DE2622954C2 - Circuit arrangement which can be used to correct distortions caused by non-linearities in a transmission system - Google Patents

Description

The invention relates to a circuit arrangement according to the preamble of claim 1 and its Use in a pre-equalizer. Such a circuit arrangement is known from DE-AS 12 11 690.

Every transmission system has a more or less imperfect linearity. It is therefore necessary correct the linearity, regardless of whether the performance requirements are strict or not, because the efficiency of the transmission systems, for example a television station, decreases very quickly as the intrinsic linearity improves; it is therefore beneficial to have a good one To achieve efficiency with a mediocre linearity, which is then improved by a correction arrangement will.

It is known to use a negative feedback circuit for this purpose to use, or an arrangement that reintroduces the non-linearity products into the system, obtained by comparing the signals before and after the treatment by the transmission system have been.

These solutions have the disadvantage that they are for everyone

Transmission system in which they are used are specific and, above all, have application limits, especially in the case of modulated signal correction circuits which require the addition of Modulators and demodulators require the linearity of which is often not much better than that to be corrected Linearity is

From the already mentioned DE-AS 12 11 690 a circuit arrangement for the correction of distortions caused by nonlinearities in a transmission system is known which has an input transformer which applies the input signal applied to it with the same phase and amplitude to two parallel circuit branches, of which the first has an attenuator and an amplifier connected downstream from it and the second has an amplifier and an attenuator connected downstream from it. The attenuator of the second circuit branch is followed by a 180 ° phase shifter. The signals emitted by the two circuit branches are then applied to an output transformer, which generates the corrected output signal by adding up Factor π are different. However, this circuit arrangement can only eliminate this one, n-th harmonic.

Another solution, which in principle can be used if the systems to be corrected are stable Transfer factor consists in the use of non-linear pre-equalizers designed in this way are that they deliver non-linearity products, which are then those of the systems to be corrected compensate.

For this purpose it is known to use circuits with one or more diodes, the non-linearity product which depend on the level of the transmitted signal. These orders largely lacks the adaptability, because the introduced non-linearity is dependent on the level of the signals to be transmitted changes abruptly, which is generally not in accordance with the laws of change of the non-linearity products of the transmission systems

From DE-OS 21 43 707 and US-PS 38 25 843 non-linearity pre-equalizers are also known which contain two parallel circuit branches between an input directional coupler and an output directional coupler, the first of which includes a delay circuit which only delays the signal during the the second contains a circuit arrangement for generating non-linearity products, the distortions are reproduced, which occur in the transmission system and are to be corrected. That delayed Signal is combined in the output directional coupler with the non-linearity product signal in such a way that a pre-equalized signal is generated, which is then amplified in the amplifier of the transmission system gives the corrected amplified signal.

The invention is based on the object of a generator to specify the generation of non-linearity products that correspond to those occurring in a transmission system Correspond to distortions as closely as possible.

By pre-distorting the signal to be transmitted, this is intended to correct this distortion as far as possible be made possible.

This object is achieved by the circuit arrangement specified in claim 1

A use of the circuit arrangement according to the invention is specified in claim 5.

A pre-equalizer using the generator according to the invention is specified in claims 6 to 9.

Embodiments of the invention will now be described in more detail with reference to the drawing. In the drawing shows

F i g. 1 shows the diagram of an embodiment of a generator for generating non-linearity products according to the invention,

F i g. 2 shows the scheme of a pre-equalizer in which the generator of FIG. 1 is used and

3 shows a modified embodiment of the pre-equalizer from F i g. 2, which is built into a frequency converter arrangement

The in F i g. 1 shown generator A for generating nonlinearity products contains two directional couplers 15 and 16, each of which has a first pair of conjugate connections 2, 3 and 9, 10 and a second pair of conjugate connections 4, 5 and 11, 12, respectively Terminal 2 is connected to input terminal 1 of the generator, and terminal 11 is connected to output terminal 14. The connections 3 and 12 are each terminated with their characteristic impedance 6 and 13, respectively. The connection 4 is connected to the connection 9 via a first circuit branch which contains an attenuator 8, which is followed by an amplifier 7; the connection 5 is connected to the connection 10 via a second circuit branch which contains an amplifier 17, which is followed by an attenuator 18

In the following description it is assumed that the various circuits associated with one of the terminals the directional couplers 15 and 16 are connected to have an impedance as close as possible to the Characteristic impedance of the corresponding connection

The amplifiers 7 and 17 must have the same linear phase response so that the phase difference between the signals present at terminals 4 and 5 is equal to the phase difference between those at the terminals 9 and 10 existing signals.

The amplifier 7 receives due to its position behind the attenuator 8 and possibly because of the Coupling coefficient of the directional coupler 15 has such a low level that it does not cause any noticeable distortion.

On the other hand, the amplifier 17 delivers non-linearity products that depend on the level of the signal transmitted by it Depend on the signal.

It is assumed that the directional couplers 15 and 16 have the same phase difference between their respective have conjugate connections.

The signal mix fed to input 1, for example a VHF or UHF television signal comprising a picture carrier, a color carrier and a sound carrier contains, is then divided into two parts on the connections 4 and 5 of the directional coupler 15, which then can be found at the connections 9 and 10 of the directional coupler 16, and also at the connection 10 the from; Amplifier 17 generated non-linearity products are present.

With a relative overall gain of the two circuit branches, the coupling factor of the directional coupler 15 and 16 are taken into account, the

Conclusions 9 or 10 supplied power of the original signal is totally destroyed in the resistor 13 connected to the summing connection, and the non-linearity products are divided between the connections 12 and 11, so that the output 14 of the generator only supplies these non-linearity products, in particular the intermodulation and Cross-modulation products between the three signals contained in the composite television signal chosen as an example.

In a preferred embodiment of the invention, the directional couplers 15 and 16 are identical to one another and have a coupling coefficient of 3 dB; they can be of any type known per se, such as 90 ° couplers or hybrids with 180 ° phase shift, two-way ferrite directional forks (in-phase or out-of-phase), "magic T", etc., depending on the operating frequency and bandwidth required.

In this embodiment, the transfer factors of the two circuit branches are the same, and the gain factors of the amplifiers 7 and 17 are equal to each other, as well as the attenuation factors of the attenuators 8 and 18, which can be chosen to be equal to the reciprocal of the gain factors of the amplifier at a low level, see above that the power destroyed in the resistor 13 , apart from the circuit losses, is equal to the power of the signal fed to the input 1 of the generator, while the output 14 emits half the power of the non-linearity products generated by the amplifier 17 and fed to the terminal 10

Such a generator is particularly suitable for use in a pre-equalizer.

In Fig. 2 represent all circuit parts which have the same reference numbers increased by 100 as in FIG. 1 wear a circuit structure with two directional couplers, which is that of Fi g. 1 is the same, with terminal 101 being the input and terminal 114 being the output of the pre-equalizer

The connections 104 and 109 are connected to one another via a first circuit branch which, one behind the other, has an attenuator 23, a generator A of the circuit shown in FIG. 1 includes a linear amplifier 20 with adjustable gain and a phase shifter 21; input 31 and output 34 of generator A correspond to terminals 1 and 14 of FIG. 1, respectively.

The connections 105 and 110 are connected to one another via a second circuit branch which is formed by a delay line 22

The delay line 22 has a delay time that is the delay time of the first Circuit branch is the same

As with the arrangement of FIG. 1, the signal to be corrected fed to input 101 is divided into two parts between the first and the second circuit branch; the sum of these two parts appears at connection 112, which in this case is used as output 114 of the VGrentzerrer.

By adjusting the phase shifter 21 and the gain factor of the amplifier 20, it is possible to adjust the phase and the level of the non-linearity products generated by the generator A , which are summed in the directional coupler 116 with the signal part transmitted via the second circuit branch, so that the distortions are compensated for which are then caused by the output amplifier which is fed via the pre-equalizer.

The attenuator 23 is not absolutely necessary for the operation of the pre-equalizer; In connection with the setting of the gain factor of the amplifier 20 , however, it makes it possible to maintain a constant transfer factor of the first circuit branch in that a different level is obtained at the input of the generator A for each attenuation value of the attenuator 23 , i.e. a different level for

ίο each of the non-linearity products generated in this way; the dimensioning depends on the properties of the transmission system to be corrected. That The extent of the correction can be dosed solely by setting the gain factor of the amplifier 20.

The phase shifter 21 must have the same phase shift for the entire band of transmitted signals result.

The last restrictive condition can be omitted if the pre-equalization takes place before a frequency conversion takes place, d. H. at the intermediate frequency as described below.

In the arrangement of FIG. 3 have all circuit parts with the same reference numerals as in FIG. 2 the same function and the same position in the circuit.

A first mixer stage 122 is inserted into the first circuit branch instead of the phase shifter 21. A second mixer 123 is inserted between the delay line 22 and the connection 110 in the second circuit branch.

A local oscillator 124 supplies the frequency required for the frequency conversion to the mixer 123 directly and to the mixer 122 via a phase shifter 121; this phase shifter could indiscriminately be connected upstream of one or the other mixer stage.

This pre-equalizer works in the same way as that of FIG. 2, but the correct phase setting of the signals is facilitated since the broadband transmitted signal no longer goes through the phase shifter; this can therefore be narrow-band, although it still gives all components of the frequency spectrum, regardless of their frequencies, a uniform phase shift.
Experience has shown that such a pre-equalizer is particularly easy to use and is suitable for very different types of transmission systems.

Furthermore, the change in level corresponds to the non-linearity products generated by the pre-equalizer in Depending on the applied level, an equal change in the non-linearity products resulting from the to corrective system will be generated; this enables a valid correction to be obtained when the Output power of the amplifier changes

In this way it was possible to intermodulate with a 50 watt television transmitter of the type mentioned as an example from -47 dB to less than -54 dB and the cross modulation from 20% to 7% for the same transmission capacity, in principle without any possible repercussions on the stability of the Transmitter.

1 sheet of drawings

Claims (1)

Patent claims: 1.Circuit arrangement which can be used to correct distortions caused by non-linearities in a transmission system, with an input circuit which divides an input signal applied to its signal input into two circuit branches, the first of which is an attenuator and an amplifier connected downstream of it and the second one Amplifier and an attenuator connected downstream of this, and with an output circuit which combines the signals emitted by the two circuit branches into an output signal, characterized in that the circuit arrangement is designed as a generator for generating non-linearity products in such a way that the input circuit and the output circuit each designed as a directional coupler (15, 16) that the two decoupled connections (2, 3) a first pair of connections of the first directional coupler (15) with the two mutually decoupled connections (9, 10) of a first pair of connections of the second directional coupler (16) are connected via the first or second circuit branch, that one (2) of each other decoupled connections of the second pair of connections of the first directional coupler (15) forms the input of the generator, that the first circuit branch and the second circuit branch have the same linear phase response as a function of frequency, that the overall gain of each of the two circuit branches at a very low level of the input signal in Each of the two directional couplers (15, 16) is determined as a function of the coupling coefficient in such a way that there is a minimum residual voltage of the input signal at the differential connection (11) of the second pair of decoupled connections (11, 12) of the second directional coupler (161 ), and that this differential connection (11) denotes the non-linearity product e forming output of the generator. 2. Generator according to claim 1, characterized in that the directional couplers (15, 16) have the coupling coefficient 3 dB and that the first circuit branch and the second circuit branch have the same overall gain. 3. Generator according to claim 2, characterized in that the directional couplers (15, 16) are 3 dB directional couplers with a 90 ° phase shift between their mutually decoupled connections and that the amplifiers (7, 17) are equal to each other. 4. Generator according to claim 3, characterized in that the damping factor of each of the attenuators (8, 18) is the inverse of the gain of the amplifier (7, 17) at a low level. 5. Use of the generator according to one of the preceding claims in a non-linearity pre-equalizer, characterized in that the non-linearity products emitted by the generator can be combined with a signal to be amplified by the pre-equalizer. 6. Pre-equalizer according to claim 5, characterized in that the two mutually decoupled connections (104,105) of a first pair of connections of a first directional coupler (115) with the two mutually decoupled connections (109, 110) of a first pair of connections of a second directional coupler (116) are connected via a first or a second circuit branch that one (102) of the two decoupled connections of the second connection pair of the first directional coupler (115) forms the input of the pre-equalizer and the other (103) with its characteristic impedance (106) is completed, that the generator (A) for non-linearity products is in cascade with an amplifier (20) with adjustable gain in the first circuit branch, that the second circuit branch contains a delay line (22) and that a Phase shifter (21) is provided for generating a relative phase shift between the output voltages of the first and second circuit branches. 7. Pre-equalizer according to claims, characterized in that that the phase shifter (21) indicates in the first, da3 the phase shifter (21) in the first Circuit branch lies 8. Pre-equalizer according to claim 6, characterized in that the first circuit branch and the second circuit branch each contain a mixer stage (122, 123) which is inserted before the junction of the relevant circuit branch with the associated terminal of the first terminal pair of the second directional coupler (116) that the two mixer stages (122, 123) are fed by a common local oscillator (124) and that the phase shifter (121) is inserted between the local oscillator (124) and one (122) of the mixer stages. 9. Pre-equalizer according to one of claims 6 to 8, characterized in that the first circuit branch in cascade between the generator (A) for non-linearity products and the first directional coupler (115) contains an attenuator (23) which controls the setting of the operating point of the generator ( A) , a constant overall gain of the first circuit branch being set by setting the gain factor of the amplifier (20).