KR19990013440U - TV screen control that changes according to voice frequency - Google Patents

Abstract

The present invention relates to a television screen control apparatus that varies according to voice frequency, and more particularly, to an apparatus for varying the size of a vertical screen and a horizontal screen of a video screen when a more dynamic and stereoscopic video screen is required to be reproduced. In general PIP televisions, since the horizontal and vertical deflections of the scanning beams injected into the CRTs of the receiving tube are always performed stably, the shaking on the video screen is reduced. According to the present invention, a voice signal received from an antenna and output from a voice signal demodulation IC is increased or decreased by frequency band by a voice equalizer IC to be converted into DC data, and then applied to a microcomputer to display a screen corresponding to the DC data. The present invention proposes a device which becomes a variable control signal for changing the horizontal size data and the vertical size data, and also causes the image screen to be lopsided up, down, left and right through the deflection process of the horizontal and vertical correction ICs.

Description

TV screen control that changes according to voice frequency

The present invention relates to a television screen control device which varies according to the voice frequency. More specifically, when a dynamic and stereoscopic video screen is required to be played rather than a fixed screen among television broadcast programs, a vertical screen and a horizontal screen of a video screen are required. The present invention relates to a television screen control device which changes according to a voice frequency to enable the size of the variable to be varied.

In general, a television receives a high frequency signal transmitted from a broadcasting station through an antenna and displays it on a screen. The color light of a subject sent to an image pickup tube is divided into RGB signals and made into a YIQ signal in a matrix circuit. In order to easily separate the YIQ signal from the receiving side, the I and Q signals pass through a balance modulator, respectively, to be changed in phase, and then transmitted by mixing color burst signals, horizontal / vertical synchronization signals, and voice signals. do. The transmitted composite video signal is received through an antenna and amplified through a high frequency amplification step to increase sensitivity and selectivity, improve S / N ratio, and increase output. In addition, YIQ signals are obtained through a series of processes such as image detection step and band amplification step, and these signals are synthesized at a constant ratio and reproduced as RGB signals, respectively, and formed into scanning beams by RGB electron guns, respectively. The image transmitted from the transmitting side is displayed while scanning the RGB fluorescent surface past the aperture grille.

1 is a block diagram schematically illustrating a television having a general PIP function.

Referring to FIG. 1, a high frequency amplification process is performed on a video signal of a channel selected for display on a main screen among high frequency signals received through the antenna 10, and amplified by mixing with an oscillation frequency oscillated by the channel being tuned. A main tuner circuit 20 for converting the intermediate frequency into easy to amplify and generating a composite video signal; A main IC 70 for demodulating and outputting the composite video signal corresponding to the channel selected by the main tuner circuit 20 to be displayed on the water pipe 80; A sub-tuner circuit unit 30 for selecting a high frequency signal corresponding to a channel to be displayed on a sub-screen among the high frequency signals received through the antenna 10 and amplifying the intermediate frequency to generate a composite image signal through a series of processes; A switching unit 60 connected to the main tuner circuit unit 20 and configured to switch a composite video signal applied from the main tuner circuit unit 20 to the PIP signal processing unit 50 or the main IC 70; It is connected to the sub-tuner circuit unit 30 and the switching unit 60, and mixes all the composite image signals applied from the sub-tuner circuit unit 30 and the switching unit 60 through the switching unit 60 through the main IC ( PIP signal processing unit 50 to be applied to 70; And a signal connected to the main tuner circuit unit 20, the sub tuner circuit unit 30, the main IC 70, the PIP signal processing unit 50, and the switching unit 60 and applied from an external button unit (not shown). The main tuner circuit 20, the sub tuner circuit 30, the main IC 70, the PIP signal processor 50, and the microcomputer 40 for controlling the operation of the switching unit 60 are included.

In the television having the PIP function as described above, when the viewer selects the multi-screen mode by using the screen selection button of the button while watching a broadcast program of the television, the microcomputer 40 recognizes this and multi-screens the PIP signal processor 50. Signal is applied, the main IC 70 is applied with an OSD blanking signal corresponding to the number of multiple screens, and the switching unit 60 receives the main video signal applied through the main tuner circuit unit 20 from the PIP signal processing unit 50. ), So that only the signal applied from the PIP signal processing unit 50 is applied to the main IC 70. The main IC 70 causes the OSD screen to be displayed on the receiving tube 90 by the OSD blanking signal applied from the microcomputer 40, and the switching unit 60 is a multi-screen applied from the PIP signal processing unit 50. Since all video signals are applied to the main IC 70, the main IC 70 displays the video signals applied from the PIP signal processor 50 on the OSD screen.

In the case of the general PIP television as described above, since the horizontal and vertical deflections of the scanning beam injected into the CRT of the receiving tube are always performed stably, the shaking on the video screen can be reduced, but the motion of the video screen When a reproduction state is required (e.g., a show program, a movie program, etc.), there is a point that does not meet the above needs.

The present invention was devised to solve the above problems, and an object of the present invention is to provide a horizontal and vertical size of a video screen corresponding to a level of a received audio signal when a more three-dimensional realism and a realistic video screen are required for reproduction. SUMMARY OF THE INVENTION An aspect of the present invention provides a television screen control apparatus that varies in accordance with a voice frequency for changing data to be configured to change a display state of a video screen vertically and horizontally.

1 is a block diagram showing a television having a general PIP function;

Figure 2 is a block diagram showing a television screen control device that changes in accordance with the voice frequency according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10, 100: antenna 20, 120: main tuner circuit

30, 200: sub-tuner circuit 40, 260: microcomputer

50, 220: PIP signal processing unit 60, 160: switching unit

70, 180: Main IC 80, 500: Water pipe

140: intermediate frequency amplifier 240: synchronous separation unit

280: key input unit 300: voice signal demodulation IC

320: voice amplifier 340: speaker

360: Voice equalizer IC 380: Horizontal and vertical correction IC

400: horizontal driving unit 420: horizontal output unit

440: vertical drive unit 460: vertical output unit

480: water pipe drive

In order to achieve the above object, the present invention includes a main tuner circuit unit for converting a high frequency signal of a channel selected for display on a main screen among high frequency signals received through an antenna into an intermediate frequency that is easy to amplify; An intermediate frequency amplifier for amplifying the intermediate frequency signal outputted from the main tuner circuit into a signal suitable for display on a water pipe; A sub-tuner circuit unit which selects a high frequency signal received through an antenna and displays an image signal on a sub-screen displayed on the screen of the receiver; A switching unit connected to the intermediate frequency amplifier and configured to switch a complex video signal applied from the intermediate frequency amplifier to a PIP signal processor or a main IC; A PIP signal processing unit connected to the sub-tuner circuit unit and the switching unit and mixing all composite image signals applied from the sub-tuner circuit unit and the switching unit to be applied to the main IC through the switching unit; A voice signal demodulation IC connected to the intermediate frequency amplifier and the sub-tuner circuit, for processing and amplifying a voice signal applied from the intermediate frequency amplifier and the sub-tuner circuit; A voice amplifier receiving a voice signal from the voice signal demodulation IC and outputting the voice signal to a speaker; A voice equalizer IC connected to the voice signal demodulation IC and converting a voice signal applied from the voice signal demodulation IC to a DC data by amplifying and reducing gain for each frequency band and applying the same to a microcomputer; A horizontal and vertical correction IC connected to the micom and outputting horizontal and vertical size data of the screen according to a screen variable control signal applied from the micom and outputting the horizontal and vertical size data, respectively; A synchronization separator connected to the main IC and separating horizontal and vertical synchronization signals from the composite video signal output from the main IC and applying the horizontal and vertical synchronization signals to the horizontal and vertical correction ICs; A horizontal driver connected to the horizontal and vertical correction ICs and amplifying a horizontal screen data signal applied from the horizontal and vertical correction ICs to a signal capable of deflection driving; A horizontal output unit connected to the horizontal driver and configured to receive a horizontal deflection driving signal from the horizontal driver to generate a horizontal output current; A vertical driver connected to the horizontal and vertical correction ICs and amplifying the vertical screen data signal applied from the horizontal and vertical correction ICs to a signal capable of deflection driving; A vertical output unit connected to the vertical driver and configured to receive a vertical deflection driving signal from the vertical driver to generate a vertical output current; In addition, the present invention provides a television screen control apparatus that varies according to a voice frequency including a vertical input mode that vertically varies an image screen, a horizontally variable mode, and a key input unit that sets both vertically and horizontally variable modes.

According to the present invention, when the variable mode of the video screen is set through the key input unit, the voice equalizer IC converts the voice signal output from the voice signal demodulation IC into DC data corresponding to the frequency and outputs it to the microcomputer. A variable display signal is applied to the horizontal and correction correction ICs. The horizontal and vertical correction ICs receiving the screen variable control signal from the microcomputer change the horizontal size data and the vertical size data of the screen, respectively, and the horizontal and vertical driving parts together with the horizontal and vertical sync signals inputted from the sync separator. The horizontal driving unit and the vertical driving unit process and amplify the input signal, convert the horizontal driving unit into a horizontal deflection driving signal and a vertical deflection driving signal, and apply them to the horizontal output unit and the vertical output unit, respectively. Therefore, the horizontal output unit and the vertical output unit convert the horizontal deflection drive signal and the vertical deflection drive signal applied from the horizontal drive unit and the vertical drive unit into horizontal and vertical output currents for deflection drive of the deflection coil, and then the horizontal deflection coil and vertical deflection. When applied to the coil, the electron beam of the tube is deflected up and down and left and right to realize a rhythmic and three-dimensional screen.

2 is a block diagram showing a television screen control apparatus that varies according to a voice frequency according to the present invention.

Referring to FIG. 2, the high frequency signal received through the antenna 100 is applied to the main tuner circuit unit 120, and the main tuner circuit unit 120 of the channel tuned to display on the main screen among the high frequency signals. In addition to the high frequency amplification processing of the video signal, the channel is tuned and mixed with the oscillation frequency that is oscillated to convert it into an intermediate frequency that is easy to amplify. An intermediate frequency amplifier 140 is connected to the main tuner circuit 120, and the intermediate frequency amplifier 140 is suitable for displaying an intermediate frequency applied from the main tuner circuit 120 on the water pipe 500. Amplify to size. The switching unit 160 is connected to the intermediate frequency amplifier 140, and the switching unit 160 is connected to the main IC 180 or the PIP according to a control signal of the microcomputer 260 applied from the main tuner circuit unit 120. The switching function is applied to the signal processor 220.

The high frequency signal received through the antenna 100 is applied to the sub-tuner circuit unit 200, and the sub-tuner circuit unit 200 is applied to the sub-screen of the water pipe 500 in the high frequency signal applied from the antenna 100. For display, the corresponding channel is tuned to convert the high frequency signal into an intermediate frequency, amplify, and output a composite video signal. PIP signal processing unit 220 is connected to the sub-tuner circuit unit 200 and the switching unit 160, and the PIP signal processing unit 220 is any complex applied from the sub-tuner circuit unit 140 and the switching unit 160. The video signals are mixed and applied to the main IC 180 through the switching unit 160.

In addition, a synchronization separator 240 is connected to the main IC 180, and the synchronization separator 240 synthesizes the composite video signal on the transmission side to reproduce the same screen as the transmission side on the water pipe 500. The horizontal synchronization signal and the vertical synchronization signal sent are separated and applied to the input port I ₂ of the horizontal and vertical correction ICs 380. The audio signal demodulation IC 300 is connected to the intermediate frequency amplifier 140 and the sub-tuner circuit 200, and the voice signal demodulation IC 300 is the intermediate frequency amplifier 140 and the sub-tuner circuit 200. The intermediate frequency signal applied from the audio signal is processed and amplified in a form suitable for the output of the speaker 340 and applied to the voice amplifier 320.

A voice equalizer IC 360 is connected to the voice signal demodulation IC 300, and the voice equalizer IC 360 amplifies and decreases the gain for each frequency band of the voice signal applied from the voice signal demodulation IC 300. The data is converted into DC data and applied to the microcomputer 260. Here, the microcomputer 260 applies a variable control signal for changing the horizontal and vertical size data of the screen corresponding to the DC data to the input port I ₁ of the horizontal and vertical correction ICs 380. The horizontal and vertical correction ICs 380 receive a screen variable control signal from the microcomputer 260 to change the horizontal size data of the screen and output a horizontal sync signal from the sync separator 240. While applying to the horizontal drive unit 400 through O ₁ ), and changes the vertical size data of the screen, the vertical drive unit ( ₂ ) through the output port (O ₂ ) the vertical synchronization signal applied from the synchronization separator 240 ( 440.

In addition, a horizontal driver 400 is connected to the horizontal and vertical correction IC 380, and the horizontal driver 400 is a horizontal screen which is changed through an output port O ₁ of the horizontal and vertical correction IC 380. Amplify the data signal to enable the horizontal deflection drive and apply it to the horizontal output unit 420. The horizontal output unit 420 connected to the horizontal driving unit 400 receives a horizontal deflection driving signal amplified through the horizontal driving unit 400 and the deflection driving of the horizontal deflection coil (not shown) and the FBT (not shown). The horizontal output current for the high-voltage generating operation is generated and applied to the water pipe drive 480 to be displayed on the water pipe 500.

Meanwhile, a vertical driver 440 is connected to the horizontal and vertical correction ICs 380, and the vertical driver 440 is a vertical screen which is changed through an output port O ₂ of the horizontal and vertical correction ICs 380. Amplify the data signal to enable vertical deflection driving and apply it to the vertical output unit 460. The vertical output unit 460 connected to the vertical driver 440 receives a vertical deflection driving signal amplified through the vertical driver 440 to generate a vertical output current for vertical deflection of a vertical deflection coil (not shown). And output to the water pipe drive 48 to be displayed on the water pipe 500.

The present invention made as described above, if the viewer wants to see the screen more realistic and realistic while watching the fixed screen is switched to the mode that can change the video screen through the key input unit 280. When the variable mode of the video screen is set, a voice signal processed and amplified by the voice signal demodulation IC 300 and output to the speaker 340 through the voice amplifier 320 is connected to the voice signal demodulation IC 300. The voice equalizer IC 360 amplifies and decreases the gain for each voice frequency band and converts the result into DC data. The DC data converted by the voice equalizer IC 360 is applied to the microcomputer 260, and the microcomputer 260 receives a screen variable control signal for changing the horizontal and vertical size data of the screen corresponding to the DC data. It is applied to the input port I ₁ of the horizontal and vertical correction ICs 380. Here, the horizontal and vertical correction IC 380 receiving the screen variable control signal from the microcomputer 260 is a synchronization separator through an input port I ₂ and a data signal for changing the horizontal and vertical size data of the screen. The vertical synchronization signal and the horizontal synchronization signal applied from the 240 are output to the horizontal driver 400 and the vertical driver 440 through the output port O ₁ and the output port O ₂ , respectively. Accordingly, the size data signal and the synchronization signal of the variable screen output from the horizontal and vertical correction ICs 380 are reproduced with the horizontal driving unit 400 to reproduce the image transmitted from the transmitter as it is and to perform the rhythmic screen. The vertical drive unit 440 is amplified to the magnitude of the deflectable drive signal and converted into a horizontal deflection drive signal and a vertical deflection drive signal, while the deflection drive of the deflection coils through the horizontal output unit 420 and the vertical output unit 460. After converting the horizontal output current and the vertical output current for the applied to the horizontal deflection coil and the vertical deflection coil to deflect the electron beam of the water pipe 500 up and down and left and right to implement a rhythmical screen.

As can be seen from the above description, when the present invention needs to be displayed in a stereoscopic and rhythmic screen state rather than in a fixed screen state, the voice equalizer IC is a frequency band of the audio signal output from the voice signal demodulation IC. The gain is increased or decreased for each DC to convert to DC data and applied to the microcomputer. The microcomputer applies the variable control signal to the horizontal and vertical correction ICs to change the horizontal and vertical size data of the screen corresponding to the DC data. Let's do it. Accordingly, the variable data signal of the screen size output from the horizontal and vertical correction ICs is converted into a horizontal deflection drive signal and a vertical deflection drive signal through a horizontal drive unit and a vertical drive unit, and a deflection coil through the horizontal output unit and the vertical output unit. After converting the horizontal output current and the vertical output current for deflection driving of the device, it is applied to the horizontal deflection coil and the vertical deflection coil so that the electron beam of the water pipe is deflected vertically and horizontally so that the screen is changed vertically and horizontally to make the screen more rhythmic and three-dimensional. Has a regenerating effect.

Claims (3)

A main tuner circuit unit 120 and a sub tuner circuit unit 200 for receiving a high frequency signal through the antenna 100; An intermediate frequency amplifier 140 for amplifying the intermediate frequency signal output from the main tuner circuit unit 120 into a signal suitable for display on the water pipe 500; A switching unit 160 for switching a complex image signal applied from the intermediate frequency amplifier 140 to the PIP signal processing unit 220 or the main IC 180; A PIP signal processing unit 220 for mixing the composite video signal applied from the sub-tuner circuit unit 200 and the switching unit 160 to be applied to the main IC 180 through the switching unit 160; In a television having a PIP function comprising a voice signal demodulation IC (300) for processing and amplifying a voice signal applied from the intermediate frequency amplifier (140) and the sub-tuner circuit (200), A voice equalizer IC 360 for adjusting the gain of the voice signal from the voice signal demodulation IC 300 for each frequency band and converting the gain into DC data to the microcomputer 260; Horizontal and vertical correction ICs 380 for changing the horizontal and vertical size data of the screen according to the screen variable control signal applied from the microcomputer 260 and outputting them to the horizontal driver 400 and the vertical driver 440, respectively; A synchronization separator 240 for separating horizontal and vertical synchronization signals from the composite image signal output from the main IC 180 and applying the horizontal and vertical synchronization signals to the horizontal and vertical correction ICs 380; A horizontal driver 400 for amplifying the horizontal screen data signal applied from the horizontal and vertical correction ICs 380 to a signal capable of deflection driving; A horizontal output unit 420 receiving a horizontal deflection driving signal from the horizontal driving unit 400 and generating a horizontal output current; A vertical driver 440 for amplifying the vertical screen data signal applied from the horizontal and vertical correction ICs 380 to a deflectable drive signal; A vertical output unit 460 for receiving a vertical deflection driving signal from the vertical driver 440 to generate a vertical output current; And a key input unit (280) for setting a vertical variable mode for vertically varying a video screen, a horizontally variable mode, and a vertically and horizontally variable mode. The method of claim 1, wherein the microcomputer 260 generates a control signal for changing only the horizontal size of the image screen to the horizontal and vertical correction ICs 380 when the variable mode for the horizontal screen is set through the key input unit 280. Television screen control device that varies according to the voice frequency, characterized in that. The method of claim 1, wherein the microcomputer 260 generates a control signal for changing only the vertical size of the video screen to the horizontal and vertical correction IC 380 when the variable mode of the vertical screen is set through the key input unit 280. Television screen control device that varies according to the voice frequency, characterized in that.