JPH02149190A - Television receiver - Google Patents

Abstract

PURPOSE:To prevent production of uneven brightness caused due to a difference of a radiation quantity of an electron beam between a part of display screen and a blank part by controlling the brightness of the blank caused at the reception of the existing standard television signal in the opposite direction to the brightness of the existing television signal. CONSTITUTION:A timing signal WP is outputted from a system controller 4 corresponding to the blank caused when a received pattern of the existing standard television broadcast of the NTSC system is displayed on a picture tube 26 of high definition television, a switch circuit 36 is turned on and a signal having a level set by a variable resistor 37 is fed to adder circuits 21A-21C during the blank period via a brightness variable circuit 35. The level of the brightness variable circuit 35 is detected by a level detection circuit 33 and set by a detection level of a luminance signal Y inverted by an inversion circuit 34 and the brightness of the blank part is controlled in the opposite direction to the brightness of the video part. Thus, the deterioration in the secular change in the video part and the blank part is equal to each other and the production of uneven brightness and color unevenness is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a television receiver capable of receiving images of both the current standard television system and the high-definition television system.

[Summary of the invention]

This invention provides a display device that has an aspect ratio of the high-definition television system, which is larger than that of the current standard television system, in a television receiver capable of receiving both the current standard television system and the high-definition television system. A receiver using this system receives high-definition television signals and current television signals with their respective aspect ratios, and the brightness of the blank area that occurs when receiving the current standard television signal is set in the opposite direction to the brightness of the current standard television signal. By providing a control circuit to the screen, it is possible to prevent uneven brightness of the screen caused by a difference in the amount of electron beam irradiation between the projected area and the margin area.

[Conventional technology]

High-definition television (HDTV) is being developed that can reproduce realistic, high-resolution images.

In high-definition television, the aspect ratio is (16:
9), the number of horizontal scanning lines is set to 1125. Such high-definition televisions have a vertical resolution of approximately 60
The number of transmission lines is 0 to 700, and a transmission band of about 20 MHz is required. This is 4.2M of the current NTSC system band.
This is approximately 5 times higher than Hz. Therefore, it is difficult to transmit high-definition television signals as they are, not only in the band of one channel of terrestrial broadcasting, but also in the band of one channel of satellite broadcasting.

Therefore, MUS E (multiple 5ub
-NyquisL saIlpling encodi
A band compression method called ng) method has been proposed.

According to the MUSE method, the baseband band of a high-definition television broadcast signal can be compressed to about 8 MHz.

It is also planned to broadcast high-definition television on a satellite broadcasting channel using the MUSE method. In addition, in preparation for the start of such high-definition television broadcasting, development of television receivers that can receive both the current NTSC system television broadcasting and high-definition television broadcasting is underway. .

In a television receiver capable of receiving both high-definition television broadcasting and NTSC television broadcasting, the aspect ratio of high-definition television is (1).
6:9) On the other hand, since the aspect ratio of an NTSC screen is (4:3), when an NTSC screen is displayed on a high-definition television screen, a blank area will appear on the screen. Become.

If such a blank area is kept at a constant brightness, the amount of electron beam irradiation will differ between the area where the screen is projected and the blank area, resulting in uneven brightness and color due to changes over time.

Therefore, US Pat.
The brightness of the blank area that occurs when displaying a screen using the C method,
By setting the brightness equal to the average brightness of the projected screen, the amount of electron beam irradiation is made equal between the projected area and the blank area, thereby preventing uneven brightness and color. Some methods have been proposed to prevent this.

[Problem to be solved by the invention]

However, when projecting an NTSC screen on the aspect ratio receiving screen of a high-definition television, if the brightness of the margin is equal to the average brightness of the screen being projected, the projected screen The difference between the image and the margin becomes unclear, making it difficult to create contrast.

Therefore, an object of the present invention is to provide a television receiver that can prevent uneven brightness and color that occur due to changes over time when an NTSC screen is projected on a high-definition television screen, and that can reproduce a screen with clear contrast. Our goal is to provide the following.

[Means to solve the problem]

This invention enables a receiver using a display device having an aspect ratio of a high-definition television system, which has a larger aspect ratio than the current standard television system, to receive a high-definition television signal and a current standard television signal at their respective aspect ratios. This television receiver is equipped with a circuit that controls the brightness of the blank space created when receiving the current standard television signal in the opposite direction to the brightness of the current standard television signal.

[Effect]

The brightness of a blank area that occurs when a receiving screen of NTSC television broadcasting is displayed on a picture tube of a high-definition television is controlled in the opposite direction to the brightness of the video area. Therefore, a screen with clear contrast can be reproduced, and the video portion 41 and the margin portions 42A and 42B are subject to the same deterioration due to changes over time, and uneven brightness and color can be prevented from occurring.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 shows an embodiment of the present invention.

In one embodiment of the present invention, for example, S with a frequency of 12 GHz
High-definition television broadcasting is sent using satellite broadcasting channels in the HF band, and current television broadcasting is sent using satellite broadcasting channels in the SHF band and channels from terrestrial broadcasting stations in the VHF and UHF bands. It is possible to receive both NTSC television broadcasts.

In FIG. 1, 1 is a parabolic antenna for receiving satellite television broadcast waves. NTSC system vision signals are FM-modulated and transmitted from geostationary satellites, and for several hours a day, high-definition television signals are transmitted via MU on a designated satellite broadcasting channel.
It is transmitted after being band-compressed on the SE side. Television broadcast waves from this geostationary satellite are received by a parabolic antenna l.

A signal received by the parabolic antenna 1 is converted into a BS-IF signal in the IGHz band, for example, by a converter (not shown).

This BS-IF multiplied signal is supplied to the SHF tuner circuit 2.

A desired satellite broadcasting channel is set by the SHF tuner circuit 2. That is, the SHF tuner circuit 2 receives the channel setting signal CH from the system controller 4.
When a desired satellite broadcasting channel is designated by the commander 5, a corresponding command signal is generated from the commander 5. This command signal is received by the receiving circuit 6, and is transmitted from the system controller 4. A channel setting signal CH3 corresponding to the channel setting signal CH3 is generated.

As a result, the SHF tuner circuit 2 is set to the desired satellite broadcast channel.

The output of the SHF tuner circuit 2 is supplied to the video detection circuit 7. The output of the video detection circuit 7 is supplied to an input terminal a of a switch circuit 8 and also to a MUSE decoder 9. Also, the output of SHF tuner circuit 2 is MUSE/
The signal is supplied to the NTSC detection circuit 3.

If NTSC television is currently being broadcast on the set satellite broadcasting channel, the video detection circuit 7 outputs an NTSC television signal.

In addition, if high-definition television broadcasting is currently being performed on the set satellite broadcasting channel, the video detection circuit 7
A high-definition television signal whose bandwidth has been compressed using the MUSE method is output from the FM terminal.

When high-definition television broadcasting is currently being performed on the set satellite broadcasting channel, the output of the video detection circuit 7 is supplied to the MUSE decoder 9;
A high-definition television signal band-compressed using the MUSE method is decoded.

This high-definition television signal has an aspect ratio of (
16:9), and the number of scanning lines is 1125. MUS
The E decoder 9 outputs decoded high-quality television three primary color signals R, , G, , B, as well as synchronization signals 5YNC, 4. These three primary color signals RH, GM, and BH are the switch 2 of the switch circuit 22.
A synchronizing signal 5YNCH is supplied to a input terminals of switches 2A to 22C, respectively, and a synchronizing signal 5YNCH is supplied to a of switch 22D of switch circuit 22.
is supplied to the input terminal.

Reference numeral 11 denotes a television antenna for receiving television radio waves from a terrestrial broadcasting station. The received signal of the television antenna 11 is transmitted to the UHF/VHF tuner circuit 12
is supplied to The UHF/VHF tuner circuit 12 sets a desired channel from among the terrestrial broadcast television channels. The υHF/V HF tuner circuit 12 is supplied with a channel setting signal CHUV from the system controller 4. This channel setting signal CHUV is generated based on the operation of the commander 5.

U) (The output of the F/VHF tuner circuit 12 is supplied to the video detection circuit 13.The video detection circuit 13 outputs the U HF/VHF tuner circuit 12.
The television signal of the selected channel is detected by the VHF tuner circuit 12, and the video signal from the video detection circuit 13 is
An NTSC television signal is output. The output of the video detection circuit 13 is supplied to the input terminal of the switch circuit 8.

The switch circuit 8 is switched by a switching signal SLI from the system controller 4 depending on whether satellite broadcasting is being received or terrestrial broadcasting is being received.

That is, when receiving a satellite broadcast, the switch circuit 8 is switched to the a side, and when receiving a terrestrial broadcast, the switch circuit 8 is switched to the b side.

From the switch circuit 8, when receiving satellite broadcasting, when an NTSC television signal is being transmitted on the set satellite broadcasting channel, the NT signal sent by the satellite broadcasting is transmitted.
An SC television signal is output. Also, when receiving terrestrial broadcasting, the NTSC of the set channel
A television signal of the same format is output.

The output of switch circuit 8 is supplied to Y/C separation circuit 14 . A Y/C separation circuit 14 separates the output of the switch circuit 8 into a luminance signal Y and a chroma signal C. The chroma signal C is supplied to the chroma demodulation circuit 15, and color difference signals RY and BY are demodulated from the chroma signal C.

Further, an NTSC television signal output from the switch circuit 8 is supplied to the synchronization signal detection circuit 23. A synchronization signal detection circuit 23 detects a synchronization signal. The output of the synchronization signal detection circuit 23 is the double-speed synchronization signal generation circuit 24
is supplied to A double-speed synchronization circuit 24 generates an NTSC synchronization signal in which the number of scanning lines is doubled, for example. The synchronization signal output from the double-speed synchronization signal generation circuit 24 is supplied to the system controller 4 and also to the b-side input terminal of the switch 22D of the switch circuit 22.

The luminance signal Y separated by the Y/C separation circuit 14 and the color difference signals RY and BY demodulated by the chroma demodulation circuit 15 are supplied to a horizontal time compression circuit 16. The horizontal time compression circuit 16 converts a high-definition television screen having an aspect ratio of (16:9) to a screen having an aspect ratio of (4:3).
In order to display an NTSC screen, the horizontal time axis is compressed. This horizontal time compression circuit 16 sets a margin on the screen.

Further, the luminance signal Y output from the Y/C separation circuit 14 is supplied to the level detection circuit 33. Level detection circuit 33
Then, the signal level of the luminance signal Y is detected. The level of the luminance signal detected by the level detection circuit 33 is inverted by the inversion circuit 24.
is inverted and supplied to the brightness variable circuit 35. The output level of the brightness variable circuit 35 is controlled by the output of the inversion circuit 34.

A timing signal WP is output from the system controller 4 in response to a blank period that occurs when displaying an NTSC screen. This timing signal WP is supplied to the switch circuit 36.

This timing signal WP turns on the switch circuit 36 during the margin period. During the margin period when the switch circuit 36 is on, a signal at the level set by the variable resistor 37 is sent to the adder circuits 21A to 21C via the brightness variable circuit 35.
is supplied to

The output of the horizontal time compression circuit 16 is supplied to a speed doubler circuit 17 . The scanning lines are interpolated by the double-speed circuit 17, and since the number of scanning lines is 525 and the NTSC system is interlaced scanning, a signal of non-interlaced scanning is formed, for example, with twice the number of scanning lines.

The output of the double speed circuit 17 is supplied to a color decoder 18. The color decoder 18 outputs a luminance signal Y and a color difference signal R-
Three primary color signals R1G and B are formed from Y and BY.

Three primary color signals R, G output from the color decoder 18,
B is supplied to adder circuits 21A, 21B, and 21C. In the adder circuits 21A to 21C, a brightness variable circuit 35 is installed in the blank area.
The output of is added. The outputs of the adder circuits 21A to 21C are supplied to the b@ input terminals of the switches 22A to 22D of the switch circuit 22, respectively. The outputs of the switches 22A to 22D are supplied via buffers 25A to 25C, respectively, to a picture tube 26 of a high-definition television having an aspect ratio of (16:9). The output of switch 22D is supplied to deflection circuit 27. The output of the deflection circuit 27 is transmitted to the picture tube 26.
deflection coil.

MUSE/NT checks whether high-definition television is currently being broadcast on the set satellite broadcasting channel.
It is detected from the SC detection circuit 3 output. Based on this detection output, a switch control signal SL2 is supplied from the system controller 4 to the switch circuit 22. This switch control signal SL2 causes each switch 22 of the switch circuit 22 to
A to 22D are switched respectively. That is, when high-definition television is being broadcast on the set satellite broadcasting channel, each switch 2 of the switch circuit 22
2A to 22D are each switched to the a side. If NTSC television is being broadcast on the set satellite broadcast channel, or if NTSC television is being broadcast from a terrestrial broadcasting station,
When receiving TSC television broadcasting, the switches 22A to 22D of the switch circuit 22 are switched to the b side.

When each of the switches 22A to 22D of the switch circuit 22 is switched to the a side, the three primary color signals R)l, GH, and BH from the MUSE decoder 9 are supplied to the picture tube 26 of the high-definition television, and the MUSE decoder The synchronizing signal 5YNCI4 from 9 is supplied to the deflection circuit 27. Therefore, the reception screen of the high-definition television broadcast is displayed on the entire screen of the picture tube 26 of the high-definition television.

When each of the switches 22A to 22D of the switch circuit 22 is switched to the b side, the three primary color signals R, G, and B of the color decoder 18 are supplied to the picture tube 26 of the high-definition television, and the double-speed synchronization signal generation circuit A synchronizing signal from 24 is supplied to a deflection circuit 27. Therefore, a receiving screen of the NTSC television broadcast is displayed on the picture tube 26 of the high-definition television.

As mentioned above, the picture tube 26 of a high-definition television is
When a receiving screen of TSC television broadcasting is projected, a blank area appears. A timing signal WP is output from the system controller 4 in correspondence with this margin.

The switch circuit 36 is turned on by this timing signal WP.

Then, during the margin period when the switch circuit 36 is turned on,
A signal at a level set by the variable resistor 37 is supplied to the adder circuits 21A to 21C via the brightness variable circuit 35.

The brightness variable circuit 35 is set based on the detected level of the brightness signal Y detected by the level detection circuit 33 and inverted by the inversion circuit 34. Therefore, the brightness of the margin portion is controlled in the opposite direction to the brightness of the video portion.

That is, as shown in FIG. 2A, when the brightness of the video portion 41 is bright, the brightness of the margin portions 42A and 42B becomes dark, and as shown in FIG. The brightness of the portions 42B and 42B becomes brighter.

In this way, the brightness of the margin portions 42A and 42B is controlled in the opposite direction to the brightness of the video portion 41, so that the west side with clear contrast can be reproduced.

In addition, since the brightness of the screen projected on the video portion 41 changes from the picture, if the brightness of the margin portions 42A and 42B is controlled in the opposite direction to the brightness of the video portion 41, the amount of electron beam irradiation due to use will be reduced. , the video portion 41 and the margin portions 42A and 42B are approximately equal. Therefore, the deterioration due to changes over time between the video portion 41 and the margin portions 42A and 42B becomes equal, and the occurrence of uneven brightness and color can be prevented.

〔Effect of the invention〕

According to this invention, the picture tube of a high-definition television has an NT
The brightness of the blank area that occurs when a receiving screen of an SC-type television broadcast is displayed is controlled in the opposite direction to the brightness of the video part. Therefore, a screen with clear contrast can be reproduced, and the deterioration due to aging is equal between the video portion and the margin portion, and the occurrence of uneven brightness and color can be prevented.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of the present invention, and FIG. 2 is a route map used to explain the embodiment of the invention. Explanation of main symbols in the drawing System controller. 33 Two-level detection circuit: Inversion circuit. 35: Brightness variable circuit. ;Video part. 42A. 2B Two blank spaces.

Claims (1)

[Claims] The above-mentioned high-definition television signal and the above-mentioned current standard television signal are received at respective aspect ratios by a receiver using a display device having an aspect ratio of a high-definition television system, which has an aspect ratio larger than that of the current standard television system. A television receiver is provided with a circuit for controlling the brightness of a blank space created when receiving the current standard television signal in a direction opposite to the brightness of the current standard television signal.