JPH07303242A - Television receiver - Google Patents

Abstract

PURPOSE:To provide a television receiver which can suitably conduct display for video software of various aspect ratios. CONSTITUTION:A valid information detection means 100 detects a non-picture part in the unit of a scanning line. The non-picture part detection is conducted in a black band detection means 110 and a vertical edge detection means 120. They judge the non-picture part in the unit of the scanning line and supply the scanning line from which a matched detection signal can be obtained to an aspect ratio calculation means 200 as the start scanning line and the termination scanning line of a valid pictuer area. In the aspect ratio calculation means 200, a reference aspect ratio expecting an overscan area is previously set, and comparison is conducted. When the detected aspect ratio is long sideways compared with the reference aspect ratio, horizontal amplitude is extended to a whole scan area and the end part of vertical amplitude is extended to a whole screen so as to display them. When the aspect ratio is longer than is wide, vertical amplitude is extended to the whole scan area and the end part of horizontal amplitude to a whole display surface so as to display them.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television receiver for displaying an image having an aspect ratio different from that of a display surface.

[0002]

2. Description of the Related Art In the NTSC system, the aspect ratio is 4 :.
However, with respect to package software such as VTR and laser disk, horizontally long software from 4: 3 is commercially available.

This image has a black band (no image area) above and below the screen.
Is inserted, and a part of the image has a horizontally long aspect ratio from 4: 3.

Even if the software is horizontally long, its aspect ratio varies, and movie software has a video size called a cinemascope or Vistavision. These are wider than the aspect ratio of 16: 9, but what is called European Vista has an aspect ratio intermediate between 4: 3 and 16: 9.

[0005] Commercially available packaged software may have an aspect ratio different from that of the original image when trimmed when re-packaged into packaged software.

Actually, there are various kinds of insertion positions or aspect ratios of the effective image portion, and there are various kinds. The number of scanning lines constituting the effective image portion, the number of scanning lines of the upper black band, and the number of scanning lines of the lower black band are different from each other depending on the software even if it is described as a cinemascope size.

[0007] In some wide-screen software, especially movie software, subtitles are inserted at the bottom of the screen.
The aspect ratio of the image including the subtitles is more diverse.

Conventionally, in a wide aspect television receiver having an aspect ratio of 16: 9, in the case of receiving horizontal software, the image is expanded in the vertical direction to effectively utilize the screen,
When receiving software with an aspect ratio of 4: 3, it has been proposed to compress and display an image in the horizontal direction.

As described above, in software with a wide aspect ratio such as a movie, the aspect ratio of the image portion is various, and if the amplitude is changed at a constant ratio, a black band will remain or the image will not be displayed. There are things that are missing.

On the other hand, even if the image can be displayed on the entire screen, the number of scanning lines in the upper and lower black bands is large and the number of scanning lines in the image portion is small in the video software such as Cinemascope. Therefore, if an attempt is made to display this image on the entire display surface with a vertical amplitude of 16: 9, the image becomes a vertically elongated image.

Further, even if the image has a wide aspect ratio, the horizontal amplitude of the image close to 4: 3 has an aspect ratio of 1
There was a problem that an image was expanded horizontally when trying to fill the display surface of 6: 9.

[0012]

As described above, in the conventional apparatus, the wide aspect differs not only by the software on the market but also by the difference in the number of scanning lines between the image portion and the upper and lower black bands (non-image portion). Therefore, it is difficult to display an image that does not look strange for all of these aspect ratios.

The present invention has been made in view of the above problems, and is applicable to video software having various aspect ratios.
It is an object of the present invention to provide a television receiver capable of providing a suitable display.

[0014]

A television receiver according to the present invention according to claim 1 has a display surface having a wide aspect ratio, and an image having an aspect ratio different from the aspect ratio can be displayed on the display surface. A television receiver, comprising: an input terminal to which a video signal is supplied; a video signal processing means for processing the video signal from the input terminal to supply an output video signal to a display means; and an effective image. Detecting means for detecting the display position of the effective image portion in units of scanning lines from the video signal having the non-image portion adjacent to the image portion, and the number of scanning lines and the non-image portion of the effective image portion supplied with the signal from the detecting means. After counting the number of scanning lines, the aspect ratio of the area where the effective image area is present is calculated, and the aspect information is output from this calculation result, and this calculation result is compared with a predetermined aspect ratio. Aspect ratio calculating means for outputting the comparison result, horizontal deflection means for selectively executing display by correcting the horizontal amplitude or the linearity of the horizontal amplitude by the output from the aspect ratio calculating means, and the aspect ratio A vertical deflection unit that selectively executes the vertical amplitude or the linearity of the vertical amplitude corrected and displayed based on the output from the ratio calculation unit is provided.

According to a second aspect of the present invention, there is provided a television receiver according to the first aspect, wherein the detecting means is supplied with a luminance signal from the video signal processing means, and a horizontal cycle timing signal is supplied from the luminance signal. And a timing signal generating means for generating and outputting timing signals of a vertical cycle, a pedestal clamp circuit which is supplied with a luminance signal from the video signal processing means and clamps a pedestal level of the luminance signal, and a luminance from the pedestal clamp circuit. A signal is supplied, and a luminance signal is supplied from the pedestal clamp circuit and a vertical edge detecting unit that detects a luminance change when the signal shifts from one horizontal scanning to the next horizontal scanning. A black band determination means for comparing and detecting the black level, and the timing signal generating means. Is provided with a counting circuit that is triggered by a timing signal of a vertical cycle and counts a timing signal of a horizontal cycle. And a non-image area determining means for counting the number of scanning lines in the black band portion and outputting the detected scanning line position in the circuit.

According to a third aspect of the present invention, there is provided a television receiver having a display surface having a wide aspect ratio and capable of displaying an image having an aspect ratio different from the aspect ratio on the display surface. An input terminal to which a video signal is supplied, a video signal processing means for processing the video signal from the input terminal to supply an output video signal to the display means, and a caption on a non-image part adjacent to the effective image part. Detecting means for detecting the display position of the effective image portion from the inserted video signal in scanning line units, and the signal from the detecting means is supplied to count the number of horizontal scanning lines of the effective image portion and to horizontally scan the subtitles. After counting the lines, calculate the aspect ratio of the area that combines the subtitle portion and the effective image portion, and output this aspect information, and compare this calculation result with a predetermined aspect ratio, Comparison result output, and the aspect ratio calculating means for outputting a signal showing still display period of the subtitle, the comparison output from said aspect ratio calculating means,
The horizontal amplitude, or horizontal deflection means for selectively executing whether to correct and display the linearity of the horizontal amplitude, and the comparison output from the aspect ratio calculation means, the vertical amplitude, or
And a vertical deflection means for selectively performing linearity of vertical amplitude for display on the display surface and compression display or expansion display of subtitles.

A television receiver according to a fourth aspect is the television receiver according to the third aspect, wherein the detecting means is supplied with a luminance signal from the video signal processing means,
A pedestal clamp circuit for clamping the pedestal level of the luminance signal supplied from the video processing means with timing signal generating means for generating and outputting a timing signal of a horizontal cycle and a timing signal of a vertical cycle from the brightness signal. A luminance signal is supplied from the pedestal clamp circuit, and a luminance signal is supplied from the pedestal clamp circuit and vertical edge detecting means for detecting a change in luminance when the signal shifts from one horizontal scanning to the next horizontal scanning. This signal is compared with a predetermined voltage to detect a black level, and a black band determination means and a count for counting the horizontal cycle timing signal triggered by the vertical cycle timing signal from the timing signal generating means. A circuit for determining the discrimination signal from the black belt discrimination means and the vertical edge detection means; The non-image area determining means for outputting the detected scanning line position while counting the number of scanning lines in the black belt portion based on the detection signal of the counting circuit, and the luminance signal from the pedestal clamp circuit are supplied, Based on the horizontal timing signal from the timing signal generation circuit,
Caption detection means for detecting a white level for each horizontal scanning line,
It is characterized by being configured with.

A television receiver according to a fifth aspect of the present invention is the television receiver according to the first or third aspect, wherein the horizontal deflection means generates a drive pulse of a horizontal period based on a synchronizing signal of a horizontal period. A horizontal output transistor having a drive pulse generating circuit, a base, an emitter, and a collector, the drive pulse from the drive pulse generating circuit is supplied to the base, and the collector is connected to a DC power source through a flyback transformer. A series circuit of a deflection coil and a first S-shaped correction capacitor connected in parallel between the collector and the emitter of, and a first S-shaped correction capacitor connected in parallel.
A series circuit of a first switch circuit and a second correction capacitor that performs an opening / closing operation based on aspect information from the aspect ratio calculation means, and the first S-shaped correction capacitor are connected in parallel, A second opening / closing operation based on the aspect information from the aspect ratio calculation means
Of the switch circuit and the third S-shaped correction capacitor, a damper diode connected in parallel with the collector-emitter path of the horizontal output transistor, and a first diode connected in parallel with the collector-emitter path of the horizontal output transistor. A resonance capacitor, a second resonance capacitor connected between the collector of the horizontal output transistor and a reference potential point, and a second diode connected between the emitter of the transistor and the reference potential point in the opposite direction to the damper diode.
A capacitor connected in parallel with this second diode,
A smoothing circuit including a coil and a capacitor connected to both ends of the capacitor, and a deflection current control transistor connected in parallel to the capacitor of the smoothing circuit and driven based on a signal from the aspect ratio calculating means. It is characterized by having done.

According to a sixth aspect of the present invention, there is provided a television receiver according to the first or third aspect, in which the vertical deflection means generates a sawtooth wave having a vertical period based on a synchronizing signal having a vertical period. A sawtooth wave generating circuit for performing the first aspect, and a first aspect based on the aspect information from the aspect ratio calculating means.
Based on the aspect information from the aspect ratio calculation means, the second coefficient having the first coefficient function in which the coefficient of 1 is set, and the second coefficient having a polarity different from that of the first coefficient is calculated. A second squaring function generating circuit having a second coefficient unit to be set, and a cuber having a third coefficient unit to which a third coefficient is set based on aspect information from the aspect ratio calculating means. A function generating circuit and a sawtooth wave from the sawtooth wave generating circuit are supplied to the first square function generating circuit, and a first sawtooth wave is added to the output from the square function generating circuit. An adder circuit and a sawtooth wave from the sawtooth wave generating circuit are supplied to the second square function generating circuit, and the output from the square function generating circuit and the output from the first adding circuit are added. From the second adder circuit and the sawtooth wave generating circuit A sawtooth wave is supplied to the third cube function generating circuit, and a sawtooth wave is provided, and a third adder circuit for adding the output from the cube function generating circuit and the output from the second adder circuit is provided. A sawtooth wave supplied from the sawtooth wave generation circuit is converted from a linear function to a cubic function and output, and an output signal from the function generation circuit is supplied,
A deflection circuit for supplying a deflection current from a power supply voltage to a deflection coil on the basis of this signal.

A television receiver according to a seventh aspect is the television receiver according to the third aspect, wherein the vertical deflection means generates a sawtooth wave having a vertical period based on the vertical synchronizing signal having the vertical period. A sawtooth wave generating circuit, and a first coefficient unit in which a first coefficient is set based on aspect information from the aspect ratio calculating means.
And a second squarer having a second coefficient multiplier in which a second coefficient having a polarity different from that of the first coefficient is set based on the aspect information from the aspect ratio calculation means. A function generating circuit, a cube function generating circuit having a third coefficient unit in which a third coefficient is set based on aspect information from the aspect ratio calculating means, and a sawtooth shape from the sawtooth wave generating circuit. A wave is supplied to the first squaring function generating circuit, a first summing circuit for summing the output from the squaring function generating circuit and the sawtooth wave, and a sawtooth wave from the sawtooth wave generating circuit. Is supplied to the second square function generating circuit, and a second adder circuit for adding the output from the square function generating circuit and the output from the first adder circuit,
A sawtooth wave from the sawtooth wave generation circuit is supplied to the third cube function generation circuit, and an output from the cube function generation circuit and an output from the second adder circuit are added together. An adder circuit, a function generating circuit for converting the sawtooth wave supplied from the sawtooth wave generating circuit into a cubic function and outputting the function, and an output signal from the function generating circuit, Based on the subtitle region signal from the ratio aspect ratio calculating means, a first polygonal line circuit that makes the slope of the sawtooth wave gentle only in the subtitle region and the output signal from the function generating circuit are supplied at a predetermined timing. A second polygonal line circuit that makes the slope of the sawtooth wave steep only in the subtitle region at a predetermined timing based on the subtitle region signal from the aspect ratio calculation unit, and the aspect information from the aspect ratio calculation unit. Based on One of the output signals from the first or second broken line circuit is selected, and a deflection circuit for supplying a deflection current from the power supply voltage to the deflection coil based on this signal is selected. is there.

The television receiver according to claim 8 is the television receiver according to claim 2 or 4, wherein a luminance signal is supplied to the vertical edge detecting means from the pedestal clamp circuit, and this signal is horizontally scanned. A delay circuit for delaying, a subtraction circuit for obtaining a difference signal from the directly supplied luminance signal and the signal of the delay means, and a difference signal from the subtraction means for detecting only a change,
An absolute value circuit for removing the polarity and a comparison circuit for comparing the voltage from the absolute value circuit with a predetermined DC voltage source to detect a change in luminance are characterized.

A television receiver according to a ninth aspect is the television receiver according to the second or fourth aspect, in which the luminance signal is supplied from the pedestal clamp circuit to the black band detecting means, and the luminance signal is black. It is characterized by comprising a low-pass filter that passes only a band required for level determination, and a slice circuit that limits a signal from the low-pass filter to a predetermined voltage.

A television receiver according to a tenth aspect of the invention is
5. The television receiver according to claim 4, wherein the caption detection means is supplied with a luminance signal from the pedestal clamp circuit, and a peak hold for detecting a peak value required for white level determination from the luminance signal every horizontal period. A circuit and a comparison circuit, which is supplied with a signal from the peak hold circuit, compares the signal with a predetermined voltage, and detects a white level, are configured.

[0024]

According to the present invention, the scanning line position of the image portion of the video software having a different aspect ratio is detected, and the linearity of the vertical amplitude or the horizontal amplitude is determined from the aspect ratio of the image portion to be displayed and the aspect ratio of the display surface. By controlling and displaying, an image having an aspect ratio different from that of the display surface can be displayed without a feeling of strangeness.

Further, according to the present invention, the positions of the image portion and the caption of the video software having different aspect ratios are detected in scanning line units, and the vertical direction is calculated from the aspect ratio of the effective image portion including the caption and the aspect ratio of the display surface. By controlling and displaying the linearity of the amplitude or the horizontal amplitude, it is possible to display images with different aspect ratios without a feeling of strangeness.

[0026]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of a television receiver according to the present invention. In FIG. 1, the same components as those of FIG. 4 are designated by the same reference numerals and described. FIG. 1 is a diagram showing a configuration of a television receiver according to the present invention.

In FIG. 1, the composite video signal is input terminal 1
Is supplied to the video signal processing means 2. Here, after the luminance signal Y and the color signal C in the composite video signal are separated, the color signals (BY, RY) and the luminance signal Y, which are video output signals, are output to the display means 4. It Of the video output signals, the luminance signal Y is also supplied to the valid information detecting means 100, where the valid image portion is detected in units of one horizontal scanning line (1H).

This detection signal is supplied to the aspect ratio calculation means 200 in the next stage, and the aspect ratio calculation means 200 calculates the aspect ratio of the input video signal from the detection information detected in 1H units.

The aspect ratio calculating means 200 includes a counting circuit such as a counter / timer circuit and an arithmetic circuit, for example, and counts the number of scanning lines (H) to calculate the aspect ratio. With this aspect ratio calculation means 200,
The calculated aspect ratio is compared with the aspect ratio set in advance in anticipation of the overscan area.
Here, it is determined whether the aspect ratio is horizontally long or vertically long. The aspect information calculated from this comparison result and the number of horizontal scanning lines is the aspect ratio calculation means 20.
From 0 to the horizontal deflection means 300 and the vertical deflection means 400.

The horizontal deflection means 300 receives the transferred data, corrects the horizontal amplitude and linearity based on this information, and outputs a deflection signal to the display means 4. The vertical deflection means 400 also receives the transferred data, corrects the vertical amplitude and linearity based on this information, and outputs a deflection signal to the display means 4.

When the comparison result is horizontally long, the horizontal amplitude is displayed in the entire overscan area, the vertical linearity is corrected according to the calculated ratio, and the entire display surface is displayed.

When the comparison result is vertically long, the vertical amplitude is displayed in the entire overscan area, the horizontal linearity is corrected according to the calculated aspect ratio, and the entire display surface is displayed.

As is well known, horizontal / vertical sync separation 3 is performed from the composite video signal, and a horizontal sync signal (hereinafter, referred to as Hsync) and a vertical sync signal (hereinafter, Vsync) are provided to the horizontal deflection means 300 and the vertical deflection means 400. Is said to be supplied. Horizontal deflection means 300 and vertical deflection means 4
00 generates a deflection signal based on these synchronization signals. The aspect ratio calculation means 200 may be composed of a microcomputer.

The configuration and operation of each part of the circuit shown in FIG. 1 will be described in detail below with reference to FIGS. 2 to 5 are shown in FIG.
The details of each circuit will be described below in order. First, the circuit configuration of the valid information detecting means 100 will be described with reference to FIG.

In FIG. 2, the luminance signal Y supplied from the video signal processing means 2 is the pedestal clamp circuit 101.
Is supplied to. Here, the luminance signal Y is clamped to the pedestal level, the direct current component of the luminance signal Y is reproduced, and supplied to the black band determination means 110, the vertical edge detection means 120, and the caption detection means 130 in the next stage.

The signal from the black band determination means 110 and the signal from the vertical edge detection means 120 are the non-image area determination means 1 in the next stage.
40, and the output signal from the non-image area determination means 140 is supplied to the aspect ratio calculation means 200.

The luminance signal Y from the video signal processing means 2
Is also supplied to the horizontal / vertical timing signal generation means 102, where the horizontal timing signal HD and the vertical timing signal VM are generated, and these timing signals are used for the caption detection means 130, the non-image part determination means 140 and It is supplied to the aspect ratio calculating means 200, respectively.

The details of these circuits will be described in more detail with reference to the block diagram showing the circuit configuration of each unit. First, the operation of detecting the black band from the luminance signal transmitted with the DC component from the pedestal clamp circuit 101 will be described.

The circuit configuration and operation of the black band determining means 110 will be described with reference to FIG. In FIG. 3, the black band detecting means 110 includes a low pass filter 111 and a slice circuit 112.

The luminance signal Y from the pedestal clamp circuit 101 is supplied to a low pass filter (hereinafter referred to as horizontal LPF) 111 having a low pass frequency as a pass band. The horizontal LPF 111 allows the luminance signal Y to pass only the frequency component necessary for the black level determination, and the slice circuit 1 at the next stage.
Supply to 12. In the slice circuit 112, a predetermined DC voltage is used as a slice level, and when the signal supplied from the horizontal LPF 111 is lower than a predetermined DC voltage value, it is determined as a black level.

The luminance signal Y from the pedestal clamp circuit 101 is also supplied to the vertical edge detecting means 120. Is there any change in the luminance signal Y from one horizontal scanning to the next one horizontal scanning? Is detected.

The circuit configuration and operation of the vertical edge detection circuit 120 will be described with reference to FIG. The vertical edge detecting means 120 includes a 1H delay circuit 121, a subtracting circuit 122, an absolute value circuit 123, and a comparing circuit 124.

In FIG. 4, the pedestal clamp circuit 10
The luminance signal Y from 1 is supplied to the 1H delay circuit 121.
The signal delayed by 1H from the delay circuit 121 is the subtraction circuit 1
22 is supplied. Further, the luminance signal Y from the pedestal clamp circuit 101 is directly supplied to the subtraction circuit 122, and subtraction is performed here with respect to the previous signal.

The output of the subtraction circuit 122 is supplied to the absolute value circuit 123 and further to the comparison circuit 124. The output signal from the comparison circuit 124 is further supplied to the non-image area determination means 140.

In order to detect the change in brightness when the line shifts from one horizontal scanning line to the next scanning line, the absolute value circuit removes the polarity and only detects whether there is a change. That is, in this comparison circuit, the output signal is supplied to the non-image area determining means 140 at the portion where the black level changes to the white level side or the white level side changes to the black level.

The comparison circuit 124 is supplied with a reference voltage for detecting a change point (edge) in the vertical direction. This reference voltage is set in consideration of a margin from the black level, and is set at a DC voltage value that can reliably detect that the black level has changed every 1H.

In the comparison circuit 124, when the reference level is exceeded, it is determined that a change from the black level to the white side level or from the white side level to the black level appears in the unit of horizontal scanning line, and the non-image area determining means in the next stage. Notify 140. That is, the edge of the vertical luminance change is detected.

The non-image area determining means 140 counts non-images in units of 1H while the black level detection signal from the black band determining means 110 is being supplied, and indicates that the slice circuit 112 has exceeded the reference voltage value. Signals and vertical edge detection means 12
When the signal indicating that the vertical edge from 0 is detected is supplied together, the end position of the non-image portion, that is, the start point of the effective image portion is detected. Further, also at the end position of the effective image portion, both the signal from the black band determination means 110 indicating that the voltage has become lower than the reference voltage value of the slice circuit 112 and the signal from the vertical edge detection means 120 indicating that the edge has been detected. The effective image portion is determined to have ended when detected.

That is, when the detection signals from both the black band determination means 110 and the vertical edge detection means 120 match, in other words, when the scanning line positions match, this is referred to as the start position or end position of the non-image area. Making a decision. By this, the end position of the non-image part on the upper part of the screen and the start position of the non-image part on the lower part of the screen are respectively detected, and this position data is supplied to the aspect ratio calculating means 200. On the other hand, the subtitle detection signal from the subtitle detection unit 130 is also supplied to the aspect ratio calculation unit 200, and the position of the subtitle is detected here.

The circuit configuration and operation of the caption detection means 130 will be described with reference to FIG. The subtitle detection means 130
As shown in FIG. 5, it comprises a peak hold circuit 131 and a comparison circuit 132.

The luminance signal Y clamped to the pedestal level is supplied from the pedestal clamp circuit 101 to the peak hold circuit 131. Peak hold circuit 131
At, the peak value of the luminance signal is detected and held. This signal is supplied to the comparison circuit in the next stage and compared with the reference value of the white peak. As a result, the subtitle is detected by detecting the white level from the luminance signal, and a signal indicating the subtitle position is supplied to the aspect ratio calculation circuit 200 in the next stage.

The horizontal timing signal (HD) is supplied to the above-mentioned peak hold circuit 131, and the peak hold circuit 131 is reset every horizontal cycle.
As a result, the comparison is performed for each 1H, and the white level is surely detected for each 1H unit.

Further, from the comparison circuit 132, the signal indicating the start of the caption is output separately from the signal indicating the caption, and when the comparison reference value is exceeded, it is notified to the aspect calculating means 200 that the caption is detected. Notifying. In the aspect ratio calculation means 200, the caption detection means 130 is set for each horizontal period.
The caption area is calculated by counting the signals indicating the captions from.

Further, the judgment signal from the non-picture area judgment means 140 is also supplied to the aspect ratio calculation circuit 200, and the aspect ratio calculation means 200 judges the subtitle only when the character data is detected in the lower non-picture area. is doing. In addition, there is no normal video software with blanking in the left and right video periods, and the aspect ratio with effective information can be calculated by counting the scanning lines. By comparing the calculated aspect ratio with a preset aspect ratio, the portrait orientation and the landscape orientation are determined.

Further, here, a signal for correcting the linearity of horizontal and vertical amplitudes is generated so that an appropriate roundness can be obtained from the number of scanning lines of the effective image portion.

However, in general, horizontal scanning is overscanned in consideration of a region in which stripes such as ringing occurring at the left and right ends of the image region do not appear on the screen. Vertical scanning is also overscanned so that the blanking period does not appear on the screen due to high voltage fluctuations. A predetermined aspect ratio is set for this overscanned area, and it is determined whether the calculated aspect ratio is horizontally long or vertically long.

This overscan area is shown in FIG. This area is set as the reference aspect ratio. The aspect ratio calculation means 200 transfers deflection signal generation data to the deflection circuits 300 and 400 according to whether the calculated aspect ratio is horizontally long or vertically long with respect to the reference aspect ratio. To do. Here, for example, I
Data shall be transferred using a serial bus such as an IC bus.

When it is horizontally long, the horizontal amplitude is displayed in the full overscan area, or the vertical linearity is corrected according to the calculated aspect ratio and displayed in the full display surface.

When it is vertically long, the vertical amplitude is displayed in the full overscan area, or the horizontal linearity is corrected according to the calculated aspect ratio and displayed in the full display surface.

Here, details of the horizontal and vertical deflection means 300 and 400 will be described with reference to FIGS. First,
The horizontal deflection means 300 will be described with reference to FIG. In FIG. 7, the horizontal sync signal Hsync separated by the sync separation circuit 3 is supplied to the horizontal drive pulse generation circuit 301. Here, the horizontal drive pulse is generated based on the horizontal period and is supplied to the base of the horizontal output transistor Tr1.

A series circuit of a damper diode DD, a resonance capacitor Cr, a deflection coil DY and a correction capacitor Cs is connected in parallel between the collector and emitter of the horizontal transistor Tr1. Further, a series circuit of a first correction capacitor Cs1 and a switch circuit Sw1 and a series circuit of a second correction capacitor Cs2 and a switch circuit Sw2 are connected in parallel to the correction capacitor Cs.

The control data from the aspect ratio calculating means 200 is supplied to the switch circuit Sw1, and the first switch Sw1 or the second switch Sw1 is supplied based on the result of the calculation of the aspect ratio and the comparison with the reference aspect ratio. The switch Sw2 of is selected and connected. The emitter of the horizontal output transistor Tr1 is connected to the reference potential point via the diode D1.

The control transistor Tr2 for controlling the deflection current to the deflection coil Dy is the horizontal output transistor T.
It is connected to the emitter of r1 via a coil L1.
A second resonance capacitor C6 is connected between the collector of the horizontal transistor and the reference potential point.

The emitter of the control transistor Tr2 is connected to the reference potential point, and the horizontal amplitude is controlled based on the signal from the aspect ratio calculating means. Note that this control is performed with a DC voltage, and a DC voltage for horizontal amplitude adjustment is supplied from the aspect ratio calculation means 200 via a DA converter (hereinafter referred to as DAC) 302. Further, the capacitor C7 is connected to the collector of the transistor Tr2 via the smoothing circuits L1 and C5,
The deflection current is controlled by the voltage generated at one end of the capacitor C7 according to the supplied DC voltage, and the horizontal amplitude is controlled. The secondary winding of the flyback transformer is connected to the anode of the picture tube 350, and a high voltage obtained by rectifying the retrace pulse is supplied to the anode.

The transistor Tr1 as shown in FIG.
Tr2, diodes DD and D1, capacitors Cr and C7
An example of a horizontal output circuit having
The one described in Japanese Patent No. 7574 is known.

The operation of FIG. 7 will be described with reference to FIG. Figure 8
FIG. 4A is a diagram for explaining the linearity of the horizontal amplitude of the image displayed on the screen, and FIG.
2 is a diagram for explaining linearity of horizontal amplitude when both switches are turned off, (b) is for turning on either one of the switches SW1 and SW2, and (c) is a diagram for explaining linearity of horizontal amplitude when both horizontal switches SW1 and SW2 are on.

As is well known, the linearity of horizontal deflection in FIG. 8 is performed by the S-shaped correction capacitor Cs and the like. Here, it is connected in parallel to the S-shaped correction capacitor Cs based on the control data from the aspect ratio calculation means 200. By turning on / off these capacitors Cs1 and Cs2 with the switch circuits Sw1 and Sw2,
Changing the resonance condition.

Here, by connecting the parallel capacitors Cs1 and Cs2, the ends of the amplitude in the horizontal direction are expanded. As for the expansion rate, the ends of the horizontal amplitude are expanded by increasing the capacitance of the capacitors Cs1 and Cs2. The expansion rate can be changed by arbitrarily setting this capacitance value.

Further, horizontal amplitude control can be performed by controlling the base voltage of the control transistor Tr2. The on / off states of the switch circuits Sw1 and Sw2 and the setting of the base voltage of the control transistor Tr2 are as follows.
This is performed based on the data from the aspect ratio calculation means 200. The expansion of the horizontal amplitude is performed, for example, by applying the data from the aspect ratio calculating means to the base of the control transistor Tr2 via the DAC 302.

Here, it is assumed that each setting is performed on the basis of the data sent by the serial bus.

With this configuration, when the calculated aspect ratio is horizontally longer than the predetermined aspect ratio,
The image amplitude of the end portion can be expanded and displayed by expanding and displaying the full horizontal amplitude of the area in which the overscan is anticipated, or by turning on / off the switch SW1 or SW2 when the area is vertically long.

The switch is a relay or PIN.
It can be configured by switches.

Next, the vertical deflection means 400 will be described with reference to FIG.

Vertical sync signal Vsync from sync separation circuit 3
Is supplied, and a sawtooth wave having a vertical cycle is generated by the sawtooth wave generation circuit 401. The sawtooth wave is generated, for example, by a sawtooth generation circuit 401 which is well known to those skilled in the art and includes a current source, a capacitor, and a switch circuit. It should be noted that, based on the data from the aspect ratio calculation means 200, a sawtooth wave with a desired vertical amplitude is obtained. This is achieved, for example, by switching the time constant determined by the resistor and the capacitor.

In FIG. 9, the sawtooth wave generating circuit 40 is shown.
A sawtooth wave is supplied from 1 to the function generating circuit 410 of the next stage. The function generation circuit 410 includes an aspect ratio calculation means 2
The signal from 00 is also supplied, and based on this signal, the conversion of the waveform of the linear function into the waveform of the cubic function is performed. However, the function generating circuit 410 can also pass the signal from the sawtooth wave generating circuit 401 as it is.

This signal is supplied to the broken line circuit 420.
The polygonal line circuit 420 is also supplied with the signal from the aspect ratio calculation means 200, and based on this signal, the slope of the sawtooth waveform is changed and output.

The signal from the broken line circuit 420 is supplied to the operational amplifier circuit 430 in the next stage. This operational amplifier circuit 43
The output of 0 is connected to the transistor Tr10 for driving the final stage single-ended amplifier circuit, and supplies a deflection current from the power supply voltage Vcc to the deflection coil Ly in accordance with the sawtooth wave supplied. In this deflection coil Ly,
Direct current and alternating current are fed back, which makes it possible to stably supply the deflection current Iy supplied from the power supply to the coil Ly.

The single-end type amplifier circuit is composed of transistors Tr20 and Tr30 and resistors R10 and R20, and the feedback circuit is capacitors C20 and C30.
And resistors R30, R40 and R50.

The function generating circuit 410 will be described here with reference to FIG. FIG. 10 shows a process of generating a sawtooth wave for correcting linearity, and the sawtooth generation circuit 401
Treat the sawtooth wave from to as a waveform represented by a linear function,
Explaining.

The function generating circuit 410 comprises square function generating circuits 411 and 412, a cube function generating circuit 413, coefficient units 414 to 416 and adder circuits 417 to 419.
The coefficient units 414, 415, and 416 use coefficients S1, S2, and S2 based on the signal from the aspect ratio calculation unit 200.
The configuration is such that S3 is set. This coefficient unit 41
4,415,416 Square function generating circuits 411,41
The second and third power function generating circuit 413 can be configured by using, for example, an operational amplifier.

Further, the coefficient data S1, S2, S3 from the aspect ratio calculating means 200 is transferred, and the coefficient units 414 to 416 composed of, for example, a ladder circuit and a switch circuit operate based on this signal, and the coefficient Vessel 414-
A predetermined coefficient can be set in 416.

The reference sawtooth wave is supplied from the sawtooth wave generation circuit 401 to the adder circuit 417. The reference sawtooth wave is also supplied to the square function generating circuit 411, where the sawtooth wave, that is, a linear function is squared. The squared sawtooth wave and the sawtooth wave represented by a linear function are added to the adder circuit 4
It is added at 17. Further, the sawtooth wave represented by the added quadratic function is further supplied to the addition circuit 418.

On the other hand, this addition circuit 418 is supplied with a quadratic function having a negative coefficient from the square function generation circuit, and the quadratic function and the addition circuit 418 are added. Further, the sawtooth wave represented by this quadratic function is further added by the addition circuit 419 with the cubic function from the cube function generation circuit. As a result, the adder circuit 419 outputs a sawtooth wave represented by a cubic function.

[0084] When the sawtooth wave reference to f (X) = X, this output is expressed as ^{F (X) = S3X 3 -S2X} 2 + S1X 2 + X.

That is, by setting the coefficients S1, S2 and S3 based on the data from the aspect ratio calculating means 200, it is possible to generate a sawtooth wave represented by an arbitrary cubic function.

A waveform when a coefficient is set in any one of the coefficient units 414 to 416 of FIG. 10 is shown. FIG. 11 (a)
Is a waveform to which a positive square function is added.
FIG. 1B shows a waveform to which a negative square function is added, which is shown in FIG.
1 (c) is a waveform to which a cube function is added. By combining these variously, a waveform represented by an arbitrary cubic function can be obtained. That is, the linearity in the vertical direction can be corrected according to the deflection speed.

By thus forming the sawtooth wave as a cubic function waveform, the inclination of the upper and lower ends can be made larger than that of the central portion. Therefore, the image is stretched at the top and bottom edges.

This is performed based on the signal from the aspect ratio calculating means 200, and the linearity of the vertical amplitude of the image can be controlled by setting a desired cubic function.

Further, in the case of video software with subtitles inserted, vertical linearity is corrected and displayed by the polygonal line circuit 420 in the next stage.

The broken line circuit 420 will be further described. The sawtooth wave from the function generating circuit 410 is supplied to the polygonal line circuit 420 at the next stage. Here, waveforms having different inclinations are generated based on the area signal indicating the subtitle area from the aspect ratio calculation means 200.

The area signal is generated by the aspect ratio calculating means based on the signal from the caption detecting means.
This is, for example, a pulse-like signal indicating the period of the subtitle region from the subtitle start position by counting the scanning lines, calculating what number signal is for 1V, and corresponding to 1H. There is a method of generating with.

The polygonal line circuit 420 can be composed of, for example, an operational amplifier circuit, a ladder type circuit, a switch circuit, etc., and the inclination can be changed by connecting an analog switch to the switch circuit based on the area signal.

Also, the time constant of the sawtooth wave generation circuit 401 described above may be switched to change the inclination.

The operation of the broken line circuit 420 will be described with reference to FIGS. 12 (a) to 12 (c) schematically show a process of generating a sawtooth wave in the case of compression, and FIGS. 12 (d) to 12 (f) show a case of expansion. 3 schematically shows a process of generating a sawtooth wave.

FIGS. 12A and 12D show the reference sawtooth wave from the sawtooth wave generation circuit 401, and FIG.
And (e) are area signals from the aspect ratio calculation means 200. This area signal is generated and supplied by the aspect ratio calculation means 200.

The area signal from the aspect ratio calculation means 200 is supplied to the broken line circuit 420, and based on this signal,
Subtitles are expanded or compressed.

When expanding, the inclination is made steep, and when compressing, the inclination is made gentle.

The inclination can be changed at the timing of the area signal,
In the case of compression, the inclination is gentle as shown in FIG. This signal is supplied to the operational amplifier circuit 440 in the next stage. In the case of extension, the opposite is true, as shown in FIG.
The inclination is steep as shown in (f). This signal is supplied to the operational amplifier circuit 430 in the next stage.

The slope can be changed by changing the time constant of the sawtooth wave generating circuit 401. In this case, the area ratio is supplied from the aspect ratio calculating means 200 to the sawtooth wave generating circuit 401. , The tilt can be changed.

The coefficient of the function generating circuit 410 is set to 0, and the sawtooth wave of the sawtooth generating circuit 401 is input to the polygonal line circuit 420 as it is. FIG. 13 shows a front view of an image displayed on the display surface projected based on these waveforms.

FIG. 13A shows an example in which the caption is expanded and displayed, and FIG. 13B shows an example in which the caption is compressed and displayed. The compression or expansion is performed based on the timing of the area signal to which the signal from the aspect ratio calculation means 200 is transferred.

With such a configuration, software having a small number of scanning lines in the image section can display the image on the screen with a high expansion rate of the subtitle section, and more scanning lines in the image section can be displayed. With software that extends beyond the screen, it is possible to compress and display the subtitle portion. The scanning lines are counted, and the scanning lines of the image section add a command code for compression or expansion control to this area signal from the aspect ratio calculation means and transfer it to the deflection means.
Such a display is performed.

Therefore, based on the comparison result of the aspect ratio calculation means, in the case of this horizontal length, the horizontal amplitude is displayed in the full overscan area, and the vertical linearity is corrected according to the calculated ratio to fill the display surface. When it is possible to display and the comparison result is vertically long, the vertical amplitude can be displayed in the entire overscan area, the horizontal linearity can be corrected according to the calculated aspect ratio, and the entire display surface can be displayed. In addition, it is possible to display an image in which subtitles are inserted without a feeling of strangeness.

As described above, in the television receiver according to the present invention, suitable display can be performed even with software having an aspect ratio different from that of the display surface.

[0105]

According to the present invention, the horizontal amplitude or the vertical amplitude is controlled by calculating the aspect ratio even with video software having various aspect ratios, or the linearity of the horizontal amplitude or the horizontal linearity of the vertical amplitude is controlled. By controlling, it is possible to maintain a proper roundness and display appropriately for images having different aspect ratios.

Further, the video in which the subtitles are inserted can be displayed on the entire display surface without feeling awkward.

[Brief description of drawings]

FIG. 1 is a block diagram showing a television receiver according to an embodiment of the present invention.

FIG. 2 is a block diagram showing an embodiment of the valid information detecting means of FIG.

FIG. 3 is a block diagram showing an embodiment of the black band detecting means in FIG.

FIG. 4 is a block diagram showing an embodiment of the vertical edge detecting means of FIG.

5 is a block diagram showing an embodiment of the caption detection means of FIG.

FIG. 6 is a diagram illustrating an overscan area.

7 is a block diagram showing an embodiment of the horizontal deflection means shown in FIG.

FIG. 8 is a diagram for explaining horizontal linearity by the horizontal deflection unit of FIG.

9 is a block diagram showing an embodiment of the vertical deflection means of FIG.

FIG. 10 is a diagram illustrating the function generation circuit of FIG.

11 is a diagram illustrating waveforms of the function generating circuit of FIG.

FIG. 12 is a diagram illustrating the operation of the broken line circuit in FIG.

FIG. 13 is a view of a subtitle compressed and expanded by the broken line circuit of FIG. 9 viewed on a screen.

[Explanation of symbols]

 2 ... Video signal processing means 3 ... Sync separation circuit 4 ... Display means 100 ... Effective information detecting means 101 ... Pedestal clamp circuit 102 ... Horizontal / vertical timing signal generating circuit 110 ... Black band detecting means 120 ... Vertical edge detecting means 130 ... Subtitle detection / detection means 140 ... Image-free area determination means 200 ... Aspect ratio calculation means 300 ... Horizontal deflection means 400 ... Vertical deflection means

Claims (10)

[Claims] 1. A television receiver having a wide aspect ratio display surface and capable of displaying an image having an aspect ratio different from the aspect ratio on the display surface, the input terminal supplied with a video signal. A video signal processing means for processing a video signal from the input terminal and supplying an output video signal to the display means; Detecting means for detecting the position in units of scanning lines, the signal from the detecting means is supplied, and after counting the number of scanning lines of the effective image portion and the number of scanning lines of the non-image portion, the effective image portion Aspect ratio is calculated, aspect information is output from this calculation result, and this calculation result,
Aspect ratio calculating means for comparing with a predetermined aspect ratio and outputting the result of comparison, and output by the aspect ratio calculating means is selected to correct and display horizontal amplitude or linearity of horizontal amplitude. And a vertical deflection unit that selectively executes the vertical amplitude or the linearity of the vertical amplitude to be corrected and displayed based on the output from the aspect ratio calculation unit. John receiver. 2. The detecting means is supplied with a luminance signal from the video signal processing means, and generates a timing signal of a horizontal period and a timing signal of a vertical period from the luminance signal, and outputs the timing signal generating means. A luminance signal is supplied from the video signal processing means, a pedestal clamp circuit that clamps the pedestal level of the luminance signal, and a luminance signal is supplied from the pedestal clamp circuit.
A luminance signal is supplied from the pedestal clamp circuit and a vertical edge detecting means for detecting a luminance change when shifting from one horizontal scanning to the next horizontal scanning of this signal, and this signal is compared with a predetermined voltage to obtain a black signal. The black band determining means for detecting the level and the counting circuit for counting the horizontal cycle timing signal triggered by the vertical cycle timing signal from the timing signal generating means are provided. A non-image area determining means for counting the number of scanning lines in the black band portion and outputting the detected scanning line position by the counting circuit based on the signal and the signal from the detection signal from the vertical edge detecting means. The television receiver according to claim 1, wherein the television receiver is provided. 3. A television receiver having a wide aspect ratio display surface and capable of displaying an image having an aspect ratio different from the aspect ratio on the display surface, the input terminal supplied with a video signal. , A video signal processing means for processing a video signal from the input terminal to supply an output video signal to the display means, and a valid image from a video signal in which a caption is inserted in a non-image part adjacent to the valid image part Detection means for detecting the display position of the unit in units of scanning lines, the signal from the detection means is supplied, after counting the number of horizontal scanning lines of the effective image portion and the horizontal scanning lines of the subtitle, Calculate the aspect ratio of the area including the effective image part, and output this aspect information.
By comparing this calculation result with a predetermined aspect ratio, outputting this comparison result, and further outputting a caption area signal representing the display period of the caption, an aspect ratio calculation means, and a comparison output from the aspect ratio calculation means. , Horizontal amplitude, or horizontal deflection means for selectively executing correction of horizontal amplitude linearity and displaying on the display surface, and vertical output or vertical linearity is corrected by comparison output from the aspect ratio calculation means. And display it on the display screen,
And a vertical deflection means for selectively performing compression display or expanded display of subtitles, and a television receiver. 4. The timing signal generating means, to which the luminance signal is supplied from the video signal processing means, and which generates and outputs a horizontal period timing signal and a vertical period timing signal from the luminance signal. A luminance signal is supplied from the image processing means, a pedestal clamp circuit that clamps the pedestal level of the luminance signal, and a luminance signal is supplied from the pedestal clamp circuit.
A luminance signal is supplied from the pedestal clamp circuit and a vertical edge detecting means for detecting a luminance change when shifting from one horizontal scanning of this signal to the next horizontal scanning, and this signal is compared with a predetermined voltage, and a black level is obtained. And a counting circuit that is triggered by the timing signal of the vertical cycle from the timing signal generating means and counts the timing signal of the horizontal cycle, and the determination signal from the black band determination means. And a non-image area determination means for counting the number of scanning lines in the black band portion and outputting the detected scanning line position in the counting circuit based on the detection signal from the vertical edge detection means, and the pedestal clamp circuit. A subtitle detection circuit is supplied with a luminance signal and detects a white level for each horizontal scanning line based on the horizontal timing signal from the timing signal generation circuit. Claim, characterized by comprising means, the 3
The described television receiver. 5. The horizontal deflection means has a drive pulse generating circuit for generating a drive pulse of a horizontal cycle based on a synchronizing signal of a horizontal cycle, a base, an emitter, and a collector, and the drive pulse generating circuit at the base. Drive pulse from
A horizontal output transistor having a collector connected to a direct current power supply via a flyback transformer; a series circuit of a deflection coil and a first S-shaped correction capacitor connected in parallel between the collector and emitter of the horizontal output transistor; A series circuit of a first switch circuit and a second correction capacitor, which are connected in parallel to the first S-shaped correction capacitor and perform an opening / closing operation based on aspect information from the aspect ratio calculation means; A series circuit of a second switch circuit and a third S-shaped correction capacitor that are connected in parallel to the first S-shaped correction capacitor and that perform an opening / closing operation based on the aspect information from the aspect ratio calculation means; A damper diode connected in parallel to the collector / emitter path of the horizontal output transistor; A first resonance capacitor connected in parallel with the collector-emitter path; a second resonance capacitor connected between the collector of the transistor and a reference potential point; and a damper diode in the opposite direction between the emitter of the transistor and the reference potential point. A second diode connected to the capacitor, a capacitor connected in parallel to the second diode, a smoothing circuit composed of a coil and a capacitor connected to both ends of the capacitor, and a capacitor connected in parallel to the capacitor of the smoothing circuit, 4. The television receiver according to claim 1, further comprising a control transistor for controlling a deflection current which is driven based on a signal from the aspect ratio calculating means. 6. The vertical deflection means includes a sawtooth wave generation circuit for generating a sawtooth wave having a vertical cycle based on a synchronization signal having a vertical cycle, and the aspect information from the aspect ratio calculation means. A first squaring function generating circuit having a first coefficient unit in which a coefficient of 1 is set; and a second coefficient having a polarity different from that of the first coefficient based on aspect information from the aspect ratio calculating means. A second square function generating circuit having a second coefficient unit in which is set, and a third coefficient unit having a third coefficient in which the third coefficient is set based on the aspect information from the aspect ratio calculating means. A sawtooth wave from the sawtooth wave generation circuit and the sawtooth wave generation circuit is supplied to the first squaring function generation circuit, and an output from the squaring function generation circuit and the sawtooth wave are added. And the sawtooth wave generator A sawtooth wave from the circuit is supplied to the second squaring function generating circuit, and a second summing circuit for summing the output from the squaring function generating circuit and the output from the first summing circuit; The sawtooth wave from the sawtooth wave generation circuit is supplied to the third cube function generation circuit, and the output from this cube function generation circuit and the output from the second addition circuit are added. A function generating circuit for converting the sawtooth wave supplied from the sawtooth wave generating circuit into a cubic function and outputting the function, and an output signal from the function generating circuit. The television receiver according to claim 1 or 3, further comprising a deflection circuit that supplies a deflection current from a power supply voltage to a deflection coil based on the above. 7. The vertical deflection means, based on the vertical synchronization signal of the vertical cycle, a sawtooth wave generation circuit for generating a sawtooth wave of a vertical cycle, and aspect information from the aspect ratio calculation means, A first square function generating circuit having a first coefficient unit in which a first coefficient is set, and a second coefficient having a polarity different from that of the first coefficient based on aspect information from the aspect ratio calculating means. It has a second square function generating circuit having a second coefficient unit in which a coefficient is set, and a third coefficient unit in which a third coefficient is set based on aspect information from the aspect ratio calculating means. A cubic function generating circuit and a sawtooth wave from the sawtooth wave generating circuit are supplied to the first square function generating circuit, and an output from the square function generating circuit and the sawtooth wave are added. 1 adder circuit and the sawtooth shape A sawtooth wave from a wave generating circuit is supplied to the second square function generating circuit,
The second adder circuit for adding the output from the square function generating circuit and the output from the first adder circuit, and the sawtooth wave from the sawtooth wave generating circuit are the third cube function generating circuit. And a third adder circuit for adding the output from the cube function generating circuit and the output from the first adder circuit to the primary of the sawtooth wave supplied from the sawtooth wave generating circuit. A function generating circuit for converting a function into a cubic function and outputting the function, and an output signal from the function generating circuit are supplied, and based on the caption area signal from the ratio aspect ratio calculating means, at a predetermined timing, A first polygonal line circuit for gently sloping the sawtooth wave only in the region and an output signal from the function generating circuit are supplied, and based on the subtitle region signal from the aspect ratio calculation means, at a predetermined timing, the caption Area only saw A second polygonal line circuit for making the slope of the linear wave steep, and one of the output signals from the first or second polygonal line circuit is selected based on the aspect information from the aspect ratio calculation means. 4. The television receiver according to claim 3, further comprising a deflection circuit that supplies a deflection current from a power supply voltage to a deflection coil based on the power supply voltage. 8. The vertical edge detection means is supplied with a luminance signal from the pedestal clamp circuit,
A delay circuit that delays this signal by one horizontal scan, a subtraction circuit that obtains a difference signal from the directly supplied luminance signal and the signal of the delay means, and only a change amount from the difference signal from the subtraction means In order to detect, an absolute value circuit for removing the polarity, and a comparator circuit for comparing the voltage from the absolute value circuit with a predetermined DC voltage source to detect a brightness change are provided. The television receiver according to 2 or 4. 9. The black band detection means is supplied with a luminance signal from the pedestal clamp circuit,
3. A low-pass filter that passes only the band required for this luminance signal to determine a black level, and a slice circuit that limits the signal from the low-pass filter to a predetermined voltage.
Or the television receiver described in 4. 10. The subtitle detecting means is supplied with a luminance signal from the pedestal clamp circuit,
A peak hold circuit that detects a peak value required for white level determination from this luminance signal for each horizontal period and a signal from the peak hold circuit are supplied, and this signal is compared with a predetermined voltage to determine the white level. The television receiver according to claim 4, further comprising: a comparator circuit that detects that there is a presence.