DE2843977C2 - Circuit arrangement for obtaining the audio signals from a television signal - Google Patents

Description

The invention relates to a circuit arrangement for extracting the audio signals from one to one high-frequency carrier transmitted television signal, in which after a first mixing to gain

of the IF vibrations in a filter, on the one hand, the intermediate frequency Image signal band is separated and on the other hand a signal area, which is made up of the intermediate frequencies Assembled sound signals and signals in the vicinity of the intermediate frequency image carrier, taken and the audio signals in the difference frequency position are obtained therefrom by a second mixture will.

Such a circuit arrangement is known as a quasi-parallel tone from the FUNKSCHAU Haft 9/1978.

The object of the invention is to suppress video modulation and other interference as well as to further improve the signal-to-noise behavior in the audio channel and in doing so, in particular when using it integrated circuits to keep the effort low.

In order to achieve this object, the compounds required for the second mixture are provided according to the invention Signal oscillations extracted from the picture IF filter by means of an IF sound carrier trap, the one behind at least one damping pole each for an adjacent carrier of the upper and lower one Adjacent channel is arranged and in which also at least vibrations of the image carrier IF with one for the Mixture of sufficient amplitude occur.

The decoupling is expediently carried out in a sound carrier trap in which the image carrier IF oscillations occur Have maximum approximately in the vicinity of the image carrier.

Due to the decoupling made according to the invention, the in the preceding Filtertdl existing traps or blocking circuits, e.g. B. for the adjacent channel picture carrier and the adjacent channel sound carrier, as a limit limit for the extracted composite signal range, so that Interference from the adjacent channels is suppressed to a particular degree without the expense of selection means to increase.

The sound carrier trap used for decoupling can be caused by a further resonance between the image carrier and Sound carrier as a damping pole for a subharmonic of the differential carrier frequency of z. B. 5.5 MHz be; the attenuation pole is then placed on an intermediate frequency, which is opposite to the image carrier Distance of about 2.75 or 1.83 MHz.

According to a further development of the invention, the decoupled vibrations can be transmitted to the image carrier IF Matched filter and a limiter amplifier of the second mixer stage as reference oscillations, expediently with a phase shift of about 90 ° compared to the image carrier IF oscillations fed to the signal input, are fed. This gives a single sideband demodulation in which the unwanted and by limitation already reduced double sideband components in the vicinity rles Image carrier are additionally suppressed.

The invention is explained in more detail below with reference to the drawing, for example, which in

Fig. 1 shows an example with a filter from which the composite vibrations are taken, and with an integrated circuit, shown in functional blocks, for obtaining the tone difference frequency signal ;

F i g. 2 shows an embodiment of a circuit arrangement for the low-distortion amplification and Limitation of the composite signal (to obtain the reference signal).

The filter according to FIG. 1, the received vibrations of a television transmitter are from a signal source 1 in the intermediate frequency position fed in a tuning unit (not shown) with the aid of an oscillator and a first mixing stage. There is an impedance at the output of this signal source 1 effective that from an effective resistance 2. an inductance 3 and a capacity 4, which are indicated in the drawing for the sake of completeness, since they occur at input terminal 5 and are taken into account when calculating the following filter have to. For the invention, the structure and design of the entire up to the output terminal 6 are interposed Filters in detail are not important.

In the vibrations fed to such a filter, the image carrier can have a frequency of 38.9 MHz and the sound carrier offset by 5.5 MHz has a frequency of 33.4 MHz; the neighboring sound carrier is then at 40.4 MHz for reception in the VHF range or at 41.4 MHz for reception in the UHF range, and the neighboring image carrier is 31.9 MHz. The damping poles for these frequencies, in the in F i g. 1 with brackets indicated filter areas 11, 12 and 14 be realized.

In area 13 there is a trap for your own sound carrier attached, which is formed by the series connection of a capacitor 16 of 27 pF and a capacitor 17 of 26 pF with parallel inductance 18, which consists of the partial inductances 18a and 186 in series with consists of a capacitor 19, which in the simple case is a large separating capacitor. This trap can be at a Point of inductance 18, e.g. at a tapping point, but also at the connection point with the capacitors 16 and 17 or by means of a secondary winding, a signal can be taken via the line 20, which is due to the resonance occurring its own Provides sound signal at 33.4 MHz with increased amplitude. At the same time, the image signal IF oscillations also occur on with an amplitude which is in particular due to the voltage division ratio the capacitor 16 and 17 to the pick-up point at the inductance 18a, 186 for the line 20 results.

The transfer curve 21 to line 20 is shown on the right below terminal 6. The representation takes place in the attenuation level below a reference level corresponding to line 22. There are those above-mentioned attenuation poles for the neighboring image carrier of 31.9 MHz and for the neighboring sound carrier of 40.4 and 41.4 MHz and the transmission maxima in the vicinity of the sound carrier of 33.4 MHz and the video carrier of 38.9 MHz. By dimensioning the partial inductances described below 18a and 18 /> and the capacitor 19 is another Attenuation pole introduced at around 36.1 MHz. The character of a band filter is thus evident for line 20.

The vibrations received from the line 20 are one, preferably executed in integrated technology, Circuit arrangement 2ίί supplied to a terminal 26, which may be multi-stage with the input eires, controllable amplifier 27 is connected.

The output signals of the amplifier 27 are used to obtain a reference oscillation for demodulation i'her another amplifier 28 tuned to the IF picture carrier oscillation of 38.9 MHz Filter circuit 29 and then a limiter amplifier 30 is supplied. The filter 29 can be a single circuit can be formed with a quality of 50 to 80. By the

Filter 29 is the image carrier IF oscillation of 38.9 MHz with some of the neighboring signals as double sideband signals transmitted vibrations filtered out; there is also a phase shift of 90 °.

The vibrations filtered out in this way are severely limited in stage 30 in such a way that the sidebands caused amplitude modulation is largely eliminated and at the output of the stage a picture carrier IF A corresponding reference signal is available, which is fed to a single sideband mixer 33 will.

The mixer 33 also receives the image signal IF oscillations The output signal of the amplifier 27 contained in the range of 33.4 MHz is supplied. In the Step 33, which can be formed by a phase discriminator, takes place! " a single sideband demodulation of the audio signal oscillations with respect to the reference signal obtained at the output of stage 30, so that at the output of stage 33 the corresponding to the frequency difference between the image carrier and the sound carrier Sound signal difference frequency oscillations (intercarrier signal) occur and are fed to the output terminal 35 via an amplifier 34. The ones about that Oscillations guided by filter 29 are restricted to the area around the image carrier; they shouldn't be nyqüiiifiaiike have and are further through the limiter 30 of amplitude fluctuations and thus freed from the side ligaments. The 90 ° phase shift also results in demodulation of the double sideband components in the mixer 33 practically prevented such that predominantly the output at the output Audio signal difference frequency occurs. This is from the terminal 35 in a known manner the area around 5.5 MHz transmitting band filter and then fed to the audio frequency demodulator.

Since in the described manner a demodulation of the Double sideband components close to the picture carrier are avoided, the sync pulses are also avoided corresponding signal component obtained in stage 33, which could be used for control purposes.

According to a further development of the invention, a further mixer stage 41 is therefore provided which generates the output signal the stage 27 is fed to both inputs in such a way that a squaring takes place. This will be the sync pulses are emphasized and signals of lower amplitude (e.g. the video signals) more suppressed. In relation to a reference signal, a control signal is provided, preferably also in stage 41 formed that the deviations from the target value, z. B. the peak value in the line sync pulse interval. This control signal is a current generator stage 42 leads to ^ whose A.us ^ sn ^ sstrom a Capacitor 43, the z. B. is arranged via a terminal 44 outside the integrated circuit 25 is supplied. This gives an integrating control in such a way that the voltage across the capacitor 43 lasts as long is increased or decreased until the control error has become zero. Control takes place from the output the stage 42 and thus from the capacitor 43 to the control amplifier 27.

In the further stages connected to stage 35, e.g. B. a limiter for the filtered tone difference frequency oscillations, non-linearities occur; the resulting harmonics or mixed products can produce vibrations in the range of 55 MHz, which affect the audio signals as distortions. In order to dampen such Schwingungskompoiienten additionally, the inductance 186 of 0.62 μΗ and the capacitance 19 of 33 pF as a series resonance circuit at 36.1 MHz, that is to one of the carrier at 38.9 MHz by about 2.8 MHz different frequency be matched so that a corresponding pole of attenuation occurs in curve 21.

The signal transmitted through the filter 29, which also contains the double sideband components, is fed to the limiter amplifier 30 of the image signal carrier which extend up to approximately 1 MHz; in this area are in particular the direct current component of the image content and the sync pulses. The input signal of stage 30 thus covers a considerable range of amplitudes. For impeccable quality of the tone signal finally obtained, it is important that the output signal of the stage 30 from the Input amplitude is at least almost independent and also works linearly for the rest, so that the formation disturbing harmonics is avoided. The stage 30 should also work in a frequency-linear manner and that during the limitation Process the resulting harmonics of the video carrier well so that the limited signal obtained is as good as possible is exactly rectangular and can serve as a stable reference oscillation for the mixer 33.

Fig. 2 shows an integrable circuit suitable for this purpose, which is designed symmetrically so that the signals from the input to the output are processed alternately in push-pull mode.
At terminals 51 and 52, the push-pull input signal from filter 29 is fed to two emitter-follower transistors 53 and 54 with emitter resistors 55 and 56 of 1.5 kOhm, the emitters of which are connected to the bases of transistors 57 and 58. These together form a differential amplifier in that their emitters are connected via a resistor 59 of approximately 300 ohms, possibly with parallel capacitance 60, and are controlled via current source transistors 61 and 62 with emitter resistors 63 and 64 of 330 ohms. The base voltages for the current source transistors 61 and 62 are supplied from the base of a transistor 65, which is supplied with a current of 12 V from the supply source + U via a series resistor 66 of 10 kOhm, so that a corresponding voltage drop across the base-emitter path If a corresponding voltage drop occurs at the resistor 67 of 330 ohms connected to earth and thus to the other pole of the supply source U. By means of a transistor 68, the collector of which is connected to the supply voltage + and the base and emitter of which are connected to the collector or the base of the transistor 65, the required current supply for the connected bases of the transistors 61, 62 and 65 is ensured.
The collectors of the transistors 57 and 58 are connected to the emitters of the transistors 71 and 72, the switching elements enclosed by the dotted line 73 being initially disregarded. The bases of the transistors 71 and 72 are connected and connected to the tap of a voltage divider which is parallel to the supply source U and consists of the resistors 74 of 5.6 kOhm, 75 of 1.9 kOhm and 76 of 3.9 kOhm

By connecting the bases of transistors 71 and 72 to the voltage divider, they are practically on A fixed potential is placed in such a way that the emitters of the transistors 71 and 72 and those connected to them The collectors of the transistors 57 and 58 carry practically no alternating voltage. Controlling the

Transistors 57 and 58 are therefore carried out exclusively on the base and emitter; so is a maximum linear dynamic range ensured; the influence of the collector-base capacitance is eliminated.

The collectors of the transistors 71 and 72 are connected to the supply source + U via individual load resistors 77 and 78 of 220 ohms and a common resistor 79 of 1 kOhm. The collector voltages of the transistors 71 and 72 control the bases of the emitter sequences 81 and 82, whose collectors are connected to + U ι ο and whose emitters are connected to earth via resistors 83 and 84 of 2.7 kOhm; the output signals appear at terminals 85 and 86 and are then fed to the mixer 33 shown in FIG.

The differential amplifier with the transistors 57 and 58 is set so that saturation is reached even with low input voltages. Here can the indicated capacitor 60 also has a certain influence on the phase position in such a way that that together with the phase rotation possibly already effected in the filter 29, there is a total phase rotation of approximately 90 ° for the reference oscillation of the mixer 33 is ensured.

In order to improve the effect of the reinforcing limiter 30, the one within the dotted line 73 specified circuit can be added. This consists of transistors 91 and 92 that are in series with the transistors 71 and 72 are switched on and their bases also from a tap of the voltage divider, namely Hch between the resistors 75 and 76, controlled and thus kept at a practically constant potential will. The transistors 91 and 92 thus work like the transistors 7! and 72 as transistor amplifiers in Basic basic circuit; On the one hand, they cause a decoupling between input and output and show on the other hand, a linear behavior up to very high frequencies, which the fundamental wave of the IF picture carrier of Significantly exceed 39.8 MHz. There is also a differential amplifier made up of transistors 93 and 94 switched on, its connected emitter via a further current source transistor connected to the transistor 65 95 can be controlled with an emitter resistor 96 of 160 ohms. As a result, the Transistors 93 and 94 in the middle position the same currents as transistors 61 and 62; their control takes place through the difference between the current-dependent components of the base-emitter voltages of the transistors 91 and 92, and the collector currents thus obtained become the collector currents in a crossed connection of transistors 93 and 91 are added. The circuit cell within the dotted line 73 thus effects a doubling of the output current with otherwise the same modulation and frequency behavior.

Due to the voltage divider 74,75,76 are the bases of the transistors in basic basic circuit (71,72,91,92) only connected to ground via certain internal resistances. If an even lower resistance connection is required appears, you can easily emitter followers between the voltage divider taps and the bases of the respective transistors are switched on.

1 sheet of drawings

Claims (17)

Patent claims: 1.Circuit arrangement for obtaining the audio signals from a television signal transmitted on a high-frequency carrier, in which, after a first mixture to obtain the IF oscillations in a filter, on the one hand the intermediate-frequency video signal band is separated and on the other hand a signal range that is made up of the intermediate-frequency audio signals and signals in the vicinity of the intermediate-frequency image carrier, removed and the audio signals in the difference frequency position are obtained therefrom by a second mixture, characterized in that the composite signal oscillations required for the second mixture (stage 33) from the Büd-ZF-Fiker (1 to i9 ) are decoupled by means of an IF sound carrier trap (16 to 19), which is arranged behind at least one damping pole each (parts 11 and 12) for an adjacent carrier of the upper and lower adjacent channels and in which at least vibrations of the image carrier ZF with one sufficient for the mix end amplitude occur (curve 21). 2. Circuit arrangement according to claim 1, characterized in that in the composite Signal oscillations the amplitudes of the sound carrier IF oscillations and the picture carrier IF oscillations about in the ratio 1: 3 to 3: 1, preferably about 1: 1. 3. Circuit arrangement according to claim 1 or 2, characterized in that the decoupling of the composite signal oscillations in a sound carrier trap (16 to 19) in which the image carrier IF oscillations have a maximum approximately in the vicinity of the image carrier. 4. Circuit arrangement according to claim 3, characterized in that one edge of the to one Maximum leading transmission curve through the neighboring sound carrier trap (12) or the neighboring image carrier trap (11) is conditional. 5. Circuit arrangement according to one of the preceding claims, characterized in that the composite signal oscillations are taken from a sound carrier trap, which is on the output side The end of the image IF filter is arranged. 6. Circuit arrangement according to one of the preceding claims, characterized in that the Sound carrier trap (16 to 19) from which the composite signal oscillations are taken, as a damping pole for an IF oscillation corresponding to a subharmonic of the differential carrier frequency is trained. 7. Circuit arrangement according to claim 6, characterized in that the sound carrier trap (16 to 19) for the extracted composite vibrations corresponding to a damping pole half or a third of the tone difference frequency. 8. Circuit arrangement according to one of the preceding claims, characterized in that the composite signal oscillations through a filter (29) matched to the picture carrier IF and b5 a limiter amplifier (30) is fed to the second mixer (33) as reference oscillations will. 9. Circuit arrangement according to claim 8, characterized in that the second mixer stage (33) the composite signal oscillations are fed to the signal input and dcß the reference oscillations are supplied with a phase position that is about 90 ° with respect to the image carrier IF oscillations at the signal input is turned. 10. Circuit arrangement according to claim 9, characterized in that the 90 ° phase shift takes place at least partially in an integrated amplifier and / or limiter circuit (30). 11. Circuit arrangement according to claim 9 or 10, characterized in that the 90 ° phase shift takes place at least partially in the mixing stage (33) 12. Circuit arrangement in particular according to one of the preceding claims, characterized in that the composite signal oscillations are fed on the one hand to the signal input of a single sideband demodulator (33), in particular a phase discriminator, and on the other hand to a limiter stage (30) via a filter (29) matched to the image carrier ), which supplies the reference oscillations for the single sideband demodulator (33). 13. Circuit arrangement according to claim 9 to 12, characterized in that the 90 ° phase shift at least in part by means of, e.g. B. the limiter amplifier (30) upstream, filter (29) takes place 14. Circuit arrangement according to one of the preceding claims 8 to 13, characterized in that that the limiter (30) is formed by an amplifier, preferably a differential amplifier (57, 58) whose output controls at least one further transistor (71, 72) in the basic basic circuit. 15. Circuit arrangement according to claim 14, characterized in that between the differential amplifier (57, 58) and the further transistor (s) (71, 72) an additional transistor (91 or 92) in Basic basic circuit is switched on and that each collector of the differential amplifier (57, 58) with the base input of a further differential amplifier (93,94) is connected, whose collector outputs cross with the collectors of the others Transistors (91, 92) are connected in a basic basic circuit. 16. Circuit arrangement according to one of the preceding claims, characterized in that the composite signal oscillations are squared (step 42) and from this compared to one Reference value an amplitude control signal is formed. 17. Circuit arrangement according to claim 16, characterized in that the amplitude control signal is supplied as current (stage 42) to a capacitor (43), the voltage of which the gain control (Level 27) causes.