DE2513700C2 - Method to compensate for amplitude distortions in radio relay systems - Google Patents

Description

The present invention is concerned with a method of compensating for amplitude distortion in transmitters of directional radio systems, consisting of at least one intermediate frequency amplifier, one Mixer with oscillator, a f-ing filter, its Phase delay compensated by a delay equalizer connected upstream of the intermediate frequency amplifier and a traveling wave tube in the exit.

Directional radio links are wireless multiple lines with message channels according to frequency in lie next to each other in a wide frequency band. These transmission systems must be very linear Have transfer characteristics so that the individual channels do not influence each other and Nachburkanäle don't bother each other.

The modules used in such a system are not so linear that this requirement is placed on the Linearity of such a system is met. There are even building blocks used that are quite remarkable Exhibit non-linearity. This non-linearity applies to eliminate. There are two ways to make these nonlinearities ineffective. One uses either special equalizer elements, that is, networks with dummy elements, or one switches Modules with a given non-linearity against each other in such a way that their non-linearity is compensated.

In order to achieve an effective and as broad-band linearization as possible, one must strive to achieve the Eliminate non-linearities where they arise. This means that the non-linearity must not only be applied on Make the end of an overlap corner consisting of several sections, but if one Non-linearity occurs, for example, at the transmitter, this should also be compensated at this point.

Distortions that arise in a transmitter should therefore also be equalized in a transmitter in order to to allow a distortion-free signal to reach the next receiver via the associated radio field.

If distortions arise in this receiver, these will have to be eliminated in its components.

An arrangement for equalization on the transmitter side is known from DE-PS 8 69 220. However, will - so that only unwanted modulation products are suppressed at the output of the modulator. Amplitude distortion, that arise in the modulator and a downstream traveling wave tube compensates for this Arrangement not.

Based on the arrangement mentioned in the introduction, phase delay distortions ΦF occur in a filter 4 connected downstream of mixer 3, which are compensated for in delay equalizer LZA 1 <!> L connected upstream of mixer 3 and intermediate frequency amplifier 2. This distortion is initially a delay time distortion, which is balanced when the condition ΦΖ. = - <PF is met. In addition, however, there is also an amplitude modulation corresponding to the 2nd derivative of the phase response according to the frequency.
la The incoming signal is thus pre-distorted in the delay equalizer 1 in order to then be compensated for by the delay distortion inherent in the filter 4. The mixer 3 following the amplifier 2 is supplied with two signal powers.
>> 1.) The amplified intermediate frequency signal from the

Intermediate frequency amplifier 2 and
2.) a signal power from an oscillator that is mixed with the intermediate frequency signal. These two signals have a predetermined level so that in most cases the mixer 3 is no longer operated in its linear part of the characteristic curve. Ks distortions arise here, namely these distortions consist of a portion of non-linearity KN and a portion of a υ conversion of an amplitude modulation into a

Phase modulation, which in the following is to be referred to as AM / PM conversion.
The proportion of non-linearity KN, which changes the modulation index of the AM generated in the delay equalizer so that a residual amount of amplitude modulation remains after the filter, together with the AM / PM conversion of the traveling wave tube WFR 5, results in an amplitude distortion DA 1 at the output of the Transmitter.

In addition, the AM / PM conversion results in an amplitude distortion in the mixer, which is output unchanged to the output via the traveling wave tube 5 and denoted by DA 2. If the oscillator is too high or low, the sign of the amplitude distortion changes. A switchover would have to take place in the case of a compensation in the IF stages of the receiver.

The invention has now set itself the task of making the sum of the two distortions (DA 1 + DA 2) equal to zero so that the two distortions compensate each other at the transmitter output. The main advantage is that there is no difference in overlay or underlay.

This object is achieved according to the invention. μ that the working point of the mixer, which is dependent on the intermediate frequency level supplied and the signal level of the oscillator, is dimensioned in such a way that the conversion of the amplitude modulation into phase modulation that occurs in the mixer leads to an amplitude distortion, which results in the conversion of the amplitude modulation into phase modulation in the traveling wave tube compensated.
This inventive idea solves very simple ones

Way the non-linear distortion of a mixer with the non-linear distortion of a traveling wave tube to balance each other so that both compensate each other. The advantage is that only the two powers, intermediate frequency level and oscillator level, are mutually balanced at the input to the mixer so that none at the output of the transmitter There is no longer any distortion and a linear signal is transmitted over the radio field.

The invention is based on a circuit diagram in conjunction with a table showing the distortions of the shows individual building blocks as physical quantities, explained in more detail

The delay equalizer LZA 1 compensates for the distortion of the filter 4, represented by the designations in line 1 Φ L = -ΦΚ

Line 2 identifies the distortions of the individual components: the delay equalizer LZA 1 supplies an amplitude modulation AML with an FM modulation; the mixer supplies two different causes of distortion, a non-linearity KN and an AM / PM conversion with the amount KP (M); The filter 4 produces an amplitude modulation AMF; the traveling wave tube WFR 5 provides an AM / PM conversion with the amount KP (W).

Line 3 shows the relationships that result from the proportion of non-linearity KN of the mixer 3: the transit time equalizer LZA 1 supplies an amplitude modulation AML; In the mixer 3, this, together with its non-linearity KN, results in the amount (1- KN) AML. This amount is split up in the filter 4, namely, A ML + AMF = O compensate one another. at (Φ L + Φ F) = O, and result in the traveling wave tube WFR 5 together with its AM / PM conversion: 0 · KP (W) = O, i.e. no distortion. In contrast, the non-linearity of the mixer 3 - KN with the amplitude modulation AML of the delay equalizer LZA 1 together with the AM / PM conversion KP (W) of the traveling wave tube WFR 5 produces an amplitude distortion DA 1.

In line 4, the relationships are shown - when the mixer contributes a portion of the AM / PM conversion KP (M) . The transit time equalizer 1 supplies an amplitude modulation AML. In the mixer 3, AML is converted into the amplitude distortion of the variable by the AM / PM conversion of the mixer

'" KP (M) - AML = DA 2.

The filter 4 again compensates the amplitude modulation components from the delay equalizer 1 and filter 4 to 0. In the traveling wave tube, there is no π effective distortion, at the same time

AM = O ■ KP (W) = O.

In contrast, the product of the amplitude modulation of the delay equalizer 1 with the AM / PM conversion of the mixer 3 KP (M) as the output of the transmitter gives the amplitude distortion; DA 2, since in the filter 4 and also in a traveling wave tube 5 no further distortion transformations occur.

According to line 5, in the column of the mixer 3

. · -> the value for the AM / PM conversion factor KP (M) = X and the value for the non-linearity of the mixer 3 KN = y are given: -v and y are the parameters for setting the operating point of the mixer 3. Here occurs the resulting amplitude

j (i distortion accordingly

(DA = AML ■ (xy KP (W))
on. The proportion disappears at (- = KP (W)): \ and \

j- are functions of the IF voltage and dos Oscillator pcgcls

Ilicr / u I sheet

Claims (1)

Claim: Method for compensating for amplitude distortions in transmitters of directional radio systems, consisting of at least one intermediate frequency amplifier, a mixer with oscillator, a subsequent filter, the phase delay of which is compensated by a delay time equalizer connected upstream of the intermediate frequency amplifier, and a traveling wave tube arranged at the output, characterized in that the of The operating point of the mixer (3), which is dependent on the intermediate frequency level supplied and the signal level of the oscillator (Fosz), is dimensioned in such a way that the conversion of the amplitude modulation into phase modulation (KP (M)) into amplitude distortion (KP (M) ■ that occurs in the mixer (3) AML) , which is the result of the conversion of the amplitude modulation into phase modulation in the traveling wave tube {-KN- AML ■ KP (W))
compensated.