant, the average voltage of the output signal of the output terminal (6) due to changes in the horizontal frequency can be reduced. There is no change, and no error occurs in the deflection width detected from the output voltage of the output terminal (6).

Here, FIG. 3 shows a configuration diagram of a specific embodiment based on the principle diagram of FIG. 1. The output signal of the switching regulator (8) whose output signal changes according to the horizontal frequency is The output signal of this switching regulator (8) is supplied to one end of a resistor (11) of a current control circuit (10) as well as to a horizontal output circuit (2). The horizontal deflection pulse signal output from the horizontal output circuit (2) is then passed through the diode (3) to the charging capacitor (4).
The other end of this capacitor (4) is grounded. Then, the deflection width detection signal output terminal (6) is drawn out from one end side of the capacitor (4).

Then, the current control circuit (lO) connects the other end of the resistor (11) to ground through a series circuit of the diode (12) and the resistor (13), and connects the resistor (11) and the diode (12) to the ground.
The midpoint of the connection is connected to the base of an npn type transistor (14). The collector of this transistor (14) is connected to one end of a charging capacitor (4), and the emitter is grounded via a resistor (15) serving as a discharging resistor.

According to such a configuration, the resistor (
11) and the diode (12), a voltage signal proportional to the horizontal frequency is generated, and the transistor (14)
This voltage signal is supplied to the transistor (14), and the amount of current flowing from the collector of this transistor (14) to the discharge resistor (15) via the emitter is controlled by the voltage signal. Therefore, the discharge amount of the charging current of the capacitor (4) is controlled in proportion to the horizontal frequency, and as shown in FIG. 2, as long as the horizontal deflection width is constant, the output terminal (6)
The average voltage value of the deflection detection signal obtained in this case becomes constant, and no error occurs in the detection signal.

Note that as the control signal for the current source, another signal that changes in proportion to the horizontal frequency may be used instead of the output signal of the switching regulator shown in the example of FIG. For example, as shown in FIG. 4, the amount of discharge current may be controlled by the output signal of a frequency/voltage converter for controlling the switching regulator. That is, the horizontal synchronizing signal obtained at the input terminal (21) is sent to the frequency/voltage converter (22).
It changes into a voltage signal that changes in proportion to the frequency of the horizontal synchronization signal. And this frequency/voltage converter (
22) is supplied to one input terminal of the multiplier (23). In addition, (24) in the figure indicates a deflection control signal input terminal with a voltage proportional to the deflection width determined by the screen size to be displayed, and the deflection control signal obtained at this input terminal (24) is input to one side of the adder (26). Supplied to the input terminal of In this case, the deflection control signal is, for example, a voltage signal that becomes IV when the screen size is normal and becomes 0.5V when the screen size is half of the normal screen size. The other input terminal of this adder (26) is supplied with a difference signal output from a comparator (25), which will be described later, and adds the difference signal to the deflection control signal. And the adder (
26) is supplied to the other input terminal of the multiplier (23). And in this multiplier (23),
A voltage signal corresponding to the frequency of the horizontal synchronization signal is varied by multiplication according to the addition signal, and the multiplication signal is supplied to the switching regulator (8) as a control signal.

Then, the DC output signal outputted by this switching regulator [8] in accordance with the multiplication signal is transferred to the horizontal output circuit (2).
) as a power signal, and the horizontal synchronizing signal obtained at the input terminal (21) is supplied to this horizontal output circuit (2) to obtain a horizontal deflection pulse signal having a period based on the horizontal synchronizing signal.

In this example, the output signal of this horizontal output circuit (2) is passed through a diode (3) to a charging capacitor (
4) and the discharge current source (5). In this case, the current value flowing through the current source (5) is changed to the frequency/voltage converter (2).
Controlled by the output voltage of 2). And the capacitor (
A voltage signal obtained at the midpoint of the connection between the diode (3) and the diode (3) is supplied to one comparison signal input terminal of the comparator (25). Then, a deflection control signal proportional to the deflection width obtained at the deflection control signal input terminal (24) is supplied to the other comparison signal input terminal of comparison 1 (25), and this comparator (25)
The deflection width indicated by the control signal is compared with the actual deflection width indicated by the detection signal. Then, the difference signal output as a result of the comparison is supplied to the other input terminal of the adder (26).

To explain the operation of such a circuit, the voltage signal output from the frequency/voltage converter (22) is connected to the input terminal (21).
The signal is based on the frequency of the horizontal synchronization signal obtained. The signals added by the adder (26) are the deflection control signal obtained at the input terminal (24) and the difference signal output from the comparator (25). Here, in this comparator (25), a deflection control signal determined by the screen size obtained at the input terminal (24) and a charging potential of the capacitor (4) indicating the actual deflection state in the horizontal output circuit (17) are used. are compared. That is, the difference between the deflection width to be controlled and the actual deflection width is indicated by the difference signal output from the comparator (25). By adding this difference signal and the deflection control signal determined by the screen size in the adder (26), a deflection control signal corrected by the difference signal is obtained, and this corrected deflection control signal is supplied to the multiplier (23). Ru. Then, in the multiplier (23), the voltage signal based on the frequency of the horizontal synchronization signal is multiplied by the corrected deflection control signal to change according to the deflection width to be controlled, and this multiplied voltage signal is used for switching. The voltage signal is supplied to the regulator (8), and a power signal based on this voltage signal is supplied to the horizontal output circuit (2).

By controlling the power signal supplied to the horizontal output circuit (2) in this way, the frequency/voltage converter (12) can control the power signal proportional to the horizontal frequency of the input video signal, and the comparator ( 20), the power signal is controlled based on the difference between the actual deflection width and the deflection width according to the screen size. In this case, the current source (5) is controlled by a voltage signal proportional to the horizontal frequency output by the frequency/voltage converter (12).
Since the current value flowing through is controlled, the accurate deflection width is detected, and the difference between the reference deflection width and the actual deflection width is accurately detected by the comparator (25), and the deflection width is accurately determined. Good control. In the case of this example in Fig. 4, the current source (5) is controlled by the output voltage of the frequency/voltage converter (22) for controlling the switching regulator, so a dedicated current control signal generation means is required. This is not necessary, and the circuit configuration becomes simpler.

Furthermore, it goes without saying that the present invention is not limited to the above-described embodiments, and can take various other configurations without departing from the gist of the present invention.

〔Effect of the invention〕

According to the horizontal deflection width detection circuit of the present invention, the deflection width (i.e., screen size) of a received image can be detected satisfactorily without being affected by fluctuations in horizontal frequency. There are benefits that are suitable for machines.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram showing the principle of the horizontal deflection width detection circuit of the present invention, FIG. 2 is a characteristic diagram for explaining the example in FIG. 1, and FIG. 3 is a diagram showing an embodiment of the present invention. FIG. 4 is a configuration diagram showing another embodiment of the present invention, and FIG. 5 is a characteristic diagram for explaining a conventional example.

[1] is a horizontal synchronizing signal input terminal, (4) is a charging capacitor, (5) is a current source, and (6) is a deflection width detection signal output terminal.

Dai Rito Matsu Hide Kuma Horn horn 1 Characteristic diagram Figure 2 Characteristic diagram Figure 5

Claims (1)

[Claims] In a horizontal deflection width detection circuit that detects the horizontal deflection width of a multi-scan television receiver that supports a plurality of horizontal frequencies by peak rectification of a horizontal deflection pulse, A horizontal deflection width detection circuit characterized in that a proportional discharge current source is connected to a peak rectification circuit.