DE3110919C2 - Amplitude and transit time equalizer - Google Patents

Abstract

The invention relates to a circuit for amplitude and transit time equalization of frequency-modulated signals. It consists of two pairs of delay equalizers (LZ1, LZ2), which are controlled via a common voltage divider network (STN). A desired runtime behavior can be set by changing the voltage divider ratio. For the amplitude equalization, the signal modulated by this amplitude is tapped via a rectifier (DGL) after the first pair of propagation time equalizers (LZ1) and the signal demodulated with this and its amplitude adjustable is fed to a phase modulator, the output signal of which is returned to the signal path after the second pair of propagation time equalizers (LZ2) is coupled. The second delay equalizer pair (LZ2) and the network connected in parallel have the same delay times.

Description

The present invention relates to an equalizer Order to compensate for the amplitude and delay time distortions of frequency-modulated signals in one Radio relay system, consisting of a first time-of-flight equalizer with quadratic time-of-flight behavior that supports the frequency-modulated input signal into an amplitude-modulated converts, a circuit for converting this amplitude-modulated signal into a phase-modulated signal, with which the inclination of the differentiated gain can be set, and a second delay equalizer, which has the same but inverted quadratic delay behavior as the first Has delay equalizer

Such an arrangement for equalizing distortions that usually occur in radio relay systems the transit time and the amplitude (differential gain) can be found in DE-OS 25 47 242. Such distortions are expressed in inclined positions of the curves plotted against the frequency differential gain and the transit time of frequency-modulated transmitted over the radio relay system Signals.

It is now important to compensate for these inclinations with an equalizer arrangement. It should be possible be able to compensate for inclines with positive and negative slopes of any size.

The invention is now based on the object of providing an equalization arrangement of the type mentioned at the beginning specify, in which an easily manageable setting option is realized with little circuit effort for the inclinations of the transit time and dsr differential amplification, namely for inclinations with any large slopes and with both positive and negative signs.

The object is achieved according to the invention in that the two delay equalizers each consist of two in the Signal path switched 3 dB couplers exist, both of which have 3 dB outputs offset in phase by 90 ° each a Z.C element containing a capacitance diode are connected that the capacitance diodes of the two Runtime equalizers are interconnected via a voltage divider network so that a change in the Voltage divider ratio cine shift of the two quadratic Laufseitkui / s with respect to the Frequency caused by the same amount but opposite to each other and that the circuit for the Skew adjustment of the differential gain from a diode rectifier bridge that derives from the Signal path after the first time-of-flight equalizer, the amplitude-modulated signal branched off is demodulated, a voltage divider connected to the two outputs of the diode rectifier bridge, its tap is connected to an amplifier via a low-pass filter, and one connected to the amplifier Phase modulator exists, which shifts the signal behind the second delay equalizer in its phase specifically as a function of the demodulated signal applied to the voltage divider tap.

Appropriate designs of the equalizer arrangement according to the invention are dependent on the subclaims remove.

Advantages of this equalizer arrangement are that for the setting of the two inclined positions in each case only one potentiometer is required and that repercussions when adjusting the inclination of the differential amplification on the running time are almost impossible.

The invention will now be described in greater detail on the basis of an exemplary embodiment shown in the drawing explained. the

Fig.! shows an equalizer arrangement and in FIG

Fig.2 are two square curves of the The running time and some of the resulting slanted running times are shown.

The equalizer arrangement of FIG. 1 has two transit time equalizers LZ 1 and LZ2 connected in the signal path. The first transit time equalizer LZ1 has a quadratic transit time behavior r1 plotted against the frequency, as shown in FIG. 2. The quadratic transit time curve τ 2 drawn in FIG. The transit time curve τ 1 corresponds to *, is implemented by the second transit time equalizer LZ2

Both transit time equalizers consist of two individual transit time circuits connected in series, from whose transit time behavior the quadratic transit time curves τ 1 and τ 2 result. Each of these individual transit time loops consists of a 3 dB coupler K \, KY, K2, K2 ' inserted into the signal path, the 3 dB outputs of which are each connected to an LC element. In fact, two identical LC elements are always connected to the two 3 dB outputs of a coupler. They consist of the series connection of an inductor Lit, L 12, LW, L 12 ', L2 !, L22, L21', L 22 'of a capacitor CIl, C12, ClI', Ci2 ', C21 for all delay loops. C22, C21 ', C22' and a capacitance diode DiI, D 12, D11 ', D12', D21, £) 22, D21 ', D22'.

In each of the individual delay loops belonging to the delay equalizers LZ 1 and LZ2, the capacitance diodes DW, D \ 2 ', D2 \', D22 'are also connected in parallel with a capacitor CW, C \ 2 ··, C2 \ ", C22". These parallel-connected capacitances cause an increase in the total capacitance of the LC elements and thereby a corresponding shift in the time-of-flight curves compared to the respective adjacent individual time-of-flight circuit in terms of frequency, so that the desired r> quadratic time-of-flight curve τ 1 or r 2 sets. In order to be able to make a few corrections to the runtime curves, some capacitors of the individual runtime circuits are designed to be tunable.

All capacitance diodes D 11, D 12 and D 11 ', D 12' of the first delay equalizer LZ1 with capacitance diodes £> 21, D22 and D2Y, D22 are connected via a voltage divider network STN, at whose corner points cie voltages + Kund - / are located 'of the second delay equalizer LZ2 linked. By changing the voltage divider ratio with the help of the potentiometer r'l, the voltage on the capacitance diodes of the transit time equalizer LZl rises or falls to the same extent as it, in the opposite direction, falls or rises on the capacitance diodes of the transit time equalizer LZ2. As a result, the resonance frequencies of the LC elements in the first transit time equalizer LZ 1 and those of the LC elements in the second transit time equalizer LZ2 can be shifted by the same amount but in opposite directions to one another. This means, however, that the quadratic runtime curves with respect to the center frequency, for example 140 MHz, experience a shift that is the same for both runtime curves but has a different direction. Due to the mutual offset of the runtime curves LZ1 and LZ2 depending on the t> o size of the offset for the entire equalizer arrangement, transit time slopes of different gradients arise, as shown in dashed lines in FIG Runtime curve rl is shifted towards lower frequencies. Correspondingly, the slope becomes negative if the runtime curve τ 1 is shifted to lower frequencies and the runtime curve r2 to higher frequencies. If the two runtime curves, as shown in FIG a horizontal run time is established.

The position described above makes it possible to use just one potentiometer Inclination of the running time can be adjusted continuously.

After the first delay equalizer LZl, which converts the frequency-modulated signal applied to terminal A into an amplitude-modulated signal, a 3 dB branch VZ is connected through which part of the power of the amplitude-modulated signal is fed to an amplitude demodulator in the form of a diode rectifier bridge DGL.

The with the demodulator from the '; amplitude-modulated! The base band obtained (7th B. 60 kHz to 12MHz) is passed through a low-pass filter TP, which suppresses the signal frequency (140 MHz), to the baseband amplifier V. With the potentiometer P2 connected to the outputs 1 and 2 of the diode rectifier bridge, the amplifier V driving signal amplitude changed in terms of their magnitude and sign and thus any inclination of the differential gain can be set which is necessary to compensate for the inclination of the differential amplification occurring in the frequency-modulated radio signal. The output of the amplifier is connected to a phase modulator via further low-pass filters TPZ and TPZ ', also to suppress the signal frequency (140MHz), which converts the amplitude-modulated signal into a phase-modulated signal. The phase modulator consists of a 3 dB coupler K 3 inserted in the signal path behind the second delay equalizer, the 3 dB outputs of which are each connected to a Ti LC network. Such a phase modulator has already been described in DE-OS 25 47 242. The LC networks consist of an inductance L 3 or L 3 'in the parallel branch and a capacitance diode DZ or DZ' connected to the low-pass filter TPZ or TPZ '. Both varactor diodes are connected to the common voltage - V to determine their operating points. The entire circuit branch, which is parallel to the second delay equalizer LZ2, has a delay which is exactly the same as that of the delay equalizer LZ 2.

The effect of the circuit branch just described is that the signal behind the second delay equalizer LZ2 has a phase shift proportional to the amplitude modulation. This allows any inclination of the differential Compensate for the amplification of the frequency-modulated signal.

A limiter, not shown in FIG. 1, is connected to the output terminal B and suppresses the remaining amplitude modulation superimposed on the equalized frequency-modulated signal.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1.Equalizer arrangement to compensate for the amplitude and delay time distortions of frequency-modulated signals in a radio relay system, consisting of a first delay time equalizer with quadratic delay time behavior, which converts the frequency-modulated input signal into an amplitude-modulated one, a circuit for converting this amplitude-modulated signal into a phase-modulated signal, with which the inclined position the differential gain is adjustable, and a second delay equalizer, which has the same but inverted quadratic delay behavior as the first delay equalizer, characterized in that the two delay equalizers (LZ 1 and LZ2) each consist of two 3 dB couplers (K 1, KV and K2.K2 ¹ ) , both of which have 3 dB outputs offset by 90 ° in phase, each with a capacitance diode (D 11, D XL.D 11 ', D 12' and D 21, D 22, D 21 ', D22 ¹ ) containing LC-Giied (L 1 i, C ί ί, D i ί; L Ί2, C ί2, D 12; ...) wired are that the capacitance diodes of the two transit time equalizers are interconnected via a voltage divider network (STN) so that a change in the voltage divider ratio causes a shift in the two quadratic transit time curves (r 1, τ 2) with respect to the frequency by the same amount but opposite to each other and that the circuit for setting the inclination of the differential gain from a diode rectifier bridge (DGL), which demodulates the amplitude-modulated signal branched off from the signal generator after the first delay equalizer (LZX) , in a voltage divider connected to the two outputs of the diode rectifier bridge (P2 ), the tap of which is connected to an amplifier (V) via a low-pass filter (TP) , and a phase modulator (K 3, D 3, L 3, -to D 3 ', L 3') connected to the amplifier The phase shifts the signal after the second delay equalizer (LZ2), specifically depending on the amount at the voltage part pending demodulated signal. 2. Equalizer arrangement according to claim 1, characterized in that the second delay equalizer (LZ2) and the circuit (DGL, PL TP, TPZ, TP3 ', D 3, L 3, D 3', L 3 ', K 3) have equally long transit times for setting the inclination of the differential gain. ϊο 3. Equalizer arrangement according to claim 1, characterized in that the phase modulator consists of a 3 dB coupler ^ 3) connected in the signal path behind the second delay equalizer (LZ2) , at the two of which are 3 dB outputs phase-shifted by 90 ° from one another LC network (L3. D3, L3 ', D3') is connected to a capacitance diode (D3, D3 '), which is connected to the output of the amplifier (^ via a low-pass filter (TP3, TP3').