KR920007378Y1 - Circuit for controlling picture size when power is turned on and off - Google Patents

Abstract

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Description

Screen size control circuit when power on / off

1 is a conventional video signal processing block diagram.

2 is a video signal waveform diagram in which the size of the screen is controlled according to the present invention.

3 is a circuit diagram of one embodiment of the present invention.

4 is a control signal waveform diagram of muting the horizontal period video signal of the time pulse generator shown in FIG.

* Explanation of symbols for main parts of the drawings

1: Preamplifier 2: VIF Integrated Device

3: buffer 4: time pulse generator

5: micom 6: time delay circuit

Q1, Q2: transistor

The present invention relates to a screen size control circuit for power on / off to change the size of the screen when power on / off in an image device for displaying a video screen. This allows the complete picture to be displayed and when the power is "off", the screen is gradually reduced in size and the final power is "off".

Conventionally, as shown in FIG. 1, the IF signal amplified and output from the IF preamplifier 1 is input to the VIF integrated device 2 and output as a composite video signal, and output from the VIF integrated device 2. Since the signal is output to the signal processing circuit through the buffer 3, only a simple on / off operation is performed in which the composite video signal described above is output or cut off at the time of power on / off.

Therefore, when the power is "on" suddenly the entire screen is displayed to the size of the CRT, when the power "off" suddenly disappears the entire screen of the CRT, so the appearance or disappearance of the screen is suddenly made at a glance It was annoying.

In other words, in the conventional video device, it could not be performed outside the simple function of making the screen appear or disappear when power on / off. However, by muting the audio signal during power on / off, the generation of pop noise was minimized.

In view of the above, the present invention allows the screen size to be gradually enlarged when the power is "on" so that the full size screen is displayed and the power is "off" so that the sudden change of the screen generated when the power is turned on / off is possible. It can be eliminated.

When the present invention as described in detail by the accompanying drawings as follows.

3 is a circuit diagram of an embodiment of the present invention, in which an IF output of a preamplifier 1 is processed as a composite video signal in a VIF integrated device 2 and then output through a buffer 3, wherein the VIF integrated device The transistor Q1, which is connected to the output side of (2) and mutes the composite video signal applied to the buffer 3, and the power control signal rev change of the microcomputer 5 are checked to determine the image based on the horizontal and vertical sync pulses. A time pulse generator 4 for applying a control signal for increasing and decreasing a display section to the transistor Q1 and a power "off" control signal of the microcomputer 5 are delayed for a predetermined time and applied to a power control relay. It is composed of a time delay circuit (6).

Here, the buffer 3 to which the composite video signal is applied in the VIF integrated device 2 is a well-known block composed of a coupling capacitor C1, a buffer amplifying transistor Q2, and a noise removing capacitor C3. The control signal of the pulse generator 4 has a very small level limiting resistor R2 and its capacity so small that the level limiting resistor R2 of the control signal and its capacity are very small to remove instantaneous noise when the level of the control signal changes. It is configured to be applied to the transistor Q1 through the capacitor C2.

The power control signal of the microcomputer 5 is configured to control the driving of the power control relay after the time delay circuit 6 composed of the diodes D1, D2, the resistor R4, and the capacitor C4. The circuit 6 is configured to output the power "on" control signal of the microcomputer 5 without a time delay and the power "off" control signal is delayed during the discharge time of the capacitor C4.

Look at the effect of the present invention configured as described above.

In the conventional imaging device, when the IF output amplified by the IF preamplifier 1 is input to the VIF integrated device 2, the composite video signal is output from the VIF integrated device 2 so that the buffer 3 composed of the transistor Q2 is opened. In the present invention, a mute transistor (Q1) is connected to the composite video signal output terminal of the VIF integrated device (2) and then applied to the final signal processing circuit. The driving of the transistor Q1 is controlled to mute the composite video signal output supplied from the VIF integrated device 2 to the buffer 3 so that the size of the screen gradually increases or decreases during power on / off.

First, the microcomputer 5 of the present invention recognizes the power key pressing of a key matrix (not shown) and outputs the high level to the power terminal when the power is "on" and outputs the low level when the power is "off". The power control signal is changed from the low level to the high level when the power is "off" and the power control signal is changed from the high level to the low level when the power is "off".

The power control signal of the microcomputer 5 is applied to the time pulse generator 4 so that its level change is checked, and the time pulse generator 4 checks the level change of the power control signal (i.e., power "on" or power "). Off "), a control signal for increasing or decreasing the image display section on the basis of horizontal and vertical synchronization pulses is output over a predetermined time.

That is, when the power control signal is changed from the low level to the high level when the power is "on", the time pulse generator 4 recognizes this and outputs a control signal for increasing the image display interval based on the horizontal sync pulse, while generating a vertical sync pulse. As a reference, a control signal for increasing an image display section is output.

For example, when power is on, the control signals of (A) → (B) → (C) → (D) in FIG. 4 are sequentially outputted over a predetermined time so as to increase the image display section of the horizontal line. On the other hand, a control signal such as (A)? (B)? (C)? (D) in FIG.

At this time, the control signal output from the time pulse generator 4 is at a high level, and the transistor Q1 is "turned on" to mute the composite video signal output of the VIF integrated device 2 so that nothing appears on the screen. If the control signal output from (4) is at low level, transistor Q1 is " turned off " to output the composite video signal output of VIF integrated device 2 to buffer 3 so that the control signal is at low level. Will be displayed normally.

Therefore, when the power is "on", as shown in (A) of FIG. 4, the control signal is output at a high level, and then a low level is output to some extent, and then the high level is output again. By increasing the low-level section as shown in (B)-(C)-(D) of 4 degrees, the display operation on the horizontal line of the image is displayed while the screen is slightly displayed from the middle and then gradually increases in size.

In addition, by outputting a control signal as described above with respect to the vertical line, the display range is gradually increased from the middle of the screen.

On the other hand, when the powder is "off", the size of the lower surface is gradually reduced in the opposite concept.

The control signal of the time pulse generator 4 is applied to the base of the transistor Q1 through the resistor R2 and the capacitor C2, where the resistor R2 is used for level limiting and the capacitor C2 is a time pulse. At the instant of the level change of the control signal output from the generator 4, the ringing phenomenon appears on the actual screen.

Therefore, the driving of the transistor Q1 is controlled by the control signal level of the time pulse generator 4, and the period in which the control signal of the time pulse generator 4 is output at a high level capable of "turning on" the transistor Q1. In this case, transistor Q1 is " turned on " to mute the composite video signal output from VIF integrated device 2 so that it does not appear on the screen and the control signal of time pulse generator 4 cannot turn on transistor Q1. In the section outputting at the low level, the transistor Q1 is " turned off " so that the composite video signal is output through the buffer 3 so that the screen is normally displayed.

Therefore, the longer the period during which the control signal output of the time pulse generator 4 is output at the low level for displaying the screen, the larger the screen displayed through the buffer 3 becomes.

That is, if the control signal generated by the time pulse generator 4 at the power "on" is the same as in (A) of FIG. 4, the video signal displayed on the screen is displayed in FIG. If only a part is displayed as shown in FIG. 4 and the control signal is as shown in (B) in FIG. 4, the video signal is displayed in a slightly larger screen as in ④ of FIG. Gradually increasing from the slightest, the final screen is displayed in full screen.

When the power is turned on, the time pulse generator 4 generates a control signal for increasing the low level in the order of (A)-(B)-(C)-(D) in FIG. (Q1) is driven so that the video signal is muted only in the high level section of the control signal, so the video signal finally displayed on the screen is displayed in the order of ③ → ④ → ⑤ of FIG. As the size gets smaller, the full screen is displayed.

When the power is "off", the reverse operation is performed to reduce the size of the screen gradually and then to "off" the power.

When the power is "off", the power control signal of the microcomputer 5 is output at a low level and is applied to the time pulse generator 4, so that the control pulse is controlled by the time pulse generator 4 (D) → (C) → The output is from (B) → (A).

Therefore, the period during which the transistor Q1 is " turned off " gradually decreases, and the video signal output through the buffer 3 is output in the order of? → ② → ③ in FIG. You lose.

At this time, the power "off" signal output from the microcomputer 5 is delayed by the time delay circuit 6, and then the size of the screen is completely reduced. Then, the power control relay is "off". Off ".

That is, when the power control signal of the high level is output from the microcomputer 5 when the power is "on", it drives the power control relay through the diode D1 of the time delay circuit 6 to supply the main power and at the same time the capacitor C4. ) Will be charged.

Therefore, when the power is turned on, the main power is immediately turned on, and the set is normally operated, but the screen size is gradually increased by the control signal of the time pulse generator 4.

However, when the power control signal of low level is output from the microcomputer 5 when the power is "off", if there is no time delay circuit 6, the main power supply is cut off immediately and it cannot indicate that the screen size is reduced. In this case, when the low-level power control signal is applied, it is delayed for a certain time so that the main power of the set is “off” after a certain time has elapsed since the power-off key is pressed.

That is, when the low-level power control signal is applied, the power control relay is operated during the discharge time of the capacitor C4 so that the main power continues to flow and the main power is cut off when the discharge of the capacitor C4 ends. During the delay time of the circuit 6, the size of the screen is gradually reduced.

As described above, the present invention outputs a smaller screen size when powering "on" to gradually increase to a full screen, and gradually reduces the size of the complete screen when powering "off" to completely remove the screen and finally " It is possible to add a new function when the power of the video device on / off and suddenly the screen appears and disappears to eliminate the phenomenon of visual rejection.

Claims (1)

In an image device in which the IF output of the preamplifier 1 is output through the buffer 3 as a composite video signal through the VIF integrated device 2, connected to the output side of the VIF integrated device 2 and the buffer 3 Transistor Q1 for muting the composite video signal applied to the control signal, and a control signal for increasing or decreasing the image display section over a predetermined time based on horizontal and vertical sync pulses by checking the power control signal level change of the microcomputer 5. A time pulse generator 4 to be applied to the transistor Q1 and a time delay circuit 6 to delay the power " off " control signal of the microcomputer 5 to a power control relay for a predetermined time. Characterized in the size of the screen when the power on / off control circuit.