DE1268235B - Adjustable four-pole damping - Google Patents

Description

Controllable four-pole damping The invention relates to a controllable Damping quadrupole, in which the series branches with temperature-dependent resistances a certain temperature coefficient and the cross-branches with temperature-dependent Resistors of the opposite temperature coefficient are fitted.

In addition to four-pole damping poles designed as T-links, which are and in the series branches contain diodes as controllable resistors, which are used for the to be influenced high frequency signal the known disadvantages (cross modulation and Distortion factor formation), four-pole attenuation are already known, the opposite in the transverse and longitudinal branches with temperature-dependent resistances Temperature coefficients are fitted (German Patent 865 465) and the mentioned Do not have disadvantages. It is also known from the cited reference that temperature-dependent resistances opposite temperature coefficients in a direct current manner to be connected in series. This can also be done with 7v elements when the direct current is fed back to the common ground line relatively easily. Difficulties arise however, if you want to train the quadrupole attenuation as a T-link, what is of interest if the input resistance of the quadrupole is high when the load resistance is high should be independent of the attenuation variation. With such four-pole attenuation and even with L-shaped quadrupoles one would then have to use the direct current feedback Provide additional cross resistors, which are relatively low in such a quadrupole should be. This would result in a high basic attenuation of the quadrupole.

The object on which the invention is based is to provide a four-pole attenuation to be created in T- or L-shape, in which the mentioned disadvantages do not occur, So despite the return of the direct current to the common ground line none has high basic attenuation.

This problem is solved in that when the quadrupole is formed as an L- or T-link of the branch or branches and the branch of two high frequencies temperature-dependent resistors connected in parallel exist and that all temperature-dependent Resistors are connected in series with respect to the control direct current.

There is also a T-shaped damping quadrupole known, in which only the shunt branch is designed as a temperature-dependent resistor, and although there are two high-frequency parallel and direct current connected in series NTC thermistor provided. The achievable difference between maximum and minimum However, damping is insufficient for many purposes. By contrast, the invention Attenuators created with a larger control range and low basic attenuation.

In Fig. 1 shows an exemplary embodiment of a four-pole T-attenuation pole constructed in accordance with the invention. In this exemplary embodiment, the two series branches are formed by four NTC thermistors H1 to H4, two NTC thermistors in each case, namely H, and H2 or H3 and H4 being parallel in terms of high frequencies. The shunt branch is formed here by two high-frequency parallel PTC thermistors K1 and K2. In this circuit, capacitors C are switched on in such a way that the thermistors H1 and H4 and the PTC thermistors K1 and K2 for the direct current supplied to the terminal 1 are in series. The control voltage is applied between terminal 1 and ground. In the case of a large control current, the NTC thermistors are low-resistance and the PTC thermistors are high-resistance; this results in a low attenuation of the quadrupole. In contrast, when the current is low, the thermistors are high-resistance and the PTC thermistors are low-resistance; this gives a high level of high-frequency attenuation. For the control voltage, as can be seen from FIG. 1 results, only a single feed is necessary.

One can in the longitudinal branches of the arrangement of FIG. 1 instead of the PTC thermistors Hl to H4 also switch on PTC thermistors and thereby switch on in the cross branch Place the PTC thermistors K1 and K2. In such an embodiment you get a high damping by the quadrupole with a large control current, while a small HF attenuation is obtained with a low current. You can also, for example the thermistors H3 and H4 of FIG. 1 or the NTC thermistors H1 and H, fall away and then receives an L-shaped adjustable attenuator.

In Fig. 2 is the quadrupole attenuation of FIG. 1 shown in a coaxial structure. The inner conductor of the coaxial line branch bears the reference number 2, the outer conductor the reference number 3. The separating capacitances CI and C2 in FIG. 1 are implemented here by interruptions in the inner conductor. The three capacities C of FIG. 1 are shown in FIG. 2 realized by dividing the inner conductor 2 into three parts (Cm). The thermistors H1 to H4 are connected to these parts; Foils with a high dielectric constant can be inserted between these parts. The two PTC thermistors K1 and K2 are connected to the two lower parts of the three-part capacitance Cm. While the PTC thermistor K1 is galvanically connected to the outer conductor 3 with its other connection terminal, the PTC thermistor K2 is merely capacitively coupled to the outer conductor (C3). In the embodiment of FIG. 2, the capacitor C is formed by placing a metal foil on the outside of the outer conductor and interposing a dielectric intermediate layer.

So-called r-pearl thermistors, for example, can be used as NTC thermistors. which are melted down in a small glass jar with opposite connectors are to use. Small barium titanium disks can be used as PTC thermistors. The intrinsically disturbing parallel capacitance of these PTC thermistors changes with the temperature in the right sense, d. i.e., if the resistance is low, the parallel capacitance also has their maximum value.

Claims (2)

Patent claims: -1. Adjustable four-pole attenuation in which the series branches with temperature-dependent resistances of a certain temperature coefficient and the shunt branches with temperature-dependent resistances of the opposite temperature coefficient are equipped, d u r c h g e -k e n n n z e i c h n e t that when the Quadrupole as an L- or T-link of the longitudinal branch or branches and the transverse branch consisting of two each high-frequency parallel-connected temperature-dependent resistors exist and that all temperature-dependent resistances with respect to the control direct current in Are connected in series. 2. T-shaped damping quadrupole according to claim 1, characterized in that a coaxial line part for its implementation in coaxial form is designed as follows: Part of the inner conductor is removed and replaced by a Replaced arrangement, which consists of two capacitively coupled with the inner conductor ends End parts, each made up of two temperature-dependent resistors connected in parallel as well as one formed from three electrically conductive parts separated from one another There is a capacitor, with one resistor each of the two connected in parallel temperature-dependent resistor pairs are connected to one of the three parts, while the other two are connected to one of the other two parts that the two last-mentioned parts also to one of the two forming the transverse branch temperature-dependent resistors are switched on and that one of these resistors is directly connected to the outer conductor, while the other, to which the control current is fed, is capacitively connected to the outer conductor. Considered Publications: German Patent No. 865 465.