DE3331076A1 - ARRANGEMENT FOR DEMODULATING THE TELEVISION TONE - Google Patents

Description

RCA 77 4-31 Ks / Ri - 6 -

U.S. Serial Nos:

412.902 - August 30, 19 «2
437,826 - October 29, '1982
412,898 - August 30, 1982

RCA Corporation New York, Ν.ϊ., V ₀ St ₀ V ₀ Ao

Arrangement for demodulating the television sound

The invention relates to television audio processing, and more particularly relates to one Phase-locked loop (PLL) involved in the frequency conversion for demodulating the audio information.

A multi-channel sound transmission for stereophonic and Bilingual television broadcasts requires the use of one or more audio sub-carriers, which means that the Bandwidth of the television audio signal from 15 kHz to approximately 90 kHz or more enlarged. This brings with it the risk that the so-called "sound creaking" that occurs in the processing channel of the sound signal arises, becomes more pronounced.

The aforementioned buzzing sound is the result of a modulation which is dependent on the picture content and which is transferred to the sound signal. This disorder is present to some extent always in television signal processing circuits, however, by various circuit measures innerha7 "-;. Fierierbarer limits are held _o

In the early days of television technology, the © picture- and audio signals in separate, similar to the tuner

Channels processed. Such separate processing prevents significant interaction between the Video and sound carriers within the television receiver, reducing the risk of sound rasping in the receiver is significantly reduced «Unfortunately, however, it happens before that frequency fluctuations of the local local oscillator in the tuner as a result of drift or automatic Fine tuning (AFA) affect the intermediate frequency sound carrier and the intermediate frequency picture carrier and from the sound frequency demodulator as sound interference (buzzing) be demodulated “Since the sound channel is also a lot has a narrower pass band than the image channel, the receiver has to work best with the processing method mentioned Sound reproduction and not adjusted for the best picture reproduction.

Modern television receivers almost generally use the so-called intercarrier method for audio signal processing. With this method, the video and sound carriers behind the tuner are processed in a common intermediate frequency channel (IF channel), which has a special IF band filter characteristic that on the one hand attenuates the sound carrier by around 20 dB more than the video carrier and on the other hand it is dimensioned in this way is that the image carrier falls on the flank at the high-frequency end of the IF = passband, namely at a location that is attenuated by 6 db the two IF carriers are mixed to form an intercarrier tone signal, the frequency of which corresponds to the difference between the frequencies of the two IF carriers. In the NTSC system, for example, a ^z f-5.75 ~ MHz picture carrier is mixed with a 4-1.25 MHz sound carrier in order to generate a 4-5 MHz intercarrier signal. “This is why the intercarrier method is special advantageous «, because common-mode frequency modulations in audio and video carriers (which, for example, are caused by

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Changes in the superimposed signal in the tuner of the television receiver itself or in additional devices coupled to the receiver such as a remote converter for cable transmission) canceled out by the mixing that takes place in the IF range when the intercarrier tone signal is derived will. However, the intercarrier method is not free from rubbish. While the above-mentioned intercarrier IF bandpass characteristic is necessary for the correct detection of the image carrier, on the other hand it leads to the fact that the sound creaking is essential becomes stronger than in the case of the processing of video and sound carriers in separate channels »This is because that, on the one hand, the sound carrier is considerably attenuated and thus the Rauscbstrand of the sound signal is reduced and that on the other hand, the sidebands of the IF picture carrier are attenuated unequally, resulting in an accompanying synchronous phase modulation (SPM or englo ICPM) results in the image carrier, commonly referred to as "Nyquist SPM", which distorts the audio signal during intercarrier mixing. aside from that it can happen with the intercarrier method that a high degree of modulation or overmodulation of the video carrier (such as usually when inserting image overlays can be caused by local daughter stations) the Video carrier signal is eliminated and causes a buzzing sound with line frequency and field frequency (i.e. with 15 7? 4 Hz and 60 Hz in the case of the NTSC system). The problem of the creaking in the Int.ercarrier method is more detailed in an essay by P “Fockens and C.G. Eilers "Intercarrier Buzz Phenomena Analysis and Cure "discussed in the journal IEEE Transactions on Consumer Electronics, August 1981, pages 3 ^ 1-397.

The sound creaking generated by an intercarrier system can be tolerated in monophonic television receivers, because the pass band of the sound channel in such BiröfÜna-ern is relatively narrow. Unfortunately, however, with the higher audio signal bandwidth of a multi-channel To η transmission, the creaking increases and no longer remains within tolerable limits. _o ο "

It is known that working with separate channels system and intercarrier system to combine with each other to Tonsignalerfassung _o Such a combined system, which can be referred to as "split Inter Carrier", is in the above-mentioned article by P. Eockens and CG. Eilers describes ο Here, after the tuner, the video carrier signal is processed separately from the audio carrier signal in order to derive the video information. However, the IF carriers for video and audio are processed together in one audio channel in order to derive the audio information according to the intercarrier system described above With this combined system, the ZP filter characteristic required to detect the video residual sideband signal is not present in the audio channel, the sound creaking caused by the Nyquist SPM is practically eliminated.Because on the other hand, however, the intercarrier method is also used, the IF carriers for picture and sound are combined processed in the ZIP gain channel. Non-linear effects within the ZE amplifier and the degree of image modulation can cause the audio signal to interfere with the image signal and thus represent two sources of creaking noise that can be assigned to the intercarrier system and that are not eliminated and needed a discriminator

The present invention is directed to creating an arrangement for audio signal detection, which with as possible Combines the advantages of separate carrier processing and the intercarrier method with little circuit effort, without having to accept the one-offs.

The essential features of an arrangement according to the invention are listed in claim 1. Advantageous refinements of the invention are identified in the sub-statements.

An arrangement according to the invention for recovering the audio information from a television signal, which image and

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-Ιοί tone carrier signals in the intermediate frequency range (IF signals) contains, has a controllable oscillator for generating an output signal of controlled frequency and a frequency-converting oscillator phase-locked loop (PLL), which contains a frequency mixer and a phase detector. The mixer receives the output signal of the oscillator at its one input and the IF video carrier signal at its other input. The phase detector receives the IF audio signal at its one input and the other input the output signal of the mixer »The phase-synchronized The loop is completed by a low-pass filter placed between the output of the phase detector and a control input of the oscillator is connected and applies a control signal to the oscillator to increase the frequency of the oscillator output signal. The demodulated Toηinformation appears at the output of the low-pass filter. In the case of the PLL system under discussion here, it is practical to use the arrangement for detecting the television signal also provide an arrangement that indicates the presence of impulse noise in the video signal »

The invention is illustrated below using exemplary embodiments explained in more detail by drawings »

Figo 1 shows in block form the structure of a television receiver, which contains an arrangement according to the invention for audio signal detection;

Fig. 2 shows in block form a television receiver, the one Another embodiment of a sound signal detection device according to the invention with a frequency-converting device phase locked loop includes;

FIG. 3 shows a block diagram of an alternative embodiment of a loop that is synchronized with the frequency-converting path and operates the anorafjmig for audio signal detection for the television receiver according to FIG. 1 according to the invention;

Figo 4 shows in block form the circuit of a television receiver, of a further embodiment of the invention with a device for supplying a contains the signal indicative of impulse noise.

In the receiver according to FIG. 1, a television broadcast signal picked up by an antenna 8 is sent to a tuner 10 which contains a radio frequency amplifier (RF amplifier) 12, a mixer 14 and a local oscillator 16. The tuner 10 converts the HF carrier signals for picture and sound into IF carrier signals, namely the picture carrier to 45.75 MHz and the sound carrier to 41 ₅ 25 MHz in the case of the NTSC system. The IF carriers are available at output 18 of the tuner. The IF picture carrier of 45.75 MHz is basically an amplitude-modulated signal which contains the composite video information (composite video signal). The IF sound carrier of 41.25 MHz is a frequency-modulated signal. Conventional color television signal processing circuitry, including an IF filter and gain channel 20, a video detector 22, and a video signal processing device 24, is responsive to the IF picture carrier from terminal 18 to generate red (R), green, video signals (G) and blue (B) to be supplied to a picture tube (not shown) so that a color picture of the television scene is displayed.

In addition, a coordinated limiter / amplifier stage provides 26 a suitably filtered, amplified and limited version of the IF picture carrier signal to the video detector 22, which demodulates the composite video signal from the IF picture carrier by synchronous demodulation o That at the output of the limiter / Amplifier stage 26 supplied IF picture carrier signal also via a 90 phase shifter 30 to a detector 28 for automatic fine tuning (AFA) to receive an AFA control signal at the output of this detector, which is applied to the local oscillator 16. In this way it is achieved that the frequency and the phase of the frequency beat signal applied to mixer 14 and follow the phase of the received RF picture carrier.

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The structure and operation of the video detector 22, the amplifier / limiter stage 26, the Ai ¹ A detector 28 and the phase shifter 30 are described in more detail in the US Patent 4 263 611.

The IF channel 20 has the usual transmission characteristics, as shown by curve 32. The IF picture carrier P is at a location that is attenuated by 6 db on the higher-frequency flank of the transmission characteristic 32, and the IF sound carrier S is at a location that is attenuated by about 25 db on the lower flank of the characteristic 32 can be demodulated by the IF sound carrier without significant interference. Unfortunately, the IF passband 32 system intercarrier leads due to the asymmetrical attenuation of the side bands of the IF BiIdträgers to the already above-mentioned Nyquist SPM (synchronous phase modulation) of the IF picture carrier _o In the conventional to Tonsignalerfassung brings these Nyquist SPM of the IF Image carrier a distortion of the intercarrier audio signal, namely because of the mixing of the IF audio carrier with the IF video carrier that takes place in this system. This distortion of the intercarrier audio signal results in the above-mentioned creaking _o The amount of creaking caused by the Nyquist SPM increases in direct relation to the increase in the bandwidth of the audio signal. If one considers that the bandwidth of a composite audio signal, which contains several subcarriers for the transmission of, for example, monophonic, stereophonic and second-tone programs, is considerably larger than the bandwidth of the monophonic signal, which is usually processed by an intercarrier system, then is It is clear that the intercarrier method of audio signal acquisition can be problematic in such cases, because c, ■ _.__. /

In accordance with the present invention, the ZF-3? Oiager in processed a way that from the processing un-jsseäaltung

for the IF picture carrier is separated, and the composite audio signal is demodulated by a frequency-converting phase-locked loop (PLL) 53. Correspondingly, the ZP carriers available at the terminal 18 for picture and sound are applied to a picture band filter 36 and a sound band filter 38 via a buffer 34 and a connection A in order to obtain the sound information. The image bandpass filter 36 has a symmetrical, relatively narrow (eg 1 MHz wide) bandpass characteristic 37 * which is centered on the IF image carrier _{frequency (z o} B "4-5.75 MHz in the NTSC system) to essentially only that IF picture carrier signal to pass through α An IF amplifier 4-0 and a limiter 4-2 effect a suitable amplification and limitation of the IF picture carrier signal and apply the resulting limited and therefore essentially unmodulated IF picture carrier to an input of a frequency mixer 4-4- »

The tone band filter 38 has a symmetrical, relatively narrow (z »Bo 1 MHz wide) bandpass characteristic 39, which is centered on the ZP tone carrier frequency (z ₀ B ₀ 4-1.25 MHz in the NTSC system) to im essentially only transmit the ZP-sound carrier signal which wirdo optionally after suitable amplification in an iF amplifier 4-6 to an input of a phase detector 4-8 the iF Ver strengthening it 4-0 and 46 may be constructed identically and z "B _o each consist of an integrated circuit such as the TA7607 module from the manufacturer Tokyo Shibaura Electric Co =>, Ltd »«. The limiter 4-2 can be formed simply by Schottky barrier diodes connected in parallel and polarized in opposite directions. A conventional circuit 4-7 for automatic gain control (AVE) responds to the output signal of the ZP amplifier 4-6 (or alternatively to the output signal of the amplifier 4-0) to AVR control voltages to the ZP amplifier 4-0 and 4-6 and thus to control their gain so that their output signals are kept at predetermined levels.

A voltage controlled oscillator 50 with varactor tuning

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The nominal oscillation frequency ζ of which is equal to the difference between the frequencies of the IF picture carrier and the IF sound carrier (e.g. equal to 4.5 MHz in the NTSC system) is applied to a second input of the mixer 44. The mixer 44 can, for example, be a double symmetrical one be an analog multiplier circuit such as the module MC1496 from Motorola Semiconductor Products, Inc. and works in a switching mode under control by the amplitude-limited IF picture carrier (which acts as a switching control signal) in order to mix the IF picture carrier signal with the output signal of the voltage-controlled oscillator 50 and to provide at its output a signal which represents the frequency and phase differences between its input signals. The frequency difference between the input signals of the mixer 44 is equal to 41.25 MHz ", This 41 ₉ 25 MHz output signal of the mixer 44 is applied to a second input of the phase detector 48, which can also be an integrated circuit of the type MC1496 mentioned above" The phase detector provides an output signal whose amplitude changes in direct relation to the phase difference between its input signals. Thus, the phase detector 48 works as an FM demodulator for the frequency-modulated IF sound carrier applied to its first input by the amplifier 46 and delivers a composite baseband sound signal at its output (together with undesired signals resulting from the demodulation process). A more detailed description of the operation of analog multiplier circuits as FM demodulators can be found in an article by A. Bilotti "Applications of a Monolithic Analog Multiplier", which is printed in the IEEE Journal of Solid State Circuits, December 1968, pages 373-380.

A connected to the output of the phase detector 48 gekoK _v i low-pass filter 52 generates by filtering the Detel ^ tor output signal a control signal for controlling the fr@cfJ.enz the voltage controlled oscillator 50 _o The mixer 4-4 ₉ of the phase detector 48, the voltage controlled oscillator 50

and the low-pass filter 52 form the frequency converting one phase-locked loop (PLL) 53 «The low-pass filter 52 has sufficient bandwidth to accommodate the composite Select the baseband audio signal (and suppress the higher-frequency unwanted signals). This selected The composite audio signal is applied to a stereo decoder 54, for example, in the case of the composite audio signal contains stereophonic information, the decoder 54- decodes this signal and delivers the stereo signals for the left and right to associated speakers 56 and 58. IaIIs none Stereo information is contained, the decoder supplies 54-das monophonic signal to the speakers.

In operation of the mixers 4-4 causes a frequency conversion of its input applied IF BiI dträg he sign as and provides at its output a signal whose frequency is the difference between the frequencies of its two gangs A sign ale .entspricht (ZOB _o 4-1 , 25 MHz) ₀ Unwanted output signals that correspond to the input signals coupled through and the sum of the input signals are attenuated as a result of the relatively narrow bandwidth of the low-pass filter 52. The amplitude of the output voltage of the phase detector 4-8 is a measure of the phase difference between its input signals. After filtering in the low-pass filter 52, this output voltage is applied to the voltage-controlled oscillator 50 as control voltage Direction to reduce the phase difference between the signals at the inputs of the phase detector s 4-8. If the input signals of the phase detector 4-8 have a phase difference of 90 ° (ie. Are in phase quadrature), then the control voltage applied to the voltage controlled oscillator 50 has a minimum amplitude. Therefore, because of the feedback nature of loop 53 in the case of its synchronized state, the control voltage at the output of filter 52 corresponds to the audio information and is such that the frequency

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The frequency of the converted difference signal at the output of the mixer 44 is equal to the mean frequency of the IF sound carrier and that the phase of this Differenζsignals is in quadrature to the phase of the IF sound carrier. The phase detector 48 thus acts as an FM demodulator for frequency demodulating the IF sound carrier. In addition, the common mode frequency modulation, the picture and the sound carrier, for _o example, by the local oscillator 16 of the be tuner or imprinted setter by lying in front of the tuner 10 additional devices such as a television, transmitted in the converted difference signal and thus in the phase detector 48 extinguished.

The described system for audio demodulation is advantageous because the predetermined Frequenζabstand between the IF picture and sound carriers for is utilized, _o in order to allow a simplified tuning of the receiver In addition, each common-frequency modulation is wiped out of the IF carrier. Furthermore, the demodulation method described prevents a Nyquist SPM of the picture carrier, which occurs because of the position of this carrier in the area of the upper edge of the IF transmission range, from leading to a creak. The processing channels for picture and sound are separated immediately after the tuner 10. In the audio processing channel, the image bandpass filter 36 symmetrically attenuates the sidebands of the IF image carrier and thus prevents a sound creak caused by Nyquist-SPM. In addition, the bandpass characteristic 37 of this filter is narrow enough to significantly attenuate those components of the video signal which are at frequencies corresponding to the second and third subharmonics of 4.5 MHz (e.g. 2.25 MHz and 1.5 MHz in the case of the NTSC Systems with the IF frame rate of 45.75 MHz). Since the frequency of the output signal of the voltage controlled oscillator 50 also is 4.5 MHz, Tonfrequer be - ■■ * Jullschwebungen at the output of the mixer 44 prevents "Thus, it is another cause of image conditional Tonschnarren _s as it is inherent in an intercarrier system virtually eliminated.

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Compared to the intercarrier system, where the transmission characteristic of the IF channel reduces the IF sound carrier by about 25 db attenuates, so that the signal-to-noise ratio in the audio channel is worsened, leaves the audio band filter in the system described here 38 the IF sound carrier relatively undamped to the Ζϊ amplifier 46 durctu Thus the amplitude level of the sound carrier is up about 25 db higher than the intercarrier system, and the signal to noise ratio of the demodulated audio signal is for one given HP signal level correspondingly better.

It should also be mentioned that in the system described, neither an intercarrier Ver nor an intercarrier discriminator or the resonance circuits associated with such circuits are required because no intercarrier audio signal is produced"

It should be noted that the input sign air. * Of the mixer 44 and of the phase detector 48 have such amplitude levels that the input circuits of these circuits in the first place address the frequency and phase of the input signals. This inherently suppresses amplitude modulations of the IF picture carrier * Although at the exit the phase detector s 4-8 also emits a buzzing frequency signal (82.5 MHz), its modulation is s-envelope in essentially symmetrical and therefore has no noticeable influence on the audio baseband frequencies en *. Therefore, the limiting action of the limiter 42 cannot be as large as required in an intercarrier system. This On the one hand, a lower degree of limitation reduces the probability Image-related line and field-frequency sound snarling, which is caused by a high degree of modulation of the ZIP-Bi 1 dtr ag he s can be caused, and on the other hand the Generation of harmonics that deal with the output signal of the voltage controlled oscillator 50 and can cause distortion in the audio frequency band.

In another embodiment, the IF picture carrier can be on

Output of limiter / amplifier stage 26 via the connection point B are coupled to the mixer 44 and thereby form the switching control signal for the mixer. The circuit arrangement between points A and B can then be omitted. However, in this case it is the IF gain channel 20 is part of the device for tone demodulation, the Nyquist SPM is not bypassed, so this embodiment can be used to demodulate a broadband composite Sound signal is not suitable «Since, however, the IF sound carrier in this embodiment is also relatively low Attenuation generated still remains a substantial improvement in signal-to-noise ratio, if relative Narrowband audio signals such as a monophonic audio signal can be demodulated.

Whereas in the embodiment according to FIG. 1 separate IF amplifiers 40 and 46 are provided, a common IF amplifier can also be used to control the output of the buffer 34 supplied IF carrier for picture and sound as described below.

In the receiver according to FIG. 2, a television broadcast signal picked up by an antenna 108 is given to a television tuner 110 which contains an RF amplifier 112, a mixer 114 and a local oscillator 116. The tuner 110 converts the HF carriers for picture and sound of a selected television channel to IF carriers, for example to 45.75 MHz for the picture carrier and 41.25 MHz for the sound carrier in the case of the NTSO system. These are IF carrier at the output terminal 118 of the tuner for grouting _β The IF picture carrier of 45.75 MHz is basically an amplitude modulated signal (AM signal) containing the composite video information (video signal). The IF Tontxö _'0 ör of 41.25 MHz is a frequency modulated signal (FM signal). A conventional color television signal processing circuitry comprising a filtering and amplifying IF channel 120, an IF video detector 122 and a video signal processing unit 124

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contains, responds to the IF picture carrier at terminal 118 to video signals for the colors red (R), green (G) and blue (B) for driving a picture tube (not shown) to provide a color picture of the television scene is »In addition, a matched limiter / amplifier stage 126 provides a suitably filtered, amplified and limited version of the IF picture carrier signal to the video detector 122 to convert the composite video signal by synchronous demodulation demodulate from the IF picture carrier. The ZF picture carrier from the output of the limiter / amplifier stage 126 is also shifted through a 90 ° phase 130 to a detector 128 for automatic fine tuning (AFA) given to. an AFA control signal at the output of this AFA detector to generate the local oscillator 116 applied will. In this way, the frequency and phase of the beat signal applied to mixer 114 will track the frequency and the phase of the received RF picture carrier. The construction and operation of video detector 122, the limiter / amplifier stage 126, AFA detector 128, and phase shifter 130 is more detailed in U.S. Patent 4- 263 611 described »

The IF channel 120 has the usual bandpass characteristics as it is represented by curve 132. The IF picture carrier P is at a location that is attenuated by 6 db on the higher frequency Edge of the characteristic curve 132, and the IF sound carrier S is at a location that has been attenuated by approximately 25 db the lower-frequency edge of the characteristic curve 132. Thus, can Video information of the remaining sideband without significant interference be demodulated by the IF sound carrier. As explained above, the bandpass characteristic 132 causes s the asymmetrical attenuation of the sidebands of the IF picture carrier is a synchronous phase modulation called "Nyquist SPM" of the ZF picture carrier.

In the case of FIG. 2, too, the audio signal is οdulated to denote the IF sound carrier is processed in a way that is separate from

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the processing circuits for the ZI picture carrier is, and the composite audio signal is demodulated by a frequency-converting phase-locked loop (PLL) 157. In the embodiment according to Pig «, 2, the amplification suitable for controlling the phase-synchronized loop 157 takes place the ZP image carrier and the ZF sound carrier in one common IF amplifier »In detail, the two IF carrier available at connection 118 for picture and sound via a buffer amplifier 134 and a filter 136 to a single one IF amplifier 138 given “The filter 136 has a double humped (i.e., having two peaks) bandpass characteristic with a substantially symmetrical and relatively narrow (e.g. having a 3 db bandwidth of 1 MHz) part 137a, which is based on the IF picture carrier frequency P is centered, and an essentially symmetrical and relatively narrow (e.g. having a 3-db bandwidth of 1 MHz) Part 137b, which centers on the IF sound carrier frequency is to select the video and the sound carrier and pass relatively undamped to the ZI amplifier 138.

The filter 136 ensures that the amounts of the picture and the sound carrier maintain their mutual relationship, and may be a conventionally constructed resonant circuit of discrete elements or a working surface acoustic wave filter such as ₃ B _ffl the filter F1322 manufacturer Tokyo Shibaura Electric Co ., Ltd. be. The IF amplifier 138 provides a linear amplification of the picture and sound carriers and contains an automatic gain control circuit to regulate the gain of the amplifier so that the output signals of the amplifier remain at predetermined levels.

The output of the IF amplifier 138 is fed via a buffer amplifier 140 and a limiter 142 an ampI_vu & @ nlimited and therefore essentially unmodulated image carrier obtained and applied to an input 14-3 of a mixer 144. A filter 146, a buffer amplifier 148 and a limiter 150 essentially only transmit the ZF TontrSg @; e as one

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Input 151 of a phase detector 152. The limiters 142 and 150 can be formed simply by oppositely polarized Schottky barrier diodes connected in parallel. The filter 14-6 can be a bandstop filter consisting of discrete elements, the center frequency of which is tuned in such a way that that the frequency response shown with the curve 17 ^ results in a maximum attenuation at the IF picture carrier frequency P and minimal attenuation at the sound carrier frequency S.

A voltage controlled oscillator 154 with varactor tuning, whose nominal oscillation frequency is equal to the difference between the frequencies of the IF carrier for picture and sound (zoBo equals 4.5 MHz for the NTSC system) a second input to the mixer 14-4-, namely at Connection 14-5ο The mixer 14-4- can e.g. be a double-symmetrical analog multiplier circuit like e.g. the module MC14-96 from Motorola Semiconductor Products, Inc., which operates in a switching mode due to the amplitude-limited IF picture carrier from the limiter 14-2 (i.e. this carrier forms the switching control signal) -, The mixer 144 mixes the IF picture carrier signal with the output signal of the voltage controlled Oscillator 154- and delivers a frequency-converted signal at its output, which the frequency and Phase difference between its input signals. The frequency difference between the input signals to the mixer 14-4- equals 4-1.25 MHz «This 4-1.25 MHz output signal of the mixer 14-4- is connected to a second input 153 of the phase detector 152, which can also be an integrated circuit of the type MC14-96. The phase detector 152 provides an output signal, the amplitude of which is in direct relation to the phase difference of its two input signals changes. The detector 152 thus works as an FM demodulator for the applied frequency-modulated IF sound carrier and delivers the composite at its output Audio signal in the baseband (together with unwanted signals resulting from the demodulation process).

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One coupled to the output of phase detector 152 Low pass filter 156 filters the output of the phase detector 152 to generate a control signal for influencing the Frequency of the voltage controlled oscillator 154 The mixer 154, the phase detector 152, the voltage controlled Oscillator 154 and low pass filter 156 form the frequency-converting phase-locked loop 157 The low-pass filter 156 has a sufficiently large bandwidth to select the composite baseband audio signal (while suppressing the higher frequency unwanted signals). This selected composite audio signal is applied to a stereo decoder 158, for example. Palis the compound Audio signal contains stereophonic ^ information, the decoder 158 decodes this signal to the To give stereo signals for left and right to a respective assigned loudspeaker 160 or 162. Ain't no If stereo information is present, then the decoder delivers 158 the monophonic signal to the loudspeakers.

In operation, the limiter 14-2 responds to the signal of the highest amplitude at its input. Both in television broadcasting and in cable distribution networks, the transmitted sound carrier is attenuated by at least 8 db compared to the amplitude of the video carrier. Since the filter 136 maintains this amplitude ratio of the two carriers, the limiter 142 essentially only selects the image carrier from the output of the amplifier 138 and applies it to the mixer 144, essentially unmodulated. Instead of the limiter 142, a band filter or a bandstop filter could also be used, However, such circuits can not easily such as a diode limiter circuit are housed in an integrated circuit die, and may also not represented by - model press imposed amplitude modulation ^ ^'3 A- video information.

As mentioned above, the mixer 144 effects a frequency conversion of the ZF image carrier applied to its entrance and

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provides an output signal, the frequency of which is the difference between the frequencies of its input signals (e.g. 4-1.25 MHz) at input 153 of the phase detector 152 “At the output of the mixer 14-4, unwanted ones also appear Output signals, namely coupled-through components of the input signals and a signal with the sum frequency of the input signals » The relatively narrow bandwidth of the low pass filter 156, however, prevents these unwanted signals reach decoder 158.

The filter 14-6 ″ causes the image carrier to be attenuated the sound carrier, and the limiter 150 speaks on the here with the larger amplitude appearing sound carrier and essentially only delivers the sound carrier to the input 151 of the phase detector 152 '. The amplitude of the output voltage of the phase detector 152 is a measure of the Phase difference between its input signals. These Output voltage is filtered in the low pass filter 156 and then as control voltage to the voltage controlled oscillator 154- laid »The output frequency of this oscillator 154 · and thus the signal converted to 4-1.25 MHz from mixer 144 changes in direct relation to the amplitude of the control voltage in the sense of reducing the phase difference between the signals at the inputs of the phase detector

152. When the inputs to detector 152 are in phase quadrature (i.e. »have a phase difference of 90 °), then that has applied to the voltage controlled oscillator 154- Control your voltage minimum amplitude «, Because of the feedback nature of the loop 157 in its synchronized state, speaks the control voltage at the output of the low-pass filter 156 of the audio information and is such that the frequency of the converted signal (difference frequency) at the output of the mixer 14-4 is the same the mean frequency of the IF sound carrier and that the phase of this signal is in quadrature to the phase of the IF sound carrier is. The phase detector 152 thus operates as an FM demodulator for frequency demodulating the IF sound carrier.

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Any common mode frequency modulations affecting the two Carriers for picture and sound can be impressed, e.g. by the local oscillator 116 in the tuner or by Additional devices such as a cable television frequency converter upstream of the tuner 110 are converted into the Difference signal transmitted and therefore in the phase detector extinguished"

Since in the embodiment of FIG. 2, a single IF amplifier is used to appropriately amplified image and sound carrier signals to the frequency-converting phase-synchronized To provide loop 157, this embodiment is less complicated and therefore less expensive than the one above embodiment described.

The input signals of the mixer 144 and the phase detector 148 have amplitude values such that the input circuits of these circuits primarily respond to the frequency and phase of the input signals and not to the amplitudes. A suppression of the amplitude modulation of the IF picture carrier is thus achieved by itself. It should also be mentioned that although a sum frequency signal (82.5 MHz) appears at the output of the phase detector 152, the modulation envelope of this signal is essentially symmetrical and therefore has no noticeable influence on the audio baseband frequencies not to be as large as required in an intercarrier system. This lower degree of limitation has two positive consequences: on the one hand, the probability of the occurrence of image-related line- and field-frequency sound rattling due to a high degree of modulation of the IF picture carrier is smaller, and on the other hand, the generation of harmonics is reduced, which is related to the output3: ^ ial the voltage controlled oscillator 154 can mix and ^1r arzerrungen in the audio frequency band effect.

The above-described arrangement for probe eodulation

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can, from the IF amplifier 138 to the decoder 158 (apart from from filter 14-6), advantageously in a single integrated Circuit can be realized. The limiters 142 and 150 can be formed by diode circuits. The filters 136 and 14-6 can be made using relatively inexpensive resonant circuits can be realized, since the demands on their damping quality are less high.

In an alternative embodiment, the limiter 150 can be omitted; however, the filter 146 must then have a correspondingly higher attenuation at the picture carrier frequency P in order to compensate for the lack of the additional signal suppression effect of the limiter 150. This can easily be achieved by adjusting the resonant circuit components of the filter 146. In addition, the filter 146 can be designed as a relatively narrow band-ended Cz ₀ B ₅ , 500 kHz) band-pass filter, the transmission curve 164 of which is centered on the sound carrier frequency S and which results in strong attenuation the video carrier frequency P has «

The alternatives described above represent various possibilities for attenuating and reducing the image carrier prevent this carrier at the input 15I of the phase detector 152 appears »If the picture carrier at this input is not sufficiently attenuated, then a mixture of the image carrier component appearing there with the through-coupled Image carrier component take place from the output of the mixer 144 and lead to a zero beat in the output signal that is within of the audio frequency range and would therefore distort the audio information »

FIG _o 3 shows an alternative embodiment for the ^ ondemodulationssystem of the television receiver according to Fig. 2. In Fig, "3, elements, each in structure and operation elements of FIG. 2 correspond, with the same reference numerals as therein. Between the output of the mixer 144 and the input 153 of the phase detector 152

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A filter 166 is inserted in order to attenuate the picture carrier substantially and to allow the sound carrier to pass through. Hence are facilities like filter 14-6 and / or limiter 150 according to FIG. 2, - which ensure the selective application of the sound carrier to the input 151 of the phase detector 152, here not mandatory. The filter 166 can be a bandstop filter with a frequency response represented by the curve 167 be the maximum signal suppression at the video carrier frequency P and a minimum attenuation at the audio carrier frequency As an alternative, a relatively narrow-band (e.g. 500 kHz) band filter can be used for the filter 166 j that has the bandpass characteristic shown by curve 168, the center frequency of which is at the sound carrier frequency S lies and which brings about a substantial attenuation at the picture carrier frequency P.

In the embodiments described above, the IF picture carriers delivered at the output of the television tuner are processed in a separate IF channel to convert the video information derive. The audio information is demodulated with the help of a frequency-converting phase-locked loop (PLL), which contains a mixer and a phase detector, wherein the mixer to the IF picture carrier from the output of the tuner and the phase detector to the IF sound carrier from the output of the Tuners appeals.

An embodiment will now be described which detects noise in the video signal and recovers the audio information from a television signal by means of a 7.0 arrangement which contains a single phase-locked loop and which can be easily fabricated as an integrated circuit.

According to Fig. 4-, one captured by an antenna 2J8. Television broadcast signal applied to a tuner 210 ₉ which converts the HF carriers for picture and sound of a selected television channel to intermediate frequencies, e.g. to an IF bi-carrier frequency.

= 27-

frequency of 4-5 ₉ 75 MHz and an IF sound carrier frequency of 41.25 MHz in the case of the NTSC system. These IF carriers are available at output 212 of tuner 210. The IF picture carrier is basically an amplitude-modulated signal (AM signal) which contains the composite video information (composite video signal). The IF sound carrier is a frequency-modulated signal (EM signal). Conventional color television signal processing circuits, which contain a filtering and amplifying IF channel 214 and a video detector 216, respond to the IF picture carrier from the output 212 of the tuner in order to demodulate the baseband video signal mixture β This baseband signal is fed to the input 217 a comb filter 218, which separates the chrominance component C and the luminance component Y from the video signal mixture and makes it available at associated connections 219 and 220. A more detailed description of the comb filter 218 is given below. The luminance and chrominance signals are further processed in a conventional manner in order to derive the color component signals for controlling the associated beam generator of a picture tube (not shown) To represent the screen of the picture tube.

The IF channel 214 has the usual bandpass characteristics, such as it is shown with the characteristic curve 221. The IF picture carrier P is at a location that has been attenuated by 6 db the higher-frequency edge of the characteristic curve 221, and the IF sound carrier S is at a level that has been attenuated by about 25 db Location of the lower-frequency edge of characteristic curve 221 ο As a result, the video information of the remaining sideband can be demodulated by the IF sound carrier without significant interference. As already explained, causes the IF pass-through characteristic 221 because of the asymmetrical damping of the Sidebands of the ZF image carrier are called a Nyquist SPM synchronous phase modulation of the IF picture carrier.

- 28 -

In the receiver according to Fig. 4- processed a frequency-converting phase-synchronized loop (PLT-) 222 the IF sound carrier in a path separate from the processing facility for the ZIF picture carrier is to store the sound information in the to demodulate the Nyquist SPM essentially without disturbing the effect. A buffer amplifier 224 couples the two IF carriers for picture and sound from the tuner output 212 to a picture band filter 226 and a To η band filter 228. The image band filter 226 has a symmetrical, relatively narrow bandpass characteristic 227 (e.g. with a 3 db bandwidth of 1 MHz), which is based on the IF picture carrier frequency P (e.g. 4-5.75 MHz at NTSC system) is centered around essentially only the IF picture carrier signal to let through. An IF amplifier 230 and a limiter 232 ensures a suitable amplification and limitation of the IF picture carrier signal «The limited and thus Substantially unmodulated IF picture carriers from the output of limiter 232 are transferred to an input of a signal mixer 234- given.

The audio band filter 228 has a symmetrical and relatively narrow bandpass characteristic 229 (with a 3 dB bandwidth of e.g. 1 MHz), which is centered on the IF audio carrier frequency S (e.g. on 4-1.25 MHz for the NTSC System) in order to allow essentially only the IF sound carrier and its immediate sidebands to pass and to pass them to an input of a phase detector 238 via an IF amplifier 236. The IF amplifier 230 and 236 may be constructed the same, for example each _o through an integrated circuit such as the IF amplifier of the type TA 7607 the manufacturer Tokyo Shibaura Electric Co., Ltd. The limiter 232 may simply parallel-connected, oppositely poled Schottky Be formed barrier diodes. A conventional circuit 24-0 for automatic gain control (ATH), which responds to the output signal of the IF amplifier 236 (oS. ^ R alternatively to the output signal of the amplifier 230), supplies AGC control voltages to the IF amplifier? 230 and 236, in order to influence their gain factors in such a way® » _? that

- 29 -

- 29 their output signals remain at predetermined levels.

A voltage controlled oscillator 242 with varactor tuning, the nominal oscillation frequency of which is equal to the difference between the IF picture carrier frequency and the IF audio carrier frequency (e.g. equal to 4.5 MHz in the case of the NTSO system) supplies a signal to the second input of the mixer 234. The mixer 234 can, for example, be a double-symmetrical analog multiplier circuit such as the module MC1496 from Motorola Semiconductor Products, Inc., which works in a switching mode under the control of the amplitude-limited IF image carrier (ie the image carrier forms the switching control signal), in order to mix the IF picture carrier signal with the output signal of the voltage-controlled oscillator and to deliver a frequency-converted signal at its output which indicates the frequency and phase difference between its input signals. In the case of the NTSC system, the frequency difference between the input signals of the mixer 234 is 41 ₉ 25 MHz. This 41.25 MHz output signal of the mixer 234 is applied to a second input of the phase detector 238, which can also be an integrated circuit of the type MC1496. The phase detector 238 supplies an output signal, the amplitude of which changes in direct relation to the phase difference of its input signals and which thus works as an FM demodulator for the frequency-modulated IF sound carrier applied to its first input by the amplifier 236 and a composite sound signal in baseband at its output supplies (together with unwanted signals resulting from the demodulation process).

The output of the phase detector 238 is in a downstream low-pass filter 244 filtered to a control signal for the frequency of the voltage controlled oscillator 242 to generate. The mixer 234, the phase detector 238, the voltage-controlled oscillator 242 and the low-pass filter 244 form the frequency-converting phase-synchronized loop

- 30 -

fe 222. The bandwidth of the low pass filter 244 is on the one hand large enough to allow the composite baseband audio signal to pass through, but narrow enough on the other hand to suppress the higher frequency unwanted signals.

The composite audio signal that has passed through is e.g. a stereo decoder 246 is given. If the composite audio signal contains stereo information, then the decoder decodes 246 the audio signal and delivers the stereo signals for left and right to assigned loudspeakers 248 and 250. If no stereo information is available, the decoder delivers 246 the monophonic signal to the loudspeakers.

In operation, the mixer 234 effects a frequency conversion of the IF picture carrier signal applied to its input and provides an output signal whose frequency corresponds to the difference between the frequencies of its input signals (eg 41.25 MHz). Unwanted output signals corresponding to the coupling through of the input signals and the sum frequency of the input signals are attenuated as a result of the relatively narrow bandwidth of the low-pass filter 244. The amplitude of the output voltage of the phase detector 238 is a measure of the phase difference between its input signals. This output voltage is filtered in the low-pass filter 244 and then applied to the voltage-controlled oscillator 242 as a control voltage. The frequency of the output signal of the voltage-controlled oscillator 242 and thus of the frequency-converted 41.25 MHz output signal of the mixer 234 changes in direct relation to the amplitude of the control voltage in the sense of a reduction in the phase difference between the signals at the inputs of the phase detector 238. If the input signals of the detector 238 are in phase quadrature (i.e. have a phase difference of 90 ° from one another), then the control voltage applied to the voltage controlled oscillator? Λϋ has the minimum amplitude Filter 244 dimensioned so that the frequency of the converted Sinais (difference

- 31 -

renzsignal) at the output of the mixer 234 is equal to the mean frequency of the IF sound carrier and that the phase of this Signal is in quadrature to the phase of the IF sound carrier. Thus, the phase detector 238 acts as an FM demodulator for frequency demodulation of the IF sound carrier in order to generate a signal which, after being filtered in the filter 244, corresponds to the sound information.

Since mixer 234 is also responsive to the video carrier signal, are any common mode frequency modulations that the two carriers for picture and sound e.g. by the local oscillator in the tuner 210 or by additional devices such as a cable television converter preceding the tuner 210 can be impressed by the mixer 234 into the The frequency-converted signal is transmitted and thus extinguished in the phase detector 238.

As mentioned, the frequency-modulated sound carrier contained in the output signal of the tuner 210 is passed through the band filter 228 selected and amplified in amplifier 236. The amplifier 236, which is controlled by the AGC circuit 240, provides for a constant long-term mean value of the amplitude of the sound carrier and thus removes all that normally occur Amplitude fluctuations that are not caused by interference are. The time constants of the AGC system are not so small that amplitude changes caused by impulse noise originate, be sifted out. The amplitude of the modulated sound carrier remains, apart from that caused by impulse noise caused amplitude changes, essentially constant .. As phase-synchronized loops are relatively insensitive against amplitude changes, it is not necessary to place between amplifier 236 and the detector 238 to provide a limiter for eliminating the amplitude changes caused by impulse noise.

The output of amplifier 236 is therefore a suitable one Point to those amplitude changes of the modulated

- 32 -

w \ / ν ι

Record sound carrier from which a correction signal is obtained to reduce the defects in the video signal caused by impulse noise. Since also the bandwidth of filter 228 is wide enough to pass the sound carrier and some of its sidebands this filter provides a signal delay that is shorter than the delays in the video signal path, allowing enough time to compensate for defects in the video signal. A correction control signal generator 252, which is a synchronous detector 254 · for recording the amplitude changes caused by impulse noise contains, can advantageously with the Structure of the phase-locked loop described above are combined, with the help of a minimal number of additional parts and in a way that is easy with that used for tone demodulation Can unite phase-locked loop, expediently in an integrated circuit.

Since the output of the mixer 234- has a frequency which is equal to the mean frequency of the frequency-modulated sound carrier, but is in phase quadrature, becomes a 90 ° phase sniffer 256 is used, which the output signal of the mixer 234- shifts by 90 ° to bring it to an input of the synchronous detector 254- "If so this detector receives the frequency-modulated sound carrier at its other input, then the phases of its two input signals synchronously with each other (i.e. there is in-phase), and the synchronous detector 254- can in a known Way the amplitude changes of the frequency-modulated Demodulate sound carriers. The detector 254- may, for example, be a be double symmetrical multiplier such as the integrated module MC! & 96 mentioned above.

The amplitude changes derived at the output of the detector 254- are applied to a first input of a equalizer 258, which generates a direct voltage at a second input receives from a source 260. De ^? ®2? Same

changes its output state whenever the output of detector 254 · passes through this threshold goes. The output signal of the detector 254- is a slowly changing alternating signal with a relatively small one Amplitude, except when there is impulse noise or some other strong signal disturbance. In this case there is a relative strong and rapid change in the output signal, which can go in a positive or negative direction, namely as a result of post-oscillation, e.g. due to the interaction of the noise pulse with the HF circuit of the tuner 210. Hence it may be useful to provide a second comparator with a threshold of opposite polarity to To detect deflections in both directions in the output signal of the synchronous detector. It is also possible to have two comparators to be logically linked with one another in such a way that an output signal is only generated for such an amplitude change, which is known to be related to noise pulse ringing.

The output signal of the comparator is generated by a pulse generator 262 conditioned and given via a connection 263 to the control input of a switch 264- which, when activated allows a substitute video signal in the comb filter 218 to take effect. The pulse generator 262 can be a monostable Be a multivibrator producing a pulse of prescribed amplitude and duration (typically in the range of 1 to 10 microseconds). Experiments have shown that the The duration of a noise pulse is usually in the range of 1 to 3 microseconds, so that a control pulse of 3 Microseconds is sufficient to compensate for most of the noise pulses. On the other hand, it may also be desirable to end the video replacement at a certain point in time in each interval, e.g. during the horizontal blanking period » In this case, the pulse generator can be an edge-triggered flip-flop that is triggered by the output signal of the Comparator is set and its reset is carried out by a separate timing pulse, e.g. by the horizontal sync pulse ο - 34 -

The comb filter 218 is carried out in charge transfer technology and contains a charge-coupled circuit (CCD) that contains a 1 ~ H delay line (i.e. a line with a delay time equal to a horizontal deflection period) integrated with CCD summing sections as well as interrogation and hold circuits in order to achieve the required function a transverse filter for comb filtering the video signal to separate the frequency-interleaved luminance and chrominance signals (Y and C), as described in US Pat. No. 4,158,209. The CCD delay line contains a plurality of memory elements connected in series, wherein interrogated data are transferred from one element to the next one after the other at a predetermined speed. The signal can be tapped from one or more of these memory locations in a non-erasing manner in order to obtain a specific signal delay. An adder 266 averages two samples of the video signal, one tapped by half a color subcarrier period and the other tapped by half a color subcarrier period after a 1Η delay. The tapped and delayed signal is conditioned in adder 266 in such a way that its chrominance component is shifted by 180 ° (i.e. by half of a color subcarrier period) compared to the untapped delayed signal remaining in the CCD circuit, so that the tapped and delayed signal has the correct color phase to be able to serve as a substitute signal. A signal delayed by 1 H (ie one line deflection period) appears at the output of the adder 266 and is applied to a terminal 269 via an amplifier 268. The signal available at terminal 269 is then applied to input terminal 270 of the comb filter. A more detailed description of the circuit for phase inversion of the chrominance signal can be found in US-Pc. Söaieschrift 4 · 272 785. The illustrated comb filter 218 is z “3. _; available as an integrated module T 3928 from Tokyo Shibaura Co., Ltd., Japan.

The real-time video signal is sent to the entrance skis. "as 217

3331UVÖ

• 1 of the comb filter is given and then on via switch 264- applied to the input terminal 271 of the CCD register. When it is determined that there is a signal defect in the real-time signal (Noise pulse) is present, then the delayed by 1H The signal from terminal 269 is temporarily substituted for the real-time signal from video detector 216, by toggling switch 264 to receive the 1 H delayed signal from terminal 270 of the comb filter receives. The signal, which has already been delayed by one horizontal deflection period, is thus re-entered into the CCD register.

Above, an advantageous method is described to the real-time signal in the video signal path of a color television receiver using a special type of comb filter to be replaced by a delayed signal. An alternative arrangement for use in black and white television receivers just needs a simple 1H delay line and one Switch included. In this case the input of the delay line is for receiving a real time video signal connected, and the switch puts either the real-time signal or the 1 H delayed signal from Output of the delay line directly to the downstream processing circuit, The video signal is not running again into the delay line but runs through the line only once, whereby it is about one image line (horizontal deflection period) is delayed. In the case of a color signal, a delay line can also be used which a delay corresponding to an integer number of Horizontalabi enkperioden brings to the same basic Achieve result. For an NTSC color television signal, the delay device, for example, a 2-H delay line and in this case it is not necessary to adjust the phase of the chrominance component of the video signal invert to give the chrominance component the correct phase for use as a substitute signal.

In the case of the one described above in connection with FIG

- 36 -

Arrangement takes place a detection of impulse noise or defects in the video signal, advantageously in connection with a ^T oninformation demodulating PI.L tone signal detector. While separate IF amplifiers 230 and 236 are used in the case of FIG. 4, it is also possible to amplify the IF carrier signals for picture and sound supplied at the output of buffer 224 in a common IF amplifier, as described above has been described

While in the case shown, the phase-synchronized Loop 222 includes a mixer 234 which sets this to 41.25 MHz converted signal for the phase detector 238 and for the Synchroηdetektor 254 derives, it is also possible that the Nominal frequency of the output signal of the voltage controlled oscillator at the same frequency as the sound carrier frequency to be changed and sent directly to detectors 238 and 254 without frequency conversion by mixer 234, as indicated by the dashed line in FIG. Of course, in this alternative, the mixer 234 omitted and would not be available to do any common mode frequency modulations in picture and Eliminate sound carriers.

In the described embodiment, the correction control signal used to control the substitute insertion of a delayed video signal. The control signal however, it can also be used in conjunction with other circuits to suppress or compensate for impulse noise will. For example, this signal could be used to control the automatic gain control system of the television receiver insensitive to noise impulses to make in the video signal.

It should also be mentioned that the NTSC frequencies mentioned are only examples. The different frequencies can also be measured differently depending on the Eiger'heitea of NTSG- used, PAL or SECAM television system _s

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Claims (1)

Claims ! Arrangement for demodulating the audio information in one Television receiver that is a source of an intermediate frequency signal which has a picture carrier modulated with the picture information and one with the sound information contains a modulated sound carrier, characterized by: a controllable oscillator (50; 15 ^; 252) on a control signal applied to a control input responds and an output signal controlled at an output Frequency supplies; a set ζ device (44; 144; 234), which is attached to a the first input receives the image carrier and the output signal of the oscillator is received at a second input and supplies a frequency converted signal at an output; a phase detector (48; 152; 238) which is connected to a Most input receives the sound carrier and the frequency-converted signal at a second input; a low-pass filter, (52; 156; 244), the input of which with is coupled to the output of the phase detector and the control signal to the control input at its output the controllable oscillator and. provides the sound information, 2. Arrangement according to claim 1, characterized in that the frequency-converted signal has a nominal frequency which is equal to the frequency difference between the picture carrier and the sound carrier ₇ and that the conversion device (44; 144; 234) has a mixer connected to a first Input (B) receives the video carrier and a second input receives the output signal of the oscillator (50; 154; 252) and delivers the frequency-inverted signal with a nominal frequency equal to the frequency of the audio carrier at its output « 3. Arrangement according to claim 2, characterized by a amplifying means (34, 36, 40, 42) which transmit the image carrier signal receives to apply a substantially unmodulated image carrier to the mixer (44). 4. Arrangement according to claim 3? characterized in that a first filter network (38) is provided, which is symmetrical, centered on the sound carrier frequency Has bandpass range and the intermediate frequency signal at its input receives, and that between the output of the first filter network and the first input <les phase detector s (48) a first IF amplifier (46) is switched. 5. Arrangement according to claim 4, characterized gekennzeiudiser that the reinforcing device the following aui \ »jeif ^: a second filter network (36) which is a symmetrical baud pass range centered on the picture carrier frequency has and at its input the intermediate frequency signal receives; «, 3 _ a second IF amplifier (4-0), which is between the output of the second filter network (36) and the first Input of the mixer (44) is switched. 6 »Arrangement according to claim 5? characterized in that between the output of the second ZI amplifier (4-0) and the first input of the mixer (44) an amplitude limiter is switched «, 7. Arrangement according to claim 1, 2 or 6, wherein the audio information contains the information of several audio channels, characterized by a multi-channel decoder circuit (54 ·), the input of which is coupled to the output of the low-pass filter (52) and the one output for delivery the information has one or more of the audio channels. Arrangement according to claim 2, characterized in that the phase detector (4-8; 152; 238) and the mixer (4-4-; 144; 234-) each with a double-symmetrical analog Multiplier circuit are formed. Arrangement according to claim 2, characterized by: a first filter (136) whose input is connected to receive the intermediate frequency signal and which has a double-humped frequency response of amplitude (137a, 137b), the apex of which corresponds to the frequencies of the image carrier and the sound carrier are centered in order to provide the image and the sound carrier at the output of the filter; an amplifier (138), the input of which is coupled to the output of the first filter (136), the image and to amplify the sound carrier and to deliver the amplified carrier at its output; a second filter (14-6), which with the first or the second input (151 or 153) of the phase detector (152) is coupled and has such a frequency response of the amplitude that the frequency of the image carrier by one predetermined amount is damped, which is significantly reduced is less than the predetermined attenuation of the frequency of the sound carrier. 10. Arrangement according to. Claim 9, characterized in that the second filter (146) between the output of the amplifier (138) and the first input of the phase detector (152) is switched. 11. The arrangement according to claim 9, characterized in that the second filter (166) between the output of the mixer (144) and the second input of the phase detector (152) is switched. 12o arrangement according to claim 9, 10 or 11, characterized in that that between the output of the amplifier (138) and the input of the mixer (144) a selecting Device (140, 142) is connected, which essentially supplies the image carrier at its output. 13 · Arrangement according to claim. 12, characterized in that the selecting device (140, 142) comprises a diode limiter circuit (142) to a substantially to deliver unmodulated image carrier to the input of the mixer (144). 14. Arrangement according to claim 10, characterized in that between the output of the second filter (146) and the first input of the phase detector (152) a first selecting device (148, 150) is connected, which causes an additional attenuation of the image carrier and thereby allowing the filter (146) to have a smaller than brings the predetermined attenuation at the frequency of the video carrier » 15. The arrangement according to claim 14, characterized in that between the output of the amplifier (138) nsd the input of the mixer (144) a second selekti-reae © input direction (140, 142) is switched to essentially just deliver the image carrier to the mixer. 16. The arrangement according to claim 14, characterized in that the first and second selecting means (148, 150 and 140, 142) diode limiter circuits (148 and 150) show »