DE472463C - Attenuator for simulating high attenuation figures, especially for measuring crosstalk in long coil lines - Google Patents

Description

Attenuator to simulate high attenuation indicators, especially for measuring crosstalk in long coil lines Determining the strength of the Crosstalk in coil lines can unileer by means of distortion-free attenuators The use of sinusoidal currents is subject to the condition that the output resistance of the attenuator is roughly equal to the wave opposite of the induced Line and the impedance of the receiving organ is chosen large against this.

The attenuators are shown in Figs. 1 and 2 of the drawing equivalent forms in question, in which the resistors reduce the impedance of the Lines and the resistors R simulate the coupling of the double line systems.

At the. However, the construction of these attenuators turns out to be a problem because of the large attenuation factor involved in crosstalk. As is well known, it follows from the theory of lines (see F. Breisig, Theoretische Telegraphie 1910, p. 3i7): For large 60 one can neglect r versus R and If there are uni lines with an average wave resistance of Z = 2ooo, then for the attenuator of the first type (Fig. I) it must be R = 20002. From this for PO = 8; r = 435 2, for βr, = ro; v - o, x8 2.

Since Y must be made variable, i.e. contacts are available, Because of their small size, these values are poorly suited for practical implementation.

For the calibration line of the second type (Fig. 2) follows r - 2,000 2, for 8; R_ = 2 98o ooo 2. for 3, = = o; R = 220300009-Here the values for R become impracticable. In order to eliminate these inadequacies and to arrive at practically feasible values, according to the invention the resistances r in the attenuator (Fig. 2) are subdivided and the resistance R is placed between the subpoints. Such a circuit arrangement is illustrated in Figure 3 of the drawing. To describe how this attenuator works, we assume, for the sake of simplicity, that r1 ' = r1 " = Y, and Y2 = r2' = r2. The desired effect is obtained when r2 is made smaller than r1, as can be seen from the following Put: R - r1 l = n y2, where n i.

Then transform the triangle ef bd (Fig. Q.) Into the so-called resistive star (Fig. 5). Its legs result in a known manner Since n should be large against i, there is also in the denominator. Yi so against y1, so that approximately p1 can be set for the denominator. Then p1 - One also obtains: The calibration can therefore be thought of as being replaced by the circuit according to Fig. 6. For this, however, the known approach applies according to equation (2) Because the number n is equal to the square root of ee, it turns out that practically executable values are obtained for the resistors, the magnitudes of which result in: For example, in the case considered above, Z - = y1. = R = 2000 9 and for, 6o 8; y2-52, .2, for ßo = io; r2 = _1g2. It is useful to make r2 fixed and R changeable. Then the relationships result, which are illustrated in Figs. 7 and 8: The value y. one chooses from a maximum bottom according to the relation (3). This reads if again is set The attenuation is then calculated from the two. Assumed quantities r1 and r2 according to equation (q.) in their dependence on the variable R. For example, if y1 - 2ooo for the above example is made, the result is ß. - io about y2 - 2o 9. Therefore, according to equation (q.), the relation applies

Claims (1)

PATENT CLAIM: Eichleitugg to simulate high attenuation figures, Especially for measuring crosstalk over long periods. Coil lines coming out of egg The output resistance simulating the apparent resistance of the induced line, a Input resistance and a 'simulating the coupling of the double line system' Resistance exists, marked by the fact that to achieve practically suitable Resistance quantities the input and output resistances (y 'and r ") are subdivided and the resistor (R) is placed at the partial points in such a way that the resistances (r ', r "and R): can be set independently of one another.