KR100218417B1 - Image compensation circuit for a television - Google Patents

Abstract

The present invention provides an image compensation circuit for compensating for a signal lost in the vertical direction due to a different aspect ratio when the current NTSC standard TV signal is displayed in full width in an HD (High Definition) TV display. In the related art, when the current NTSC standard TV signal which can also display the current NTSC standard signal is displayed with full aspect width when the current NTSC standard TV signal is displayed in full width, the vertical direction is lost. If there is a mark, there is a problem that the mark is not visible.

Accordingly, in view of the above-described deficiencies, the present invention provides a current NTSC standard TV signal in accordance with the width of the HDTV display in an HDTV display capable of displaying a signal of a current NTSC standard TV system having a different aspect ratio from that of an HDTV system. When displayed, the area of the image signal lost above and below the screen can be displayed on the HDTV display by moving or compressing the display size in the screen using a memory.

Description

Image Compensation Circuit

1 is an image processing circuit diagram of a conventional HDTV.

2 is a front view of the current NTSC standard TV displayed on the HDTV display.

3 is an image compensation circuit diagram of the present invention.

4 is a front view showing an image display state according to the present invention.

* Explanation of symbols for main parts of the drawings

4: aspect converter 7: DC divider circuit

8: analog / digital converter 9: synchronization separator

10: comparison unit 11, 18: switching switch

12-14: memory 15: memory control unit

19: digital / analog converter

The present invention relates to an image compensating circuit in a TV (TV) receiving method. In particular, when the HD (High Defintion) display displays the current NTSC standard TV signal full width and width on the display, the aspect ratio is different, so An image compensation circuit is provided for compensating for a lost signal.

Currently known HDTV is a MUSE method proposed by Japan's NHK, as compared with the current NTSC method.

Therefore, although HDTV and NTSC TV are incompatible with each other, macroscopically, HDTV is not a substitute for the current NTSC standard TV, but both TV systems will be covered for some time. Therefore, there is a need to receive and display the current NTSC standard TV image even in HDTV display.

FIG. 1 is an image processing circuit diagram of a conventional HDTV, wherein a TV signal input through an NTSC standard TV signal input terminal 1 is scanned converted by the scan converter 3, and the scan converted signal is converted into an aspect converter 4 The signal converted into the aspect suitable for the current NTSC standard TV screen is converted, and the signal converted from the scan converted signal and the aspect signal by the switching switch (SW1) is displayed together with the signal input through the HDTV signal input terminal (2). is switched by a change-over switch (SW _2), the screen change-over switch CPT (which is processed by the signal processing unit 5 in order to increase the NTSC standard TV signal or picture quality of the HDTV signal by a switching (SW ₂₎ processes the image Color It is configured to be displayed on Picture Tube.

In the circuit configured as described above, the scan conversion section 3 performs the scan conversion on the NTSC standard TV signal applied through the current NTSC standard TV signal input terminal 1, and the signal is made to be the screen as shown in FIG. Is converted, and the aspect conversion unit 4 converts the scan-converted signal to the screen as shown in FIG.

The scan conversion signal or the aspect conversion signal switched through the switching switch SW1 together with the HDTV signal applied through the HDTV signal input terminal 2 is the TV signal switched by the screen switching switch SW2 as the signal processing unit 5. Through signal processing to increase the quality of the image through the CPT (6) is displayed.

However, in the HDTV display that can display the current NTSC standard signal, the aspect ratio is different when the current NTSC standard TV signal is displayed with the width of (c) of FIG. If there is a wood (Super Impose) display, there is a problem that the display is not visible.

In view of such a conventional deficiency, the present invention provides a super impose display that is lost at the top and bottom of the screen when the current NTSC standard TV signal is also displayed on an HDTV display capable of displaying the current NTSC standard TV signal. An image compensating circuit has been created that can be viewed by moving within a screen or by compressing a display size. The following description will be given with reference to the accompanying drawings.

3 is an image compensating circuit diagram of the present invention, as shown here, a DC-dividing regeneration circuit section 7 for cladding NTSC standard TV signals signal-converted by the aspect changing section 4 to perform direct-current regeneration processing; An analog / digital converter 8 for converting a DC signal reproduced into a digital signal, and a comparison unit for comparing the synchronous signal separated by the synchronous separator 9 with a reference voltage VREF according to the DC reproduced signal ( A timing generator 16 for generating a timing signal according to the output signal of 10) and an output of the analog / digital converter 8 are switched and selectively stored in the memories 12, 13, and 14 A first switching switch 11 to be selectively stored in the memory 12, 13, and 14, the first switching switch 11, and memory 12, 13, and ( A second switching switch 18 for selectively outputting the output of the switch 14, the switching switch 11, A memory control unit 15 for switching the connection of 18 and controlling the timing of read and write to the memories 12, 13, and 14, and the second switch. And a digital / analog converter 19 for converting the digital signal of the switch 18 into an analog signal and outputting it to the screen switching switch SW ₁ .

Referring to the operation, effects of the present invention configured as described above in detail. It is assumed that the signal output from the aspect converter 4 has a super impose indication in the range of the interval d as shown in FIG. 4, and the signal is supplied to the DC divider circuit 7 to supply a direct current. The reproducing process is performed and digitized by the analog / digital converting section 8 and supplied to the digital / analog converting section 19 through the contact 2 → 1 of the second switching switch 18.

First, a signal whose scan of the current NTSC standard TV signal is 4: 3 in the first field as a method for compensating the superimposed 2 lost at the bottom in the vertical direction with the modified superimposed 23 in FIG. Scanning is performed sequentially starting at section a of FIG. 4, which is the region 20, and the second switching switch 18 maintains the contact 2-> 1 state until the end point of section c is reached. Next, when the scan of the current NTSC standard TV signal enters the range d, the output of the comparator 10 becomes high when the signal amplitude level by the super impose display is greater than or equal to the reference value VREF of the comparator 10. .

When the timing generator 16 is driven according to the high signal of the comparator 10, the memory controller 15 is driven as a timing signal so that the current NTSC standard TV signal of the d section is connected to the 1-2 contact of the first switch. To write to the memory 12. At this time, even if the scanning of the current NTSC standard TV signal enters the d section, the second switching switch 18 maintains the state of electricity. This completes the scanning of the first field.

In the second field, when the scanning of the current NTSC standard TV signal returns to the range of section a in FIG. 4, the second switching switch 18 maintains the electric state, but the current NTSC standard TV signal area 20 and the HDTV. As the signal region 21 is different, that is, the aspect ratio is different, the section a is not displayed on the screen. The control of the switching switch is performed by counting the synchronous pulses separated by the synchronization separating unit 9 by the timing generating unit 16 to detect the dice of the current NTSC standard TV signal and controlling the memory control unit 15 to control the switching switch. To control.

Even in the range of section b, the second switching switch 18 maintains the state of electricity, and when the scanning of the current NTSC standard TV signal enters the range of section c, the memory controller 15 issues a command of the microcomputer 17. ) Controls the second switching switch 18 to connect the fixed contact 3 and the movable contact 1 to read the d section image in the first field stored in the memory 12 to convert the digital / analog converter ( 19).

Therefore, as shown in FIG. 4, the display of the super impose (9 home appliance laboratories) recorded during the first field scan in the range c is displayed as the super impose 23 changed.

Next, when the current NTSC standard TV signal is moved in the d section, the movable contact 1 of the second switching switch 18 is switched to the fixed contact 2 so that the image signal from the analog / digital conversion unit 19 is changed. Is supplied to the digital-to-analog converter 19. On the other hand, without changing the connection state of the first switching switch 11, the current NTSC standard TV signal of the d section range is written to the memory 12, and the scanning of the second field is finished.

Likewise repeated, the superimposed indication in the d section is displayed in the c section.

Second, if there is a horizontally filled super impose indication, a method for compressing the super imposes 24 lost in the vertical direction up and down and compensating them with the compressed super imposes 25 is described in the first field. When the dice of the TV signal are within the e section of the a section, the movable contact 1 is connected to the fixed contact 2 of the second switch 18, and the digitized signal is converted into a digital / analog converter 19. Supplied to.

Next, the scanning of the current NTSC standard TV signal is moved to the range of f section, and the level of the image signal by the super impose display is detected to be higher than or equal to the predetermined value by comparison with the reference value VREF of the comparator 10. The movable contact 1 of the one-switch switch 11 is connected to the fixed contact 3, and is written into the memory 13 every time the scan of the current NTSC standard TV signal comes in the f section.

In this operation, the scanning of the current NTSC standard TV signal continues the first field scan until the end of the d section.

In the second field, when the scanning of the current NTSC standard TV signal returns to the range of section a on the screen and enters the range of section f, the memory control unit 15 causes the movable contact 1 of the first switching switch 11 to be changed. ) Is connected to the fixed contact point 4, and is written into the memory 14 each time a scan of the current NTSC standard TV signal comes in the f section. This operation continues scanning of the current NTSC standard TV signal to the end of the d section. At this time, the movable contact 1 of the second switching switch 18 is in a state connected to the stationary contact 2.

In parallel with this, when the scanning of the current NTSC standard TV signal is to be made from the b and c sections to the f section, the movable contact 1 of the second switching switch 18 is fixed by the memory control unit 15. The contents of the memory 13 recorded by the current NTSC standard TV signal during scanning of the first field are read.

The read content starts at the same time as the scan enters the f section in synchronization with the scan of the current NTSC display TV signal of the input, and the scan ends at the end of the range of the f section and enters the range of the e section. The movable contact 1 of the switching switch 18 is connected to the fixed contact 2 so that the image signal of the output of the analog / digital converter 8 is supplied to the digital / analog converter 19.

In the memory 13, image signals corresponding to the sections a, b, c, and d of the 525/2 lines of the first field are recorded. Therefore, the display area covering the sections a, b, c, and d is provided. In order to change the display area of section b and section c by compression, the scanning line is selected one by four lines, and the longitudinal length of the image is set to 3/4, and the scanning of the current NTSC display TV signal enters the range of section d. At this time, the movable contact 1 of the second switching switch 18 is connected to the stationary contact 2.

In this way, the second field scan is finished and the third field scan is entered. At this time, the memory 14 replaces the signal lead memory of the superimposed display portion.

By repeating the above operation, the display area is changed.

As described in detail above, the present invention moves or displays the size of the super impose display lost on the screen in the horizontal direction when the current NTSC standard TV signal is displayed on the HDTV display capable of displaying the current NTSC standard TV signal. It has the effect of making it visible by compression.

Claims (1)

DC splitting circuit 7 for clamping the NTSC standard TV signal converted by the aspect converting part 4 to perform direct current reproduction, and analog / digital converting unit for converting the DC reproduced analog signal into a digital signal. (8) and a timing generation REF unit for generating a timing signal in accordance with the output signal of the comparator 10 comparing the synchronous signal separated by the synchronous separation section 9 with the reference voltage VREF in accordance with the DC reproduced signal. (16), a first switching switch (11) for switching the output of the analog-to-digital converter (8) to selectively store in the memory (12), (13), (14), and the memory (12). 2) switch (18) for switching the outputs of the (13), (13) and (14) to selectively output the memory 12, and at the same time switching the connection of the switch (11), (18) A memory controller 15 for controlling the timing of read writes for each of (13) and (14), and the second And it converts the digital signal of the switch ring (18) into an analog signal switching switch screen image correction circuit, characterized by consisting of a (SW _1), a digital / analog converter 19 for output to.