DE2133772C3 - Circuit arrangement for increasing the stop-band attenuation of a baseband fast shutdown - Google Patents

Description

The present invention relates to a circuit arrangement for increasing the blocking attenuation a baseband fast shutdown in telecommunications equipment, with the transmission line im Failure across the signal path by at least two separated by a series inductance in the signal path Switching contacts is switched to ground.

In the case of commercial communications engineering transmission systems, in particular the radio relay technology, rapid shutdowns are used for the baseband outputs required, which interrupt the signal path in the event of impermissibly high noise voltages.

Such a quick shutdown is subject to high requirements. It must be designed so that it over the entire frequency range of the baseband is effective. As an example, consider a requirement from at least 4OdB blocking attenuation within a frequency range of 0.3-8 MHz. Another The requirement is that only contacts across the signal path may be used to in the Signal path itself does not have to use any mechanical switching elements for reasons of operational safety; for this only the possibility remains open, an effective short-circuit of the signal path, which is common to all Frequencies is equally good to switch.

Various circuit arrangements for emergency shutdowns are already common. In Fig. 1 of the drawing, the simplest embodiment of a quick shutdown is shown. In the event of a malfunction, contact a1 of relay A shorts the signal to ground. The signal path ends on both sides with the characteristic impedance Z. The equivalent circuit diagram of this circuit arrangement according to FIG. 1 is shown in FIG. 2 of the drawing. At low frequencies, the blocking attenuation is determined by the transition resistance RaI of the contact al, for higher frequencies, on the other hand, the self-inductance LaI LaI of the contact al is also decisive. With the in F i g. 1, the blocking attenuation can be improved even further by inserting an inductance L, as shown in FIG. 3 shows. The capacitances Cl and Cl can optionally be used in order to reduce the influence of the inductance L in the operating state - that is to say when the contacts are open.

The Fig.4 shows this with closed contacts Valid equivalent circuit diagram for the arrangement according to FIG. 3, i.e. with two contacts connected in parallel. The above-mentioned improvement of the stop-band attenuation in the range of the higher frequencies of interest is based on the voltage division, which is approximately

ίο is given by the ratio LuW

Practical tests have shown, however, that with the arrangement according to FIG. 3 achievable blocking attenuation at very high frequencies is not yet sufficient because, on the one hand, the inductance L cannot be increased at will without impairing the properties of the arrangement for higher frequencies in the operating state and, on the other hand, there is often an undesirable magnetic ^{between the contacts a 1 and a} Coupling K is present.

The invention has therefore for its object to provide a circuit arrangement which ensures adequate to the required frequency range (0.3-8 MHz) blocking attenuation of an emergency shutdown. According to the invention, this object is achieved in that the series inductance is connected in series with a coupled second inductance which is included in the following signal path and which is switched in phase opposition to the series inductance. As a simplification of the circuit arrangement, it is considered that the switching contacts are arranged on a relay. To reduce the influence of the inductances in the operating state, the input of the series inductance and the output of the second inductance are each connected to ground via a capacitor.

The invention is illustrated in more detail by means of an exemplary embodiment of the circuit arrangement with the aid of the drawing described.

FIGS. 1-4 have already been explained in the introduction to the description;

5 shows the circuit arrangement according to the invention.

A signal is emitted from the generator G, which here represents the receiver including the baseband amplifier and has the characteristic impedance Zl.

Lie parallel to its output capacities Cl, and the first switching contact al of relay A. In the signal path, the first inductance is switched on as a winding Wl of a transformer, the all of the same at its output via the second switching contact relay A is connected to ground. The signal path is now via the coupled second inductance according to the invention, represented by the winding W2, at the output of which the signal with the characteristic impedance Z 2 is taken and a second capacitor C 2 is also connected to ground to compensate for the inductances.

The mode of operation is that via the second inductance L with the winding W2 when the contacts are closed, a small alternating voltage is coupled into the output line, which is the same amount as the residual alternating voltage across the contact when the phase position is opposite. With careful dimensioning, the residual AC voltage across the contact will all completely compensate.

h ¹ ; sated.

With the help of this circuit arrangement, it was demonstrably possible to increase the blocking attenuation to 60 dB.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for increasing the blocking attenuation of a baseband quick disconnection in telecommunications equipment, the transmission line being switched to ground in the event of a fault across the signal path by at least two switching contacts separated by a series inductance in the signal path, characterized in that the series inductance (L-Wi) a coupled second inductance (L-W2) included in the following signal path is placed in series, which is switched in phase opposition to the series inductance (L-Wi) 2. Circuit arrangement according to claim 1, characterized in that the switching contacts (a ¹ , a ") are arranged on a relay (^ 3. Circuit arrangement according to claim 1, characterized in that the input of the series inductance (L-Wl) and the output of the second inductance (L-W 2) are connected to ground via a respective capacitor (Ci, C 2).