DE1270076B - Circuit arrangement for video demodulation for television receivers operating according to the differential carrier method - Google Patents

Description

Circuit arrangement for video demodulation according to the differential carrier method working television receivers The invention relates to a circuit arrangement for video demodulation for television receivers operating according to the differential carrier method using a bridge demodulator consisting of diodes connected in opposite directions, which is controlled by an additional carrier.

It is known that such television receivers have not yet been able to fully utilize the video frequency band broadcast by the transmitter, since the sound carrier in the receiver must be suppressed below the white value to 5010 of the image carrier amplitude before the demodulator. In the known transmission curve according to FIG . 1 , assuming an intermediate frequency carrier of 38.9 MHz, this must decrease in its sideband range from about 34.4 MHz so that the sound carrier arrives at -26 decibels (amplitude ratio). In order not to obtain an excessively steep slope of the transmission curve, it is unavoidable according to the prior art to reduce the sideband at 33.9 MHz practically by more than 14 decibels (factor 5). For this reason, the video frequency range of 4.5 to 5 MHz, which is important for horizontal image resolution, has not yet been able to be reproduced with full amplification.

Television receivers with a reduction in non-linear ones are known Distortion with feeding in an additional carrier synchronous to the image carrier on the only consisting of a diode video demodulator to overcome the disadvantages of a poorer one Avoid black and white leaps. The intermediate frequency signal is here over a narrow-band amplifier tuned to this frequency. One A small detuning, however, already results in a large phase deviation, although this is disadvantageous a large amount of circuitry required for phase synchronization per se is.

It is also known in television reception methods for residual sideband transmissions to suppress the auxiliary signal modulation with symmetrically constructed demodulation circuits, this auxiliary signal being fed as a signal voltage with pure double sideband modulation to the video rectifier to achieve low-distortion signal demodulation with sidebands asymmetrical to the carrier (German patent specification 956 690).

The removal of demodulation distortion in television receivers, both residual sideband distortion and single sideband distortion, is furthermore served by a known demodulator circuit which operates as a double sideband transmission system in that the detector signal derived from the message signal in the demodulator is essentially a symmetrical double sideband signal, which is also the carrier frequency Part of the sideband frequency ranges, which is then mixed with the detector signal to demodulate the message signal (Austrian patent 193 445).

The circuit arrangement for video demodulation according to the differential carrier method working television receivers using an oppositely switched Identifies the existing bridge demodulator with control via an additional carrier according to the invention now in that the two demodulator diodes of the image carrier of the intermediate frequency signal with its modulation with the same, the unmodulated Additional carrier but are fed with unequal amplitude in such a way that the out the output voltage formed by the sum of the additional carrier amplitude and the mean image carrier amplitude one diode is equal to that formed from the difference between these two amplitudes Output voltage of the other diode, and that the additional carrier amplitude is at least has three times the value of the mean picture carrier amplitude.

A modification of the circuit arrangement according to the invention is characterized in that the additional carrier with the same amplitude, but the image carrier of the intermediate frequency signal with its modulation with unequal amplitude are fed to the two demodulator diodes in such a way that the ratio of the effective degree of modulation on one diode to the effective degree of modulation on the other diode is lowered to about 0.8 to 0.9. The circuit arrangements according to the invention with asymmetrically constructed bridge demodulators eliminate the so-called "sound-in-picture interference" between sound and picture signals or they are reduced to a minimum that practically no longer occurs. As a result, however, the video bandwidth of 5 MHz emitted by the transmitter can now be fully utilized on the receiver side, as shown by a transmission curve according to FIG . 2 shows a frequency-dependent representation of an image intermediate frequency carrier assumed to be 38.9 MHz in relation to a sound carrier of 33.4 MHz as a function of amplitude. This transmission curve according to FIG . 2 has - compared to previously known disadvantageous conditions according to FIG. 1 - in the range of the audio carrier intermediate frequency of 33.4 MHz and the image intermediate frequency of 33.9 to 34.9 MHz no steep edge and thus allows maximum amplification of the entire video frequency range. This means optimal conditions in phase and amplitude also in this frequency range, which is important for horizontal image resolution. The very flat edge in the range of 33.4 MHz avoids the previously often disadvantageous conversion of the frequency modulation of the sound carrier into amplitude modulation, which led to the well-known horizontal disturbances on the screen that fluctuate in brightness and width in the rhythm of the sound modulation.

The circuit arrangement according to the invention also has the great advantage that the unmodulated additional carrier is used to generate the intermediate audio frequency (5.5 MHz), whereby the unpleasant background noise previously referred to as "intercarrier hum" can be suppressed.

You can also achieve with the switching measures according to the invention compared previously known demodulators up to 10 times higher audio intermediate frequency voltages, so that a sound IF tube can be saved as a result.

Finally, there is the advantage over known circuits, that the DC voltage component of the video signal is independent of that in the bridge demodulator fed-in additional carrier remains. The internal resistance of the bridge demodulator is kept very low, which in turn has a favorable effect on the video frequency response. Through this however, due to the larger load resistances, the diodes work with much higher levels Efficiency than before.

The nature of the circuit measures according to the invention is described below in the figures using several exemplary embodiments. It shows the other drawings F i g. 3 shows a symmetrical circuit arrangement, FIG. 4 shows a bridge demodulator circuit modified according to the invention with asymmetrical feeding of the picture carrier, FIG . 5 shows a further embodiment of a bridge demodulator circuit according to the invention with an asymmetrical feed of the additional carrier, FIG. 6 shows a symmetrical circuit with stabilization of the phase synchronization of the additional carrier oscillator.

A circuit according to FIG. 3 can be substantially divided into the actual bridging modulator 1 which lies within the dotted line and the dot-dash line relocated oscillator part 2 to generate the be fed into the bridging modulator auxiliary support consisting of the phase discriminator 3 and the oscillator tube 4. 5 is further the Bildzwischenfrequenz- Designated power amplifier tube, from the circle of which the broadband IF signal is fed into one diagonal of the bridge demodulator 1 with two diodes 6 and 7 connected against one another. In the other diagonal of the demodulator 1 is a from the oscillator 4 z. B. generated in a known ECO circuit, unmodulated additional carrier, which is synchronized via operating as a phase discriminator diodes 8/9 and a reactance diode 10 controlled by these on the image intermediate frequency carrier (38.9 MHz). The image carrier gets in the same phase to phase detector 3 as to the demodulator 1, while the synchronous additional carrier of the oscillator tube 4, however, shifted by extraction from the primary circuit of the tuned to 38.9 MHz bandpass filter 11 to the phase discriminator 3 to the on the secondary circuit of the filter 11 in the bridging modulator 1 is flowing additional carrier. This simple switching measure guarantees that the additional carrier, compared to the image carrier, has the relative phase zero at the diode 6 of the demodulator 1 and the relative phase-r at the diode 7. Consequently, the image carrier with its modulation is added to the unmodulated additional carrier at the diode 6, while it is subtracted at the other diode 7.

Between the taps 12 and 13 in the bridging modulator 1, the video image signal, and on the other hand Differenzträgertonsignal (5.5 MHz) are formed as the difference voltage of the two diodes 6 and 7 to the generated rectified voltages on the one hand. Both signals jointly pass through a low-pass filter 14 and are then separated like a switch by a trap circuit 15 balanced to 5.5 MHz. The audio signal is supplied to the audio IF amplifier and the video signal to the video output stage, as shown in FIG. 3 indicated.

The addition or subtraction according to the invention of image and sound carriers to one another at the diodes 6 and 7 in the demodulator part 1 results in different degrees of modulation at these diodes, which is demonstrated in the following by calculation: The degree of modulation at the diode 6 results in and to diode 7 too where degree of modulation without additional carrier, Z = additional carrier amplitude, B = mean image carrier amplitude.

To reduce the "sound-in-picture interference" and interference phenomena between sound and image signals, a certain ratio of the degrees of modulation "16" and M7 to each other is required, which is the factor shows which ratio should move within the following limits: if, according to the invention, the additional carrier is made about at least three times as large in terms of amplitude as the image carrier.

This inequality leads to an asymmetrical bridge circuit according to the invention in such a way that, compared to a symmetrical structure, the ratio of the effective degree of modulation at diode 7 to the effective degree of modulation at diode 6 is reduced to about 80 to 900! will. According to an embodiment according to FIG. 4 for this purpose, this can be achieved by using coupling coils with different numbers of turns 6 ′ and 7 ′ to one another for the diodes 6 and 7 connected against one another in the bridge demodulator 1 .

Another possibility of asymmetrical feed can be achieved according to the invention in that the ratio of the effective modulation levels at the diodes 6 and 7 to one another is determined by asymmetrical feed of the unmodulated additional carrier with optionally different amplitudes for the bridge demodulator 1 , as shown, for example, in FIG. 5 is shown. The additional carrier unmodulated according to the invention is fed to the diodes 6, 7 with different amplitudes, for which circuit the following generally applies: Z7 = Z6 + 2B, i. h .. with an additional carrier amplitude A, four times the value of the mean image carrier amplitude B for the diode6, the additional carrier for the diode7 must be six times the mean image carrier amplitudeB.

In Fig. 6 , a further circuit possibility is finally reproduced according to the invention, which has the advantage of additionally stabilizing the synchronization of the additional carrier in relation to the image intermediate frequency carrier, namely by a factor of 10, so that the capture and entrainment range of the phase synchronization now work independently of the image content and contrast can, by means of a limitation in the frequency discriminator circuit 16. This arrangement still works absolutely reliably even with a weak or dull image, which is of particular importance in the case of borderline reception. For television receivers with automatic tuning, a circuit according to FIG. 6 opposite FIG. 3 therefore no additional effort, since the phase discriminator 3 is connected in its one diagonal parallel to the frequency discriminator 16 of the automatic tuning system 17 . The frequency discriminator 16 is preferably used here as an amplitude-limiting ratio detector which, in cooperation with the amplifier tube 17 of the automatic tuning system, which works as a pentode limiter, generates a good amplitude limitation of the image IF carrier signal from the output stage 5 on the phase discriminator 3 with the diodes 8, 9 connected against each other. Furthermore, with narrow-band dimensioning of a band filter 18 in the frequency discriminator circuit 16, the image IF side oscillations below approximately 38 MHz can be suppressed, and thus at the same time any phase modulation of the image IF carrier signal. The bridge demodulator with diodes 6 and 7 is shown in FIG. 6 again carried out asymmetrically. Finally, the reactance diode of the automatic tuning system 17 in the channel selector is designated by 19.

Claims (2)

Claims: 1. Circuit arrangement for video demodulation for television receivers operating according to the differential carrier method using a bridge demodulator consisting of diodes connected in opposite directions, which is controlled by an additional carrier, d a - characterized in that the two demodulator diodes (6, 7) with the image carrier of the intermediate frequency signal its modulation with the same, but the unmodulated additional carrier with unequal amplitude are supplied in such a way that the output voltage of one diode formed from the sum of the additional carrier and mean image carrier amplitude is equal to the output voltage of the other diode formed from the difference between these two amplitudes and that the additional carrier amplitude is at least has three times the value of the mean picture carrier amplitude. 2. Modification of the circuit arrangement according to claim 1, characterized in that the two demodulator diodes (6, 7) of the additional carrier with the same amplitude, but the image carrier of the intermediate frequency signal with its modulation with unequal amplitude are supplied in such a way that the ratio of the effective degree of modulation to the a diode (7) is reduced to the effective degree of modulation at the other diode (6) to about 0.8 to 0.9. 3. Circuit arrangement according to claim 1 or 2, characterized in that the asymmetrically supplied with the image carrier of the intermediate frequency signal or the additional carrier bridge demodulator (1) is connected directly in parallel to a phase discriminator (3) regulating the additional carrier oscillator (4). 4. A circuit arrangement according to claim 3, characterized in that the phase discriminator (3) of the additional carrier oscillator (4) with its one diagonal parallel to the frequency discriminator (16) operating as an amplitude-limiting ratio detector (16) of the automatic tuning system (17) of the receiving device (F i g. 6). Documents considered: German Patent No. 956 690; Austrian Patent No. 193 445; British Patent No. 900 824; U.S. Patent No. 2,738,380.