SU1617496A1 - Fixed coaxial attenuator - Google Patents

Abstract

The invention relates to radio engineering and can be used in broadband measuring equipment. The purpose of the invention is to improve the matching in the range of operating attenuations up to 10 dB. The attenuator contains two segments 1 of a coaxial line, the outer conductors of which are formed by stepped bushes (CB) 2, and the inner conductors 3 are fixed in them by means of washers 4, which are connected to segment 5 with losses formed by a metal bush 6 installed between CB 2, and a thin film resistive plate (TRP) 7 fixed with contacts in the longitudinal slots of the metal sleeve 6 and in the grooves made in the ends of the 10 inner conductors 3. The ends of the 10 inner conductors 3 are truncated by planes parallel to the TRP 7. In The adjusting screws 11 can be installed to the metal sleeve 6. The length L of the segment 5 is made equal to (0.3 + 0.15 LGP ₁ / P ₂ ) λ ± 0.3λ, where λ is the critical wavelength of the lowest mode

P ₁ and P ₂ are, respectively, the power at the input and output of the attenuator for a given attenuation. The length L of each CB 2 is equal to (0.3 + 0.15LGP ₁ / Р ₂ ) λ _р ± 0.03 λ _р , where λ _P is the smallest wavelength of the working frequency range. The signal entering the attenuator undergoes reflections from discontinuities at the junction of its elements and is attenuated a predetermined number of times in TRP 7. Since each heterogeneity has its own frequency response of the reflection coefficient, then the variation in the ratio of the sizes of the ends 10 and the indicated choice of lengths L and L A predetermined frequency response of the reflection coefficient of the entire attenuator is provided. 1 hp f-ly, 2 ill.

Description

The invention relates to radio engineering, in particular to power control devices, and can be used in a broadband radio measuring apparatus.

The purpose of the invention is to improve agreement with a range of operating attenuations of up to 10 dB.

FIG. 1 shows the proposed attenuator, a general sectional view; Fig. 2 shows a line segment with losses.

The attenuator contains two segments 1 of the coaxial line, the outer conductors of which are formed by stepped sleeves 2, and the inner conductors 3 are fixed in them by means of washers 4, which are connected to cut 5 of the line with losses formed by the metal sleeve 6 installed between the stepped sleeves 2 and thin-film resistive pitch 7, fixed with contacts in the longitudinal slots x 8 of the metal sleeve 6 and in the grooves 9, made at the ends 10 of the inner conductors 3 of the corresponding segments 1 of the coaxial line. The ends 10 of the inner conductors 3 are truncated by planes parallel to the thin film resistive plate 7.

In the middle of the metal sleeve 6, i.e. on either side of the thin-film resistive plate 7 perpendicular to it, adjusting screws 11 can be installed. The length L of the length of 5 pines with losses is equal to

РЪ

L (0.3 + 0.15g-p) A ± 0.03

I

where A is the critical wavelength of the lowest mode;

PI and Ra are, respectively, the power at the input and output of a fixed coaxial attenuator for a given attenuation.

The length I of each stepped sleeve 2 can be equal to

I (0.3-fO, 15lg) lp ± 0.03A,

where Yar is the smallest wavelength of the working frequency range.

Attenuator works as follows.

The signal arriving at the input of a fixed coaxial attenuator, reflects reflections from irregularities at the junction of the stepped sleeves 2 with the metal sleeve and hits the connection points of the inner conductors 3c with a thin-film resistive plate 7, and the passage through the 5-line loss section is attenuated by a specified number of times in accordance with the attenuation value for which the thin film resistive plate 7 is designed. In this case, a small part of the floor, which is connected to the metal sleeve 6, also participates in the electr dynamic interaction with fields reflections from inhomogeneities. The re-reflected signals are added or subtracted in amplitude depending on the phase of the reflection at different frequencies of the working range and

give maximums and minimums of the reflection coefficient, the location of which depends on the ratio of the sizes of inhomogeneities.

Because each inhomogeneity gives

its frequency response of the reflection coefficient with a certain arrangement of maxima and minima, then a variation of the ratio of the sizes of the slots 9, ends 10 and the indicated choice of lengths of the 5th line with losses and stepped sleeves 2 depending on the specified attenuation within 10 dB provides such an addition partial reflection coefficient coefficients, at which a given

the dependence of the resulting reflection coefficient curve on frequency. The use of adjustment screws 11 makes it possible to enhance the effect on the resulting dependence of the reflection coefficient on frequency.

Thus, thanks to the choice of the lengths of the 5-loss-line segment and the stepped sleeves 2, an improvement in the matching in the operating attenuation range to 10 dB is achieved while reducing the attenuator dimensions.

Claims (2)

1. A fixed coaxial attenuator containing two coaxial line segments, the outer conductors of which are formed by stepped sleeves, and the inner ones are fixed in them by means of washers and which are connected by a loss line, formed by a metal sleeve mounted between the stepped sleeves and a thin-film resistive plate fixed in longitudinal slots of the metal sleeve and in the grooves made at the ends of the inner conductors of the corresponding segments of the coaxial line, truncated by planes parallel to the thin-film re-active plate, so that, in order to improve the matching in the range of working attenuations up to 10 dB, the length L of the segment loss lines are equal to L (0.3 + 0.151d) A ± 0.03 A, where L is the critical wavelength of the lowest mode; PI and P2 are, respectively, the power at the input and output of a fixed coaxial attenuator for a given attenuation. 2. The attenuator according to claim 1, about tl and h and y i and y, so that the length I of each stepped sleeve is equal to ten I (0.3 + 0.151 dp) Dr. ± 0.03 Dr. where dr is the smallest wavelength of the working frequency range. ten FIG. 2