DE3331076C2 - Sound demodulator for a television receiver - Google Patents

Abstract

A frequency-converting phase-locked loop (PLL) is used to demodulate the audio information from a television signal. A voltage-controlled oscillator (50), the nominal oscillation frequency of which is equal to the difference frequency between the IF picture carrier and the IF sound carrier, acts on an input of a mixer (44) which receives an essentially unmodulated picture carrier at its other input. A phase detector (48) receives the output signal of the mixer at a first input and the sound carrier at its second input. The phase-locked loop is closed by a low-pass filter (52) which is connected between the output of the phase detector and a control input of the voltage-controlled oscillator. The demodulated audio information appears at the output of the low-pass filter (52). In a particular embodiment, the phase-locked loop can supply a correction control signal which causes a compensation circuit to reduce the influences of impulse noise in the image information.

Description

The invention relates to a tone demodulator as required in the preamble of claim 1.

Multi-channel sound transmission for stereophonic and bilingual television broadcasts requires the Use of one or more audio sub-carriers, where-

This increases the bandwidth of the television audio signal from 15 kHz to approximately 90 IcHz or more brings with it the danger that the so-called "sound creaking" arising in the processing channel of the audio signal becomes more pronounced. It arises as a result of a modulation that is dependent on the image content and is applied to the Audio signal is transmitted. This disturbance is always present to some extent in television signal circuits, can however by various switching measures be kept within tolerable limits.

In the early days of television technology, the image and sound signals were in separate, downstream of the tuner Channels processed. Such separate processing prevents significant interaction between the image and sound carriers within the television receiver, reducing the risk of occurrence sound creaking in the receiver is significantly reduced. Unfortunately, however, it happens that Frequency fluctuations of the upper position oscillator in the tuner as a result of drift or automatic fine-tuning (AFA) on the intermediate frequency carrier and on the intermediate frequency carrier and demodulated by the sound frequency demodulator as sound interference (buzzing). Since the Sound channel has a much narrower pass band than the picture channel. must with the processing method mentioned the receiver must be tuned for the best sound reproduction and not the best image reproduction.

Modern television receivers almost generally use the so-called intercarrier method for audio signal processing. Here the video and sound carriers are placed behind the tuner in a common intermediate frequency channel processed, which has a special IF band filter characteristic, which on the one hand converts the sound carrier attenuates about 20 db more than the image carrier and on the other hand is dimensioned so that the image carrier on the Edge at the high-frequency end of the IF transmission range falls on a sidle that has been attenuated by 6db. Then the one with the higher Image carriers appearing in amplitude in the image channel are processed in order to demodulate the image information. To the To recover the audio information, the two IF carriers are mixed to form an intercarrier audio signal to form, the frequency of which corresponds to the difference between the frequencies of the two IF slaves. At the In the NTSC system, for example, a 45.47 MHz picture carrier is mixed with a 41.25 MHz sound carrier generate a 4.5 MHz intercarrier signal. The Intercarricr process is particularly advantageous because common-mode frequency modulations in tone and Image carrier - {the z. B. caused by changes in the oscillator signal in the tuner of the television receiver itself or in additional devices coupled to the receiver, such as B. a television converter for cable transmission) due to the mixing that takes place in the IF range when deriving the intercarrier tone signal be wiped out.

However, the intercarrier process is not free from rubbish. While the aforementioned 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 snarling is much stronger than in the case of processing the image and sound carriers separately Channels. This is due to the fact that, on the one hand, the sound carrier is attenuated considerably, and thus the signal-to-noise ratio of the Sound signal reduces fc, ird and that, on the other hand, the sidebands of the IF picture carrier are attenuated unequally which results in an accompanying synchronous phase modulation (SPM or ICPM) in the picture carrier which is commonly referred to as the "Nyquist SPM" and the audio signal during intercarrier mixing distorted In addition, the intercarrier method can have a high degree of modulation or overmodulation of the image carrier (as is usually the case with the insertion of image overlays by local daughter stations can be caused) the video carrier signal eliminated and a creaking sound caused at line frequency and field frequency (i.e. 15 734 Hz and 60 Hz in the case of the NTSC system). The problem of creaking with the intercarrier method is more elaborate in an article by P-Fockens and C. G. Eilers "Intercarrier Buzz Phenomena Analysis and Cure «in the journal IEEE Transactions on Consumer Electronics, August 1981, pages 381-397

The creaking sound generated by an intercarrier system can be tolerated in the monophonic Fenreh receivers because the passage area of the audio channel in such receivers is relatively narrow. Unfortunately it will However, with the higher audio signal bandwidth of a multi-channel audio transmission, so does the creaking bigger and no longer stays within tolerable Limits.

It is known to combine the system, which operates with separate channels, and the intercarrier system for audio signal detection. Such a combined system, which can be referred to as a "split intercarrier", is described in the above-mentioned article by P. Fockens and CG Eilers. 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 picture and sound are processed together in a sound channel in order to derive the sound information in accordance with the intercarrier system described above. Since in this combined system, which is necessary for detection of the video-vestigial sideband signal IF filter characteristic is not present in the audio channel, which caused by the Nyquist SPM Tonschnarren but is virtually eliminated other hand, since the Intercarrie ^r -Metbode is shared, the IF carrier for are Image and sound processed together in the IF amplification channel Non-linear effects within the IF amplifier and the degree of image modulation can cause the image signal to interfere with the audio signal and thus constitute two factors that can be assigned to the intercarrier system

thus represent sound sources that are not eliminated. In addition, additional circuit arrangements such as intercarrier amplifiers, resonance circuits and a discriminator are required.
Furthermore, from DE-OS 29 45 563 a working with a PLL loop demodulator circuit for a television signal is known, in which the PLL loop provides a loading reference signal for the demodulation of the image signal. Here, an intermediate frequency signal filtered by a bandpass filter, which contains the modulated audio and video carriers, is fed to a phase comparison circuit, where it is compared with a video carrier vibration generated by a controllable oscillator. The comparison result contains the modulated audio IF signal, which is decoupled here for further processing in the audio channel, but is also fed as a control signal to the aforementioned video carrier oscillator via a low-pass filter with a low cut-off frequency. This oscillator forms with the comparison circuit

device and the low-pass filter a PLL loop for readjustment of the oscillator to the image intermediate frequency, compared to that with the help of a multiplier circuit modulated image IF is demodulated to derive the video signal. From the magazine "Der Elektroniker" 12/1975, pages EL6 to ELl 2, it is finally known to also provide a mixer stage within a PLL loop; however, this reference deals with the Generation of very high frequencies of over a few MHz in a fixed phase relationship to a given one Frequency using a mixing technique, at which between the mixer and a phase detector a divider is switched on, which is necessary for generating the desired high frequency.

The task is based on DE-QS 29 45 563 of the invention is to avoid sound interference in an intercarrier system. This task is carried out by those specified in the characterizing part of claim 1

Hi ^ -I. _._] _lx_.

(VIl-I fVlltait,> IV / 3l.

According to the invention, there is no intercarrier modulated Tone signal is generated, but this is generated by the tone IF (for example 41.25 MHz) by phase demodulation compared to a reference oscillation generated with a PLL loop of the same frequency (41.25 MHz). The invention combines the advantages of separate carrier processing and the intercarrier method with little switching effort, without having to accept the individual disadvantages of these methods.

sehempfänger, which is another embodiment of the Invention including means for providing a signal indicative of impulsive noise disclosed.

In the receiver according to FIG. 1, a television broadcast signal picked up by an antenna 8 is fed 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 41.25 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. A conventional color television signal processing circuit which uses an IF-Filtcr üfiu - τcrätariiüngSfCäfiä! 20, cificfi V'iucöucickiOf 22 and a video signal processing device 24, responds to the IF picture carrier from connection 18. to deliver video signals for the colors red (R), green (G) and blue (B) to a picture tube (not shown) so that a color picture of the television scene is displayed. In addition, a matched limiter / amplifier stage 26 supplies 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. That

Phase of the beat signal applied to mixer 14 follow the frequency and phase of the received RF picture carrier.

The structure and operation of the video detector 22, the limiter / amplifier stage 26, the AFA detector 28 and phase shifter 30 are described in more detail in US Pat. No. 4,263,611.

The ZF-Kana! 20 has the usual passage character

An arrangement according to the invention for recovering the audio information from a television signal at the output of the limiter / amplifier stage 26, the IF video carrier signal is also transmitted to a detector 28 via a video and audio carrier signals in the intermediate frequency 90 ° phase shifter 30 for automatism ( IF signals), has a control fine tuning (AFA) fed to the Ausbaren oscillator to generate an output signal output this detector to receive an AFA control signal, controlled frequency and a frequency converting 35 which is applied to the local oscillator 16. On phase-locked loop (PLL) on, which a fre- this is achieved that the frequency and the quenzmischer and contains a phase detector. Of the
Mixer receives the output signal of the oscillator at its one input and the IF picture carrier signal at its other input. The phase detector rec- 40
the IF audio signal begins at one of its inputs
its other input is the output signal of the mixer. The phase-locked loop is completed by a low-pass filter, which is stik between the output of the phase detector and a control input of the 45, as shown by the curve 32. The IF oscillator is connected and a control image carrier P is connected to the oscillator and applies a 6 db attenuator signal to control the frequency of the oscillator output on the higher-frequency edge of the pass signal. At the output of the low-pass filter characteristic curve 32, and the IF sound carrier 5 appears, the demodulated sound information appears. With the location at the lower PLL system in question, which is attenuated by around 25 db here, it is practical to use the 50 flank of the characteristic curve 32. Thus, the image information arrangement for capturing the television sound signal can also ne the remaining sideband without significant interference

demodulated by the IF sound carrier. Unfortunately, however, the IF transmission characteristic 32 leads because of the asymmetrical attenuation of the sidebands of the IF picture carrier in relation to the Nyquist SPM already mentioned above (synchronous phase modulation) of the IF picture carrier. With the conventional intercarrier system for audio signal acquisition brings this Nyquist SPM of the IF picture carrier a distortion of the intercarrier audio signal, namely

the other embodiment of an inventive 60 because of the mixture taking place in this system moderate audio signal detection device with frequency of the IF sound carrier with the IF picture carrier. These perpetrators phase locked loop contains. Distortion of the intercarrier audio signal leads to this F i g. 3 shows in a block diagram an alternative to the above-mentioned buzzers. The measure of the The form of sound creaking caused by frequency-converting phase Nyquist SPM increases synchronized loop working arrangement for 65 in direct relation to increasing the bandwidth of the Audio signal detection for the television receiver according to the audio signal. If you consider that the bandwidth ei-F i g. 2 according to the invention. nes composite sound signal, the several auxiliary F i g. 4 shows in block form the circuit of a remote carrier for transmission, for example monophonic

to provide an arrangement which indicates the presence of impulse noise in the video signal

The invention is explained in more detail below using exemplary embodiments with reference to drawings.

F i g. 1 shows in block form the structure of a television receiver which uses an arrangement according to the invention Includes audio signal detection

F i g. 2 shows in block form a television receiver,

Shear, treophonic and second tone programs included. is much larger than the bandwidth of the monophonic signal usually produced by an intercarrier system is processed, then it becomes clear that the I nicrciirricr method of audio signal detection for such Cases can become problematic because the sound creaking caused becomes much louder.

Size According to the present invention, the IF sound carrier is processed in a path which is separate from the processing circuitry for the IF picture carrier, and the composite sound signal is demodulated by a phase-locked loop (PLL) 53 which converts the frequency. Correspondingly, the IF carriers for picture and sound available at the terminal 18 are applied to a picture bandpass filter 36 and a sound bandpass 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 (e.g. 1 MHz hreii.c) band-pass characteristic 37, which is centered on the IF carrier frequency (e.g. 45.75 MHz in the NTSC system) in order to achieve a essential to let through only the IF picture carrier signal. An IF amplifier 40 and a limiter 42 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 44.

The audio bandpass filter 38 has a symmetrical, relatively narrow (for example 1 MHz wide) bandpass characteristic 39 which is centered on the IF carrier frequency (for example 41.25 MHz in the NT. ^C C system) essentially only to allow the IF sound carrier signal to pass, which, after suitable amplification in an IF amplifier 46, is passed to an input of a phase detector 48. The IF amplifiers 40 and 46 can be constructed identically and z. B. each consist of an integrated circuit such as the module TA7606 from the manufacturer Tokyo Shibaura Electric Co, Ltd. The limiter 42 can be formed simply by Schottky barrier diodes connected in parallel and polarized in opposite directions. A conventional automatic gain control (AGC) circuit 47 responds to the output signal of the IF amplifier 46 (or alternatively the output signal of the amplifier 40) to apply AGC control voltages to the IF amplifiers 40 and 46 and thus their amplification to control that their output signals are maintained at predetermined levels.

A voltage controlled oscillator 50 with varactor tuning, its nominal oscillation frequency 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 may e.g. B. a double symmetrical analog multiplier circuit be like B. the module MCl 496 from Motorola Semiconductor Products, Inc. and works in one Switching operation under control by the amplitude-limited IF picture carrier (which acts as a switching control signal acts) to the IF picture carrier signal with the output signal to mix the voltage-controlled oscillator 50 and to deliver a signal at its output, 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 41.25 MHz output of the mixer 44 is applied to a second input of the phase detector 48, which is also an integrated Circuit of the type mentioned above can be MC1496. The phase detector 48 provides an output signal whose Amplitude is directly related to the phase difference existing between its input signals changes. Thus, the phase detector 48 operates as an FM demodulator for its first input from Amplifier 46 applied frequency-modulated IF sound carrier and delivers a composite at its output Baseband audio signal (shared with unwanted signals from the demodulation process originate). A more detailed description of the operation of analog multipliers than FM demodulators can be found in an article by A. Bilotti, "Applications of a Monolithic Analog Multiis plier ”, which is printed in the IEEE Journal fo Solid State Circuits, December 1968, pages 373-380.

A low-pass filter 52 coupled to the output of the phase detector 48 is generated by filtering the De tplftnr-AuscrancrssiirnaU pin ^ tpnprsional 711m. ^ Tpnprn

the frequency of the voltage controlled oscillator 50. The mixer 44, the phase detector 48, the voltage controlled The oscillator 50 and the low-pass filter 52 form the frequency-converting phase-locked loop (PLL) 53. The low-pass filter 52 has a sufficient bandwidth to pass the composite baseband audio signal to select (and to suppress the higher frequency unwanted signals). This selected compound The audio signal is applied to a stereo decoder 54, for example. If the composite sound signal contains stereophonic information, the decoder 54 decodes this signal and provides the stereo signals for left and right to associated loudspeakers 56 and 58. If no stereo information is contained, delivers the decoder 54 sends the monophonic signal to the loudspeakers

During operation, the mixer 44 effects a frequency conversion of the IF picture carrier signal applied to its input and delivers at its output a signal whose frequency is the difference between the frequencies of its corresponds to both input signals (e.g. 41.25 MHz). Unwanted output signals, the coupled through Input signals and the sum of the input signals are due to the relatively narrow bandwidth of the low-pass filter 52 attenuated. The amplitude of the output voltage of the phase detector 48 is a Measure of the phase difference between its input signals. This output voltage is after filtering in the low-pass filter 52 as a control voltage to the voltage-controlled Oscillator 50 placed. The output frequency of the oscillator 50 and thus the signal converted to 41.24 MHz by the mixer 44 changes is directly related to the amplitude of the control voltage in a direction to reduce the phase difference between the signals at the inputs of the phase detector 48. When the input signals of the Phase detector 48 have a phase difference of 90 ° (i.e. are in phase quadrature), then the dem voltage controlled oscillator 50 applied control voltage minimum amplitude. Therefore corresponds to, because of the feedback nature of loop 53 in the case of its synchronized state, the control voltage am Output of the filter 52 of the sound information and is such that the frequency of the converted difference signal am The output of the mixer 44 is equal to the mean frequency of the IF sound carrier and that the phase of this difference signal is in quadrature to the phase of the IF sound carrier. The phase detector 48 thus acts as an FM demodulator for frequency demodulation of the IF sound carrier.

In addition, the common-mode frequency modulation that the image and the sound carrier z. B. be impressed by the local oscillator 16 of the tuner or by additional devices located in front of the tuner 10 , such as a cable television converter, transmitted into the converted difference signal and thus extinguished in the phase detector 48.

The described system for sound demodulation is advantageous because the predetermined frequency spacing between the IF carriers for picture and sound is used in order to allow a simplified tuning of the receiver. In addition, any common-mode frequency modulation of the IF carriers is canceled. 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 flank of the IF transmission range, from leading to creaking. 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 substantially 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 NHz and 1.5 MHz in the case of the NTSC system with the IF picture carrier frequency of 45.47 MHz). Since the frequency of the output signal of the voltage-controlled oscillator 50 is also 4.5 MHz, audio frequency zero beats at the output of the mixer 44 are prevented. This practically eliminates another cause of image-related sound creaking, which is inherent in an intercarrier system.

Compared to the intercarrier system, where the transmission characteristic of the IF channel attenuates the IF sound carrier by about 25 db, so that the signal-to-noise ratio in the sound channel is worsened, in the system described here, the sound band filter 38 leaves the IF sound carrier on relatively undamped the IF amplifier 46 through. The amplitude level of the sound carrier is thus approximately 25 db higher than in the intercarrier system, and the signal-to-noise ratio of the demodulated audio signal is correspondingly better for a given RF signal level.

It should also be mentioned that in the system described, neither an intercarrier amplifier nor an Intercarrier discriminator or the resonance circuits assigned to such circuits are required, because no intercarrier tone signal is generated.

It should be noted that the input signals to mixer 44 and phase detector 48 have amplitude levels such that the input circuits of these circuits are primarily responsive to the frequency and phase of the input signals. This inherently suppresses amplitude modulations of the IF picture carrier. Although a sum frequency signal (82.5 MHz) is also supplied at the output of the phase detector 48 , its modulation envelope is essentially symmetrical and thus has no noticeable influence on the audio baseband frequencies. The limiting effect of the limiter 42 does not therefore have to be as great as is required in an intercarrier system , and on the other hand the generation of harmonics which mix with the output signal of the voltage-controlled oscillator 50 and can cause distortions in the audio frequency band.

In another embodiment, the IF picture carrier can be coupled at the output of the limiter / amplifier stage 26 via the connection point B to the mixer 44 and thereby form the switching control signal for the mixer. The circuit arrangement between the

ίο Points A and B can then be omitted. However, since the IF amplification channel 20 is part of the device for tone demodulation in this case, the Nyquist SPM is not bypassed, so that this embodiment is not suitable for demodulating a broadband composite tone signal. However, since the IF sound carrier is also produced with relatively little attenuation in this embodiment, there is still a substantial improvement in the signal-to-noise ratio. if relatively narrow sound signal p wjp

z. B. a monophonic audio signal can be demodulated.

While in the embodiment according to FIG. If separate IF amplifiers 40 and 46 are provided, a common IF amplifier can also be used in order to amplify the IF carriers for picture and sound supplied at the output of the buffer 34, as will be described further below.

At the recipient according to FIG. 2 becomes a television broadcast signal picked up by an antenna 108! is fed to a television tuner 110 which includes an RF amplifier 112, a mixer 114 and a local oscillator 116 . The tuner 110 converts the RF carriers for picture and sound of a selected television channel to IF carriers, e.g. B. to 45.75 MHz for the video carrier and 41.25 MHz for the sound carrier in the case of the NTSC system. These IF carriers are available at the output terminal 118 of the tuner. The IF picture carrier of 45.75 MHz is basically an amplitude-modulated signal (AM signal) which contains the composite video information (composite video signal). The IF sound carrier of 41.25 MHz is a frequency-modulated signal (FM signal). A conventional color television signal processing circuit including a filtering and amplifying IF channel 120, a video detector 122, and a video signal processing means 124 responds to the IF picture carrier at port 1 18 to video signals for red (R), green (G) and blue (B) to drive a picture tube (not shown) so that a color picture of the television scene is displayed. 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 demodulate the composite video signal from the IF picture carrier by synchronous demodulation. The IF picture carrier from the output of the limiter / amplifier stage 126 is also passed via a 90 ° phase shifter 130 to a detector 128 for automatic fine tuning (AFA) in order to at the output of this AFA detector

to generate an AFA control signal which is applied to the local oscillator 1 16 . In this manner, the frequency and phase of the overlay signal applied to mixer 114 will track the frequency and phase of the received RF picture carrier. The construction and operation of video detector 122, limiter / amplifier stage 126, AFA detector 128, and phase shifter 130 are described in more detail in U.S. Patent 4,263,611.

The IF channel 120 has the usual bandpass characteristics as shown by curve 132. The IF picture carrier flies to a 6db attenuated Place au: 'of the higher-frequency flank of the characteristic curve 132, and the IF sound carrier S lies on one at approximately 25 db attenuated place on the nieoVigerfrequenten Edge of the characteristic curve 132. Video information of the remaining sideband can thus be transmitted without significant interference be demodulated by the IF sound carrier. As explained above, the bandpass characteristic causes 132 because of the asymmetrical attenuation of the sidebands of the IF picture carrier, one called »Nyquist-SPM« Designated synchronous phase modulation of the IF picture carrier.

Also in the case of F fg. 2 is processed for demodulation of the audio signal of the IF sound carrier in a way that is separate from the processing circuits for the IF picture carrier, and the composite audio signal is synchronized by a frequency-changing phase (rLLJ u # uciiiciuuiici i. Oci uci nuaiun- 2, the IF picture carrier and the IF sound carrier are amplified in a common IF amplifier to control the phase-synchronized loop 157. In detail, the two IF carriers available at connection 118 for picture and sound are transferred a buffer amplifier 134 and a filter 136 are fed to a single IF amplifier 138. The filter 136 has a double humped (ie, two peaks) bandpass characteristic with a substantially symmetrical and relatively narrow (/ ... e.g. a 3 db bandwidth of 1 MHz having) part 137a, which is centered on the IF picture carrier frequency .P, and a substantially symmetrical and relatively narrow en (e.g. B. a 3-db bandwidth of 1 MHz having part 1376, which is centered on the IF sound carrier frequency to select the picture and the sound carrier and pass relatively undamped to the IF amplifier 138. The filter 136 ensures that the magnitudes of the image and the sound carrier maintain their mutual relationship, and can be a conventionally constructed resonance circuit of discrete elements or a filter operating with surface acoustic waves such as e.g. B. the filter Fl322 from the 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 138 so that the output signals of the amplifier remain at predetermined levels.

An amplitude-limited and therefore essentially unmodulated image carrier is obtained from the output of the IF amplifier 138 via a buffer amplifier 140 and a limiter 142 and applied to an input 143 of a mixer 144. A filter 146, a buffer amplifier 148 and a limiter 150 essentially only transmit the IF sound carrier to an input 151 of a phase detector 152. The limiters 142 and 150 can simply be formed by parallel-connected, oppositely polarized Schottky barrier diodes. The filter 146 can be a bandstop filter consisting of discrete elements, the center frequency of which is tuned in such a way that the frequency response shown by curve 174 results, which results in maximum attenuation at the IF picture carrier frequency P and minimum attenuation at the audio carrier frequency S.

A voltage-controlled oscillator 154 with varactor tuning, its nominal oscillation frequency is equal to the difference between the frequencies of the IF carrier for picture and sound (e.g. equal to 4.5 MHz for d: .s NTSC system), provides a second input signal to mixer 144 at port 145. The mixer 144 can e.g. B. be a double-symmetrical analog multiplier circuit such. B. the building block MC1496 from Motorola Semiconductor Products, Inc., which is in a switching mode due to the amplitude-limited IF picture carrier from limiter 142 operates (i.e. this carrier forms the switching control signal).

The mixer 144 mixes the IF picture carrier signal mu the output signal of the voltage-controlled oscillator 154 and provides a frequency-converted one at its output Signal indicating the frequency and phase difference between its input signals. the The frequency difference between the input signals of the mixer 144 is equal to 41.25 MHz. This 41.25 MHz output signal of the mixer 144 is applied to a second input 153 of the phase detector 152, the also an integrated circuit of the type MC1496

id can be. The phase actuator 152 provides an output signal the amplitude of which changes in direct relation to the phase difference between its two input signals. The detector 152 thus works as an FM demodulator for the applied frequency-modulated IF sound carrier and delivers the composite sound signal in the baseband at its output (together with undesired signals resulting from the demodulation process).

A low pass filter 156 coupled to the output of phase detector 152 filters the output signal of the phase detector 152 in order to generate a control signal for influencing the frequency of the voltage-controlled oscillator 154 to form. The mixer 154, the phase detector 152, the voltage controlled oscillator 154 and the Low-pass filters 156 form the frequency-converting phase-locked loop 157 has a sufficiently large bandwidth to select the composite baseband audio signal (during it suppresses the higher-frequency unwanted signals). This selected composite sound signal is z. B. a stereo decoder 158 is applied. If the composite sound signal is stereophonic information contains, the decoder 158 decodes this signal to convert the left and right stereo signals to one to give respectively assigned loudspeaker 160 or IPJ. If no stereo information is available, then returns the decoder 158 sends the monophonic signal to the speakers.

In operation, the limiter 142 is responsive to the highest amplitude signal at its input. Both at In television broadcasting as well as in cable distribution networks, the sound carrier transmitted is at least 8 db opposite the amplitude of the image carrier is attenuated because the filter 136 has this amplitude ratio of the two carriers maintains, the limiter 142 essentially selects only the image carrier from the output of the amplifier 138 and applies it to mixer 144, essentially unmodulated. Instead of limiter 142, could a band filter or a bandstop filter can also be used, but such circuits cannot do so easily housed in an integrated circuit die such as a diode limiter circuit The amplitude modulation imposed by the video information cannot and cannot be suppress.

As mentioned above, the mixer 144 performs a frequency conversion of the IF picture carrier applied to its input and supplies an output signal, its frequency the difference between the frequencies of its

13 14 §

Input signals corresponds (ζ, e.g. 41.25 MHz) to the consequences: on the one hand there is the probability of the Aufpi

passage 153 of the phase detector 152. At the output of the step-related line and field frequencies ||

Mixer 144 also shows undesirable output sound creaking due to a high degree of modulation s |

signals, namely coupled-through portions of the input of the IF picture carrier are smaller, and on the other hand, the Er- § |

signals and a signal with the sum frequency of the 5 generation of harmonics reduced with the

Input signal ?. The relatively narrow bandwidth of the output signal from the voltage controlled oscillator The low-pass filter 156, however, prevents this from mixing and distortion in the audio frequency band

desired signals reach the decoder 158. can cause.

The filter 146 causes an attenuation of the picture carrier. The above-described arrangement for the sound with respect to the sound carrier, and the limiter 150 io modulation, from the IF amplifier 138 to the despricht to the here with the larger amplitude coder 158 (apart from the filter 146) , advantageously appearing sound carrier and essentially delivers se in a single integrated circuit only the sound carrier to the input 151 of the phase end. The limiters 142 and 150 can be formed by diode 152. The amplitude of the output voltage of the circuit. The filters 136 and 146 phase detector 152 is a measure of the phase difference 15 can using relatively inexpensive resonance between its input signals. These output circuits are implemented because the voltage requirements are filtered in the low-pass filter 156 and then their attenuation quality is less high. ff as a control voltage to the voltage controlled Oscil- In an alternative embodiment, the loading may% lator The output frequency of this oscil- limiter 150 are omitted set 154; 20 Filter 146 'A gate 154 and thus the converted to 41.25 MHz signal, a correspondingly higher attenuation at the § from the mixer 144 varies in direct relation to the picture carrier frequency P have to the absence of the additional S _Amplitude: However, then it must the control voltage in the sense of minimizing the signal suppression effect of the limiter 150 U to compensate for the change in the phase difference between the signals. This can be done easily by adjusting the || the inputs of the phase detector 152. When the one-resonance circuit components of the filter 146 reach 2i output signals of the detector 152 are in phase quadrature. In addition, the filter 146 can be designed as a relative ii (ie have a phase difference of 90 °), then has a narrow-band (e.g. 50OkHz) bandpass filter applied to the voltage-controlled oscillator 154, whose transmission curve 164 is based on the audio carrier control voltage with minimum amplitude . Because of the return frequency S is centered and that a strong attenuation | 5> coupling nature of the loop 157 in its synchronizing at the video carrier frequency Phat || 30 The alternatives described above represent '£! passage of the low-pass filter 156 of the sound information, and illustrate various ways to the image carrier to \ fi so that the frequency of the converted signal (dampen differential and to prevent this carrier ence frequency at the input K) at the output of the mixer 144 is equal to the passage 151 of the phase detector 152 appears. When the H center frequency of the IF sound carrier and the picture carrier is not enough overall at this input 151 · ■.}, Phase of this signal is attenuates in quadrature to the phase of the IF 35, then a mixture, the appearance where ^r The video carrier component is thus the phase detector 152 working with the through-coupled FM demodulator for frequency demodulation of the video carrier component from the output of the mixer IF audio carrier. 144 take place and to a zero beat in the output ^;

Any common mode frequency modulations that carry signals that are within the audio frequency range

would be impressed on the two carriers for image and sound 40 and would therefore distort the sound information,

can e.g. B. by the local oscillator 116 in the FIG. 3 shows an alternative embodiment for ^;

Tuner or by additional devices such as the sound demodulation system of the television receiver

the tuner 110 upstream cable television according to FIG. 2. In Fig. 3 are elements that are used in construction and

sequence converter, individual elements of FIG.

are transmitted in signal and are therefore identified in phase detector 152, denoted by the same reference numerals as

turned off. there between the output of the mixer 144 and the

Since in the embodiment according to FIG. 2 a single input 153 of the phase detector 152 is a filter 166 IF amplifier is used to match amplified inserted in order to attenuate the picture carrier and substantially Allow image and sound carrier signals to pass through to the frequency-converting sound carrier. Hence are facilities

To deliver phase-locked loop 157, this 50 is like the filter 146 and / or the limiter 150 according to -

Embodiment less complicated and thus no F i g. 2, for the selective creation of the sound carrier

In this case, the input 151 of the phase detector 152 is more economical than the embodiment described further above

form. not mandatory. The filter 166 can be a bandstop filter

The input signals of the mixer 144 and the phase with a frequency represented by the curve 167

transmit detector 148 have such amplitude values that 55 be the output that provides maximum signal suppression

the input circuits of these circuits primarily the picture carrier frequency P and a minimal attenuation

on the frequency and phase of the input signals and at the sound carrier frequency S. Alternatively, For

do not respond to the amplitude. Thus, the filter 166 also produces a relatively narrow-band (/ .. B.

even a suppression of the amplitude modulation 500 kHz) band filter can be used, which is the one with the

of the ZF picture carrier reached. It should also be mentioned that ob-60 curve 168 has shown band-pass characteristics, their

probably also a center frequency at the audio carrier frequency S is at the output of the phase detector 152 and

Sum frequency signal (82.5 MHz) appears, the mod-

The simulation envelope of this signal essentially brings the P sym- quency.

is metric and therefore has no noticeable influence on the

Has sound baseband frequencies. Therefore, the need is the one delivered at the exit of the television tuner

The limiting effect of the limiter 142 is not so great to process the IF image carrier in a separate IF channel.

as required in an intercarrier system. tet to derive the video information. The audio information

This lesser degree of limitation has two positive mation, with the help of a frequency-converting pha-

sensor-synchronized loop (PLL) demodulates the one Mixer and a phase detector contains the mixer on the IF picture carrier from the output of the Tuner and the phase detector responds to the IF sound carrier from the output of the tuner.

In the following an embodiment will be described detects the interference in the video signal and recovers the audio information from a television signal, and with the help of an arrangement that phase-locked a single one Loop and can easily be fabricated as an integrated circuit.

According to FIG. 4, a television broadcast signal picked up by an antenna 208 is applied to a tuner 210 which converts the RF carriers for picture and sound of a selected television channel to intermediate frequencies, e.g. B. to an IF picture carrier frequency of 45.75 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 (FM signal). Conventional color television signal processing circuitry, including filtering and amplifying IF channel 214 and video detector 216 , is responsive to the IF picture carrier from output 212 of the tuner to demodulate the baseband composite video signal. This baseband signal is applied to the input 217 of a comb filter 218 , which separates the chrominance component C and the luminance component Y from the composite video signal and makes it available at assigned 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). The resulting electron beams are deflected in a known manner over successive horizontal picture lines to display an image on the screen of the picture tube.

The IF channel 214 has the conventional band-pass characteristic, as shown with the forward characteristic 221 of the IF picture carrier Flies is located on a 6 db down damped place of höherfrequenzten edge of the characteristic curve 221, and the IF sound carrier S at an approximately 25 db Attenuated location of the lower- frequency edge of characteristic curve 221. As a result, the video information of the remaining sideband can be demodulated by the IF sound carrier without significant interference. As already explained, because of the asymmetrical attenuation of the sidebands of the IF picture carrier, the IF transmission characteristic 221 causes a synchronous phase modulation of the IF picture carrier, referred to as Nyquist-SPM.

In the receiver according to FIG. 4, a frequency-converting phase-locked loop (PLL) 222 processes the IF sound carrier in a path that is separate from the processing device for the IF sound carrier in order to demodulate the sound information essentially without the interference of the Nyquist SPM. A buffer amplifier 224 couples the two IF carrier for picture and sound from the tuner output 212 on a picture-band filter 226 and a sound band filter 228. The image-band filter 226 has a symmetrical, relatively narrow Bandpaßcharakterisük 227 (for. Example, with a 3 -db bandwidth of 1 MHz), which is centered on the IF picture carrier frequency P (e.g. 45.75 MHz in the NTSC system) in order to allow essentially only the IF picture carrier signal to pass through. An IF amplifier 230 and a limiter 232 provide appropriate amplification and limitation of the IF picture carrier signal. The limited and thus essentially modulated IF image carrier from the output of the limiter 232 is applied to an input of a signal mixer 234 .

ίο The audio bandpass filter 228 has a symmetrical and relatively narrow bandpass characteristic 229 (with a 3 db bandwidth of e.g. 1 MHz) that is centered on the IF audio carrier frequency S (e.g. on 41.25 MHz for NTSC system) in order to allow essentially only the IF sound carrier and its immediate sidebands to pass through and to pass it on to an input of a phase detector 238 via an IF amplifier 236 . The IF amplifiers 230 and 236 can be constructed in the same way, e.g. B. each by an integrated circuit such as the IF amplifier type TA 7607 from the manufacturer Tokyo Shibaura Electric Co, Ltd. The limiter 232 can simply be formed by parallel-connected, oppositely polarized Schottky barrier diodes. A conventional automatic gain control (AGC) circuit 240 , which is responsive to the output of IF amplifier 236 (or alternatively to the output of amplifier 230) , provides AGC control voltages to IF amplifiers 230 and 236 in order to add their gain factors affect that 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 44 MHz in the case of the NTSC system), supplies a signal to the second input of the mixer 234. The mixer 234 may e.g. B. a double-symmetrical analog multiplier circuit such. B. be the module MC1496 from Motorola Semiconductor Products, Inc., which works in a switching mode under control by the amplitude-limited IF picture carrier (ie the picture 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 provide at its output a frequency converted signal indicative of the frequency and phase difference between its input signals. In the case of the NTSC system, the frequency difference between the input signals to the mixer 234 is 41.25 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 supplies a composite audio signal in baseband at its output (along with unwanted signals resulting from the demodulation process).

The output signal of the phase detector 238 is filtered in a downstream low-pass filter 244 in order to generate a control signal for the frequency of the voltage-controlled oscillator 242. The mixer 234, the phase detector 238, the voltage-controlled oscillator 242 and the low-pass filter 244 form the frequency-converting phase-locked loop 222. The bend

width of the low-pass filter 244 is on the one hand sufficiently large to accommodate the composite baseband audio signal to let through, but on the other hand narrow enough to suppress the higher-frequency unwanted signals. The let through composite sound signal 5 is z. B. given to a stereo decoder 246. if the composite audio signal contains stereo information, then decoder 246 decodes the audio signal and delivers the stereo signals for left and right to associated speakers 248 and 250. Is not stereo information is present, the decoder 246 provides the monophonic signal to the speakers.

In operation, the mixer 234 effects a frequency conversion of the IF picture carrier signal applied to its input and supplies an output signal whose Fre- is quenz corresponds to the difference between the frequencies of its input signals (e.g. 41.25 MHz). Undesirable Output signals according to the coupling of the input signals and the sum frequency of the input signals are attenuated due to the relatively narrow bandwidth of the low-pass filter 244. The amplitude of the phase detector output voltage 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 sent as a control voltage to the voltage-controlled oscillator 242 placed. The frequency of the output signal of the voltage controlled oscillator 242 and thus of the frequency converted 41.25 MHz output signal from the mixer 234 changes in direct relation to the amplitude of the control voltage in the sense of a decrease the phase difference between the signals at the inputs of the phase detector 23β When the input signals of 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 242 has the minimum amplitude. Therefore Because of the feedback nature of loop 222 in its synchronized state, the control voltage is the control voltage dimensioned at the output of the filter 244 so that the frequency of the converted signal (difference signal) am The output of the mixer 234 is equal to the mean frequency of the IF sound carrier and that the phase is diesss The signal is in quadrature with 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 filtering in the filter 244 corresponds to the sound information.

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

As mentioned, the frequency-modulated sound carrier contained in the output signal of the tuner 210 is generated by the Band filter 228 selected and amplified in amplifier 236. The amplifier 236 carried out by the AGC circuit 240 is controlled, ensures a constant long-term mean value of the amplitude of the sound carrier and removed thus all normally occurring amplitude fluctuations that are not caused by disturbances 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 the changes in amplitude caused by impulse noise, essentially constant Da phase-locked Loops are relatively insensitive to changes in amplitude, so there is no need to switch between a limiter to the amplifier 236 and the detector 238 for eliminating impulse noise Provide amplitude changes.

The output of amplifier 236 is therefore a suitable one Point to detect those changes in amplitude of the modulated sound carrier that make up a correction signal could be gained to reduce the defects in the video signal caused by impulse noise to reduce. In addition, since the bandwidth of the riter 228 is wide enough to accommodate the sound carrier and some of his Passing sidebands, this filter introduces a signal delay that is shorter than the delays in the video signal path so that there is enough time to compensate for defects in the video signal. A correction control signal generator 252, which has a synchronous detector 254 for detecting the caused by impulse noise Changes in amplitude may be advantageous be combined with the structure of the phase locked loop described above, using a minimal number of additional parts and in a manner that is easily compatible with that of the Tone demodulation used can be combined in a phase-locked loop expediently integrated circuit.

Since the output of mixer 234 has a frequency equal to the mean frequency of the frequency modulated Is a sound carrier, but is in phase quadrature, a 90 ° phase shifter 256 is used, which shifts the output signal of the mixer 234 by 90 ° in order to transfer it to an input of the synchronous detector 254 to give. So if this detector has the frequency-modulated sound carrier at its other input receives, then the phases of its two input signals are synchronous with each other (i.e. it exists In-phase), and the Synchroiidetektor 254 can in a known manner the changes in amplitude of the frequency-modulated Demodulate sound carriers. The detector 254 can e.g. B. a double-symmetrical multiplier circuit like the MC1496 integrated module mentioned above.

The amplitude changes derived at the output of the detector 254 are applied to a first input of a comparator 258, which receives a threshold direct voltage from a source 260 at a second input. The comparator changes its output state whenever the output of detector 254 goes through this threshold. The output of detector 254 is a slowly changing alternating signal having a relatively small amplitude, except when there is impulse noise or some other severe signal disturbance. In this case there is a relatively strong and rapid change in the output signal, which can go in a positive or negative direction, as a result of ringing 7 .. B. by interaction of the noise impulses with the RF circuit of the tuner 210. Therefore, can It may be expedient to provide a second comparator with a threshold of opposite polarity in order to detect deflections in both directions in the output signal of the synchronous detector. It is also possible to logically link two comparators with one another in such a way that an output signal is only generated for such an amplitude change that is known to be associated with a

19 20

Noise pulse post-oscillation is temporarily related to the place of that of the video detector

The output signal of the comparator is set by an incoming real-time signal by the

nen pulse generator 262 is conditioned and switched over by a switch 764 so that it increases by 1 H

Terminal 263 to the control input of a switch 264 delayed signal from terminal 270 of the comb filter

given, which receives a substitute video signal in the s when activated.

Comb filter 218 takes effect. The signal delayed by the pulse joint period is newly entered into the CCD register

rator 262 can be a monostable multivibrator given.

a pulse of prescribed amplitude and duration An advantageous method was described above (typically in the range of 1 to 10 microseconds) to generate using a comb filter. Experiments have shown that the duration of a special type of the real-time signal in the video signal path is usually in the range from 1 to 3 mi- of a color television receiver is delayed by a microsecond, so that a control pulse of 3 mi- nals has to be replaced. An alternative arrangement for microseconds to compensate for most of the noise pollution in black-and-white television receivers needs pulse is sufficient. In this case, the input is the point in time to end in each interval, e.g. B. during delay line to receive a real-time video of the horizontal blanking period. In this case the deosignal can be connected, and the switch sets the selection pulse generator to be an edge-triggered flip-flop, either the real-time signal or the delayed signal from the output of the delay line that is set by the output signal of the comparator and is reset by a separate 20 directly to the subsequent processing circuit. Zeilsteuerimpuls occurs, z. B. by dsn Horizontalsyn- Here the video signal does not run again in the chronimpuls. The comb filter 218 is in charge transfer technology only once, whereby it is delayed by one image line (horizontal scan and contains a charge-coupled steering period). In the case of a color signal circuit (CCD) which has a 1-H delay line 25, a delay line can also be used (ie a line with a delay time equal to that, ie a delay corresponding to a whole of a horizontal deflection period) integrated with the CCD number of horizontal deflection periods to achieve the same-summation sections as well as interrogation and hold marriage basic result. For an NTSC circuit that contains the required function of a color television signal, the transverse filter delay device for comb filtering the video can be, for example, a 2-H delay line, and in this case it is not necessary to change the phase to obtain the luminance and chrominance signals (Y and Q, to invert the chrominance component of the video signal, as described in US Pat. No. 4,158,209, in order to give the chrominance component the correct phase for the
memory elements connected in series, in which 35 In the case of the data requested above in connection with FIG. The signal can be used in a non-erasing manner in connection with a PLL audio signal detector which demodulates the audio information from one or more of these memory locations. While in the tapped, a certain signal delay 40 case of FIG. 4 separate IF amplifiers 230 and 236. An adder 266 forms the mean value, it is also possible to use the output of two interrogations of the video signal, one of which is the IF carrier signals supplied by the buffer 224 for half of a color subcarrier period and the other and tone in a common IF amplifier to verre by half a subcarrier period strengthen after as wurda described above.
1 H delay is tapped. The tapped and 45 While in the illustrated case the phase-synchronously delayed signal, the adder 266 contains a mixer 234, which is conditioned so that its chrominance component is converted by 180 ° (that is, by 41.25 MHz, the signal for the phase detector converted by half a color subcarrier period) with respect to the 238 and for the synchronous detector 254, it is also possible to shift the nominal frequency of the output delayed signal, which remains in the CCD circuit, so that the tapped 50 signal of the voltage-controlled oscillator is transferred to the sliding and delayed signal has the correct color phase in order to be able to change the frequency as well as the sound carrier frequency and to be able to serve as a substitute signal. At the output of the adder, without frequency conversion by the mixer 234 or 266, there appears a signal delayed by 1 H (ie to give a line deflection to the detectors 238 and 254, as is the case with the riode) Line in Fig. 4 is indicated. Of course, to a connection 269 is applied. The signal available at connection 55 is omitted in this alternative of mixer 234, 269 is then sent to the input cycle and would not be available to any 270 of the comb filter. Eliminate a more detailed before common-mode frequency modulation in the picture and description of the circuit for phase inversion of the sound carrier.

The chrominance signal is found in the US patent. In the embodiment described, this is 42 72 785. The comb filter 218 shown is e.g. B. used as a correction control signal to control the second integrated module T 3928 from Tokyo Shibau- se insertion of a delayed video signal, ra Co., Ltd., Japan, available. The control signal can, however, also be used in connection with The real-time video signal is sent to the input terminal other circuits for suppression or coming 217 of the comb filter and then used to compensate for impulse noise. So switch 264 to the input terminal 271 of the CCD-Re-65 could this Signa ' ζ. B. can be used to put the gisters. If it was found that in the real-time arrangement for automatic gain control signal a signal defect (noise pulse) is present, the television receiver is insensitive to then the signal delayed by 1 H from the terminal will make noise pulses in the video signal.

21 22

It should also be mentioned that the NTSC frequencies mentioned are only examples. The different frequencies can also be measured differently, depending according to the characteristics of the NTSC, PAL or SECAM television system used.

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Claims (16)

Patent claims: 1. Tone demodulator for a television receiver, whose intermediate frequency signal is one with the image information contains modulated image carrier and a sound carrier modulated with the sound information, with a PLL loop generating a reference signal for carrier demodulation, which has a phase detector, a downstream low-pass filter and an oscillator controlled by its output signal and from which a signal containing audio information is extracted, characterized in that that the output signal of the controllable oscillator υ (50; 154,252) is fed to the second input of a frequency converter (44; 144; 234), at whose first input the image carrier is located,
that the sound carrier is applied to the first input of the phase detector (48; 152, 238) and the output signal of the frequency converter is applied to its second input, and that the demodulated audio information is extracted from the output of the low-pass filter (52; 156; 244) will. 2. Tone demodulator according to claim 1, characterized in that the nominal frequency of the oscillator output signal is equal to the frequency difference between the picture carrier and the sound carrier, and that the frequency converter (44; 144; 234) has a mixer, the first input (B) of which is the picture carrier and the output signal of the oscillator (SO; 154> 052) can be fed to its second input and which supplies a signal with a nominal frequency equal to the frequency% of the sound carrier at its output. 3. Tone demodulator according to claim 2, characterized in that the intermediate frequency signal is a amplifying signal processing circuit (34,36, 40,42) is supplied, which is a practically unmodulated Image carrier supplies to the mixer (44). 4. tone demodulator according to claim 3, characterized in that the intermediate frequency signal is a first band-pass filter (38) is supplied, which has a symmetrical to the sound carrier frequency central pass band and its output via a first IF amplifier (46) to the first input of the phase detector (48) is switched. 5. Tone demodulator according to claim 4, characterized in that ia indicates that the amplifying signal processing circuit comprises a second band-pass filter (36) whose The pass band is symmetrical to the video carrier frequency and its input is the intermediate frequency signal is fed, and a second IF amplifier (40), which is between the output of the second Bandpass filter (36) and the first input of the mixer (44) is connected. 6. tone demodulator according to claim 5, characterized in that between the output of the second IF amplifier (40) and the first input of the mixer (44) connected to an amplitude limiter (42) is. 7. sound demodulator according to claim 1, 2 or 6 for multi-channel sound information, characterized by a multi-channel decoder circuit (54), the input of which is connected to the output of the low-pass filter (52) is coupled and at its output the information one or more of the audio channels occurs. 8. tone demodulator according to claim 2, characterized in that the phase detector (48; 152; 238) and the mixer (44; 144, 234) each by a double-balanced analog multiplier circuit are formed. 9. tone demodulator according to claim 2, characterized by a first filter (136), the input of which the intermediate frequency signal can be supplied ir *, the amplitude frequency response of which has two maxima (137a, 1370) whose vertices are centered on the frequencies of the video and sound carriers, and that on delivers the image and sound carrier to its output; and a second filter (146), which with the first or the second input (151 or 153) of the phase detector (152) is coupled and such Has an amplitude frequency response that the video carrier frequency is attenuated by a predetermined amount, which is significantly less than the predetermined attenuation of the sound carrier frequency. 10. tone demodulator 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 connected. 11. Tone demodulator according to claim 9, characterized in that the second filter (166) is connected between the output ass mixer (144) and the second input of the phase detector (152). 12. Tone demodulator according to claim 9, 10 or 11, characterized in that between the output of the amplifier (138) and the input of the mixer (144) a selection circuit (140, 142) is connected which at its output essentially has the image carrier supplies 13. Tone demodulator according to claim 12, characterized in that the selection circuit (140, i42) has a diode limiter circuit (142) which connects a practically unmodulated image carrier to the Input of the mixer (144) supplies 14. Tone demodulator 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 selection circuit (148, 150) is inserted, which causes an additional attenuation of the image carrier, so that the filter (146) results in less than the predetermined attenuation at the frequency of the image carrier. 15. Tone demodulator according to claim 14, characterized in that between the output of the amplifier (138) and the input of the mixer (144) is connected to a second selection circuit (140, 142) is that practically only supplies the image carrier to the mixer. 16. Tone demodulator according to claim 14, characterized in that the first and the second selection circuit (148, 150 and 140, 142) have diode limiter circuits (148 and 150).