KR100215392B1 - Circuit for controlling vertical blanking - Google Patents

Abstract

The present invention relates to a circuit for blanking an overscan area when receiving an image signal having a wide vision aspect ratio from a general aspect ratio TV and going to a matching mode of aspect ratio, in particular, initialized and inputted by a vertical synchronization signal. Up-counting the horizontal synchronous signal and outputting the counting value. When the counting mode change signal is input, the up / down counter down counting from the current counted value and the horizontal synchronous signal input to the up / down counter are set. It is initialized by a carry signal generated after counting up to a predetermined threshold, and stores an up counter that provides the carry signal as a counting mode switching signal of the up / down counter, and a threshold value for an area to which vertical blanking should be attempted. The adjustment data storage unit and the car output from the up / down counter. A comparison unit for inverting and switching the current output signal state in the same case compared to the counter value and data provided from the adjustment data storage unit, and any one of a blanking signal and a video signal according to the state of the signal output from the comparison unit It relates to a vertical blanking adjustment circuit comprising a switch for selecting and transmitting to the image processing unit.

Description

Vertical blanking adjustment circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device for displaying a screen when an aspect ratio is matched. In particular, the present invention relates to an aspect ratio of an image and a screen when a video signal having a 16: 9 aspect ratio is received or input from a television broadcast receiver having a 4: 3 aspect ratio. It relates to a vertical blanking adjustment circuit for preventing the display of overscan when applying an aspect ratio fitting method to eliminate matching.

In general, since a problem aspect ratio of a conventional television is 4: 3, a technique proposed for solving a problem such as lack of a sense of reality is a television having an aspect ratio of 16: 9.

Since the aspect ratio of the television is 16: 9, it is also commonly referred to as a wide TV. When a conventional TV signal of 4: 3 is received, the aspect ratio is not correct so that the screen is compared with the display state of a signal having a normal 16: 9 aspect ratio. Distortion occurs.

On the contrary, even when an aspect ratio of 16: 9 is received on a general TV having an aspect ratio of 4: 3, a distortion of the signal occurs because the aspect ratio and the image ratio do not coincide with each other. As shown, the display area of the upper part and the lower part of the general TV is reduced so that an image having an aspect ratio of 16: 9 can be displayed.

However, in the case of viewing on a normal wide TV as in the areas indicated by reference numerals A and B in FIG. 1B, there is an area in which an image signal is present but is not actually seen. Such an area is called an overscan. Since the screen of this area is a part which is likely to cause deterioration of the actual screen, when overscan occurs, there is a high probability that deterioration will occur at this moment, which causes a problem of low user reliability.

An object of the present invention for solving the above problems is to solve the mismatch between the image and the screen when a video signal having a 16: 9 aspect ratio is received or input from a television broadcast receiver having an aspect ratio of 4: 3. It is to provide a vertical blanking adjustment circuit to prevent the display of overscan when applying the aspect ratio adjustment method.

1A and 1B are exemplary diagrams for describing an operation example and a problem when the aspect ratio adaptation method is applied.

2 is an exemplary configuration diagram of a vertical blanking adjustment circuit according to the present invention.

A feature of the present invention for achieving the above object is, in the circuit for blanking the overscan area when receiving a video signal having a wide vision aspect ratio from the normal aspect ratio TV and proceeds to the matching mode of the aspect ratio, It is initialized by the vertical synchronization signal and up counts the input horizontal synchronization signal to output the counting value. When the counting mode change signal is input, the up / down counter which counts down from the current counted value and inputs to the up / down counter Up-counter and vertical blanking which are initialized by a carry signal generated after counting up to a predetermined threshold and receiving the horizontal synchronization signal, and providing the carry signal as a counting mode switching signal of the up / down counter. An adjustment data storage that stores a threshold for the area to be attempted; A comparison unit for inverting and switching the current output signal state in the same case compared to the counter value output from the up / down counter and the data provided from the adjustment data storage unit, and according to the state of the signal output from the comparison unit And a switch for selecting one of a blanking signal and a video signal and transferring the selected signal to the image processor.

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

FIG. 2 is an exemplary configuration diagram of a vertical blanking adjustment circuit according to an embodiment of the present invention, in which an image signal having a 16: 9 aspect ratio is received and initialized by a vertical synchronous signal (V.sync) when the image signal has a matching mode, and is inputted An up / down counter 100 for counting up a horizontal synchronization signal (H.sync) and outputting a counting value and counting down from a current counting value when a counting mode change signal is input, and the up / down counter 100 ) Is initialized by a carry signal (C) generated after receiving a horizontal sync signal (H.sync) input to the predetermined threshold value, and converts the carry signal (C) to the up / down counter ( An up counter 200 provided as a counting mode switching signal of the control unit 100, an adjustment data storage unit 400 storing a threshold for an area to be attempted for vertical blanking, and an output from the up / down counter 100. felled Any one of a blanking signal and a video signal according to the state of the signal output from the comparator 300 and the comparator 300 for inverting and switching the current output signal state in the same case compared to the counter value and the data provided. And a switch (SW) for selecting and outputting a signal, and an image processor (500) for displaying a signal output from the switch (SW) on a screen.

Looking at the preferred operation of the vertical blanking adjustment circuit according to the present invention operating as described above are as follows.

First, in a typical NTSC TV having a 4: 3 aspect ratio, 262.5 horizontal synchronization signals are generated within a vertical synchronization signal cycle. However, only 198 horizontal synchronization signals are required to form a 16: 9 aspect ratio.

Therefore, blanking signal processing should be performed on the areas corresponding to the first to thirty-second horizontal synchronous signal portions and the 231 to 262 th horizontal synchronous signal portions.

Therefore, the data 32 is stored in the adjustment data storage 400.

The up / down counter 100 is initialized when the vertical synchronization signal V.sync is input and then counted by receiving the horizontal synchronization signal H.sync among the input video signals, and counted by the counter 100. Is input to the comparator 300. The comparison unit 300 determines whether the value 32 output from the adjustment data storage unit 400 and the input counting value are the same.

In this case, it is assumed that the state of the signal output from the comparator 300 has a low state in the initial state, and the switch SW transmits a blanking signal to the image processor 600 while the low state signal is input. Assume In addition, the comparison unit 300 compares the counter value output from the up / down counter 100 and the data provided from the adjustment data storage unit 400 to invert and switch the current output signal state in the same case. do.

When the value of counting the horizontal synchronization signal (H.sync) in the up / down counter 100 is 32, the comparator 300 is the same as the data provided from the adjustment data storage unit 400 and thus the current low state. The state of the output signal held is switched to the high state. Therefore, the switch SW blocks the blanking signal that is currently transmitted to the image processor 600 and transmits the video signal.

In this case, the up / down counter 100 continuously performs an up counter function until a counting mode switch signal is input, and inputs a horizontal synchronization signal (H.sync) input to the up / down counter 100. The up counter 200 that receives and counts the carry signal C generated after counting up to a predetermined threshold value, that is, 131, is provided as a counting mode change signal of the up / down counter 100. In addition, the up counter 200 is cleared by the carry signal C generated by the up counter 200. In addition, the up counter 200 is also cleared by the vertical synchronization signal (V.sync).

The up / down counter 100 in which the counting mode is switched by the carry signal C generated by the up counter 200 counts an incoming horizontal sync signal (H.sync), at 131 previously counted. Perform the function of decrementing down counter. Accordingly, when the signal output from the up / down counter 100 gradually decreases to reach 32, the comparator 300 switches the output signal, which is currently kept high, to a low state.

Therefore, the switch SW cuts off the video signal that is currently transmitted to the image processor 600 and transmits a blanking signal.

Providing the vertical blanking adjustment circuit according to the present invention operating as described above, it is possible to prevent the phenomenon that the overscan portion that is likely to cause degradation during the aspect ratio adjustment operation is displayed.

Claims (4)

A circuit for blanking an overscan area when a video signal having a wide vision aspect ratio is received from a TV having a general aspect ratio and proceeding to a matching mode of aspect ratio, It is initialized by the vertical synchronization signal (V.sync) and up counts the input horizontal synchronization signal (H.sync) to output the counting value. When the counting mode change signal is input, the counting value is counted down from the current counting value. A counter 100; The carry signal (C) is initialized by the carry signal (C) generated after counting the horizontal sync signal (H.sync) input to the up / down counter (100) to a predetermined threshold. An up counter 200 for providing a counting mode switch signal of the up / down counter 100; An adjustment data storage unit 400 which stores a threshold for an area to which vertical blanking should be attempted; A comparison unit (300) for inverting and switching the current output signal state in the same case in comparison with the counter value output from the up / down counter (100) and the data provided from the adjustment data storage unit (400); And And a switch (SW) for selecting any one of a blanking signal and a video signal according to the state of the signal output from the comparator (300) and transferring the selected signal to the image processing unit (500). The vertical blanking adjustment circuit of claim 1, wherein the counting threshold of the up counter is 131. The vertical blanking adjustment circuit of claim 1, wherein the up counter is initialized by a vertical synchronization signal. The vertical blanking adjustment circuit of claim 1, wherein the threshold value stored in the adjustment data storage unit is 32. 3.

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