JPH073737Y2 - High definition television receiver - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention is a high-definition television receiver for receiving and reproducing a high-definition television signal formed by band compression and time-axis multiplexing of a fixed density subsampling method. Regarding the machine.

[Conventional technology]

Conventionally, the Time Compressed Integration signal (hereinafter referred to as TCI signal), which is one example of this kind of high-definition television signal, is a foundation commemorative lecture issued by NHK Research Institute, Broadcasting Science Laboratories, June 6, 1984. It is formed by band compression of subnakist sampling that makes a cycle of four fields and time-axis multiplexing, as described in the conference proceedings "New Transmission System for High-Definition Television (MUSE)".

On the other hand, a high-definition television receiver that receives and reproduces a TCI signal is shown in Figure 8 on page 8 of the above-mentioned draft, Figure 4 on page 116 of Nikkei Electronics March 12, 1984, and Technical Report of the Television Society of Japan. Hygiene 1 channel transmission system (MUSE) "TEBS95-2" of the same report, "BSD transmission system of high-definition television" TEBS91-5 as described in TEBS91-5 Has been done.

Since the playback process is performed digitally, the received TC
The I signal is digitized by the digital conversion unit (1),
A digital signal formed by digitizing the TCI signal is output from the digital converting unit (1) to the separating unit (2).

Further, the digital signal input to the separation unit (2) is separated into various digital signals such as digital video signals, audio signals, and motion vector information control signals.

Then, the video signal output from the separation unit (2) is input to the temporal interpolation circuit (4), the spatial interpolation circuit (5), and the synchronization control unit (6) provided in the video processing unit (3). The motion vector information control signal is input to the temporal interpolation circuit (4), and the interpolation circuit (4) interpolates the still image portion of the video signal based on the motion vector information control signal, and the spatial interpolation circuit (5). Interpolates the moving image portion of the video signal.

Further, the motion part detection circuit (7) of the processing unit (3) connected to the temporal interpolation circuit (4) detects the motion part of the video signal from the difference between the video signal of the previous frame and the video signal of the current frame. To detect.

Furthermore, the output signals of both interpolation circuits (4) and (5) are processed by the processing unit (3) based on the control of the detection signal of the detection circuit (7).
Is mixed by the mixing circuit (8), and is interpolated from the mixing circuit (8) to the TCI decoder (9) of the processing unit (3).
The video signal of CI signal type is output. The mixing ratio of the output signals of both interpolation circuits (4) and (5) is determined by the detection circuit (7).
It is set by the detection signal of.

Then, from the decoder (9) to the CRT (11) on the display unit (10)
, The video signal in the normal video signal format is output to the CRT
The reception screen is displayed in (11).

On the other hand, the synchronization control unit (6) counts the clock signals,
An internal synchronization signal for reproduction control of the receiver, that is, an internal frame pulse signal is formed, and a reproduction synchronization signal in the input video signal, that is, a synchronization loss between the reproduction frame pulse signal and the internal frame pulse signal is detected, The internal frame pulse signal is synchronously controlled with the reproduction frame pulse signal.

Furthermore, the digital audio signal output from the separation unit (2), that is, the PCM audio signal, is converted into an analog signal by the audio decoding unit (12), and a pair of speakers (from the decoding unit (12) to the audio output unit (13) ( Analog voice signals are output to 14a) and (14b), and voices received from the speakers (14a) and (14b) are reproduced and output.

The audio decoding section (12) is formed by an audio decoder circuit (12a) and an analog converter (12b) as shown in FIG. 7, and a PCM audio signal transmitted through the decoder circuit (12a) is converted into a converter (12b). ) Is converted into an analog voice signal.

[Problems to be solved by the invention]

By the way, when the reproduction frame pulse and the internal frame pulse are out of synchronization, at this time, the audio decoding unit (12)
Since the input signal is converted into an analog signal and output in the same manner as when there is no loss of synchronization, there is a problem that annoying noise is output from the audio output section (13).

[Means for solving problems]

This invention is a high-definition television receiver that receives and reproduces a high-definition television signal formed by band compression and time-axis multiplexing of a fixed density sub-sampling method, and converts the received high-definition television signal into a digital signal. A digital conversion unit, a separation unit that separates the digital signal of the conversion unit into various signals such as a digital video signal, an audio signal, and a control signal, and outputs the digital video signal by the digital video signal and the control signal. An out-of-sync signal is detected between the video processing unit that processes the signal and supplies an analog video signal to the screen display unit, and the playback sync signal included in the digital video signal and the internally generated internal sync signal for playback control. Then, a sync control unit for synchronously controlling the internal sync signal with the reproduction sync signal, and analog-converting the digital audio signal to output the audio. And an audio decoding unit for supplying an analog audio signal to the audio decoding unit, and the audio decoding unit performs a microcomputer control for the digital or analog audio signal during the occurrence of the out-of-sync by the out-of-sync detection signal of the synchronization control unit. It is a high-definition television receiver equipped with a means for meeting.

[Action]

Therefore, when the sync signal between the reproduction sync signal and the internal sync signal is lost, the audio control unit provided in the audio decoding unit controls the muting of the digital or analog audio signal by the out-of-sync detection signal of the sync control unit. , The analog audio signal supplied to the audio output unit is muted.

〔Example〕

Next, the present invention will be described in detail with reference to FIGS. 1 to 5 showing one embodiment thereof.

In FIG. 1, the same symbols as those in FIG. 6 indicate the same things, and (15) and (16) are synchronizations provided in place of the synchronization control unit (6) and audio decoding unit (12) in FIG. The control unit and the audio decoding unit.

As shown in FIG. 2, the synchronization controller (15) is formed by a frame pulse detection circuit (15a), a NOR gate (15b), an AND gate (15c), a counter (15d) and a frame pulse position comparator (15e). Then, the digital video signal of the separation unit (2) is input to the detection circuit (15a), and the reproduction synchronization signal included in the video signal is detected by the detection circuit (15a).
That is, only the reproduction frame pulse signal is extracted, and the detection circuit (15a) to the OR gate (15b) and the comparator (15
A reproduction frame pulse signal of logic 0 (hereinafter referred to as "0") is output to one input terminal of e) as shown in FIG. 3 (a).

In the TCI signal, one frame is formed by 1125 lines and each horizontal component is formed by 480 samples, and one reproduction frame pulse signal is output for each frame from the detection circuit (15a).

On the other hand, the counter (15d) counts the clock signal input to the clock terminal (ck), and also counts the clock signal for one frame based on a preset pulse signal described later input to the preset terminal (ps). “0” for each
The internal synchronization signal of, that is, the internal frame pulse signal of "0" shown in FIG. 3 (b) is output.

The internal frame pulse signal of the counter (15d) is fed to one input terminal of the AND gate (15c) and the comparator (15
The comparator (15e) compares the positions of both frame pulse signals and is input to the other input terminal of e), and when the positions of both frame pulse signals are different, that is, when the synchronization of both frame pulse signals is lost, " An out-of-sync detection signal of 0 "is output to the other input terminal of the OR gate (15b) and the audio decoding unit (16).

By the way, if there is no loss of synchronization and the positions of both frame pulse signals are the same, the output signal of the comparator (15e) is logical 1
(Hereinafter, referred to as “1”), which is input to the other input terminal of the AND gate (15c) at this time.
The output signal of 5b) is formed by the output signal of "1" of the comparator (15c).

And "1" of OR gate (15b) to AND gate (15c)
Output signal of the counter (15d) and the internal frame pulse signal of the counter (15d) are input, that is, the output signal of the AND gate (15c), that is, the preset terminal (ps) of the counter (15d).
The preset pulse signal input to the counter (15
It is formed by the internal frame pulse signal output from (d), and the counter (15
d) is preset every time the clock signal for one frame is counted.

On the other hand, although the reproduction frame pulse signal is output at ta time as shown in FIG. 3A, the internal frame pulse signal is delayed from ta time as shown in FIG.
When the two frame pulse signals are out of synchronization with each other, the comparator (15e) outputs t as shown in FIG. 3 (c).
An out-of-sync detection signal of "0" is output from ta "time between a time and ta 'time.

The reproduction frame pulse signal and the out-of-synchronization detection signal are input to the OR gate (15b), so that the reproduction frame pulse signal is output from the OR gate (15b), and the output signal of the AND gate (15c) is It changes according to the logical product, and a preset pulse signal is formed by the reproduction frame pulse signal at time tb in FIG. 3 (b).

Therefore, the counter (15d) is preset by the reproduction frame pulse signal, and at this time, the internal frame pulse signal is controlled synchronously with the reproduction frame pulse signal as shown in FIG. The output signal of the comparator (15e) is held at "1" again at tb 'as shown in FIG.

That is, the synchronization control unit (15) forms and outputs an internal frame pulse signal for reproduction control of the receiver by counting the clock signals, and when the reproduction frame pulse signal and the internal frame pulse signal are out of synchronization. , "0"
The internal frame pulse signal is synchronously controlled with the reproduction frame pulse signal based on the out-of-synchronization detection signal.

Next, the audio decoding section (16), as shown in FIG.
An audio decoding section (16a) similar to the audio decoder (12a) of FIG. 7, a miute circuit (16b) constituting audio miuteing means, and an analog converter (16c) similar to the analog converter (12b) of FIG. ) Is formed.

Then, the digital audio signal output from the separation unit (2), that is, the PCM audio signal is input to the mute circuit (16b) via the decoder (16a) and the comparator (15e) of the synchronization control unit (15). The output signal of the miute circuit (16
Entered in b). The PCM audio signal is N-bit PCM.
It is formed by signals.

By the way, the miute circuit (16b) is
AND gate (G ₁ ), (G ₂ ), the number of bits of the CM audio signal,
, (G _n ), each AND gate (G ₁ ) ~
The output signal of the comparator (15e) is input to one input terminal of (G _n ) and each AND gate (G ₁ ) to (G _n )
PCM output from the decoder (16a) to the other input terminal of
Each bit of the audio signal is input.

The reproduced frame pulse signal and an internal frame pulse signal is synchronized, while being held in the output signal "1" of the comparator (15e), each AND gate _{(G 1) ~ (G n} ) is turned on The PCM audio signal from the decoder (16a) is converted into the analog converter (16
c), an analog audio signal is output from the converter (16c) to the audio output unit (13), and the received audio is output from the speakers (14a) and (14b) of the audio output unit (13).

On the other hand, when the reproduction frame pulse signal and the internal frame pulse signal are out of synchronization, and the out-of-synchronization detection signal is output from the comparator (15c), the AND gates (G ₁ ) to (G _n )
Is turned off and the PCM audio signal of the decoder (16a) is muted and controlled, and the analog audio signal supplied to the audio output section (13) is muted while synchronization is lost.

Then, during out-of-synchronization, that is, while noise is generated, the PCM audio signal input to the analog converter (16c) is subjected to muting control, so that noise output from the speakers (14a) and (14b) due to out-of-synchronization occurs. To be prevented.

In the above embodiment, the audio muting means is formed by the muting circuit (16b) and the PCM audio signal output from the decoder (16a) to the analog converter (16c), that is, the digital audio signal is muted controlled. (16a) is provided before or after the converter (16c) with audio muting means to control the PCM audio signal input to the decoder (16a) or the analog audio signal output from the converter (16c). Good.

Further, it is needless to say that the present invention can be applied to a high-definition television receiver that receives and reproduces high-definition television signals other than TCI signals.

[Effect of device]

Therefore, according to the high-definition television receiver of the present invention, audio decoding is performed based on the out-of-synchronization detection signal output from the synchronization control unit (15) while the out-of-sync between the reproduction synchronization signal and the internal synchronization signal occurs. A digital audio signal input to the decoding section (16) or the decoding section (16) by the audio muting means provided in the section (16).
The output of noise due to loss of synchronization can be prevented by controlling the analog audio signal supplied from the audio output unit (13) to the audio output unit (13).

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the high-definition television receiver of the present invention, FIG. 2 is a detailed block diagram of the synchronization control unit of FIG. 1, and FIGS. 2 is a timing chart for explaining the operation, FIG. 4 is a detailed block diagram of the audio decoding unit of FIG. 1, FIG. 5 is a detailed wiring diagram of the miute circuit of FIG. 4, and FIG. 6 is a conventional high quality. FIG. 7 is a block diagram of the television receiver, and FIG. 7 is a detailed block diagram of the audio decoding unit of FIG. (1) ...... Digital conversion section, (2) ...... Separation section, (3)
...... Video signal processing unit, (10) …… Display unit, (13) …… Sound output unit, (15) …… Synchronization control unit, (16) …… Sound decoding unit, (16b) …… Mute circuit.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-55-161475 (JP, A) JP-A-56-24885 (JP, A) JP-A-51-52228 (JP, A) Nikkei Electronics, 1984 March 12 issue Nikkei BP

Claims (1)

[Scope of utility model registration request] 1. A high-definition television receiver for inputting a MUSE signal and converting it into a high-definition video signal, and a digital conversion section for digitally converting the MUSE signal, and an output of the digital conversion section as digital video information. Separating means for separating into digital audio information, separating frame synchronization information from the digital video information, forming and deriving internal frame synchronization information in synchronization with the frame synchronization information, and comparing the internal frame synchronization information with the frame synchronization information. A synchronization control unit for detecting a phase shift and generating a phase shift detection signal, and a voice decoding unit for processing the digital voice information to derive an analog voice signal are provided, and the phase shift detection signal is provided in the voice decoding unit. Based on this, a mute circuit that mutes the audio signal digitally or analog is provided. High-definition television receiver as a feature.