SU1272277A1 - Method of determining invariant stability factor of linear four-terminal network - Google Patents

Abstract

The invention retreats to engineering, radio measurements and provides an extension of the range of emittable (real values of invariant goat; 11 stability). At the input of a quadrupole (LPP), a 154JI transfer ratio, a PPP feedback ratio and a PPP transfer ratio when connected to its input or output of two resistive loads of different size. The magnitudes and method of switching resistive loads required; i1 to increase the goat (}) and the resistance to the patient of the LPC are determined by the tin of the measured LPC. A two-way matching condition is provided.The invariant stability coefficient is determined by the formula The device implementing this method consists of a high-frequency signal generator, an input and a terminal sender, 1x taps 2, matching Pf: -1I loads 3, LPP 4 , input (Л Io and output matched transformers 5, additional resistive load 6 or 7, indicator 8. To determine the feedback ratio generator 1 and indicator 8 msn: from; -: csta and. 1 il. N2 Yu Yu

Description

The invention relates to a technique of radio measurements and can be used to measure the invariant stability factor of a microwave transistor, which is in a small signal mode by a linear quadrupole. The purpose of the invention is to expand the range of measurable values of the invariant stability coefficient. The drawing shows a structural electrical circuit of the device that implements a method for determining the invariant stability coefficient of a linear quadrupole. The device consists of a generator 1 of high frequency signals, input and terminal directional couplers 2 with matched loads 3, intended for supply and removal of passing power, linear quadrupole A, input and output matching transformers 5, intended respectively for matching the system input and output imitations consisting of a linear quadripole 4 and an additional resistive load 6 or 7 connected to any of its terminals with immittances matched by loads 3, the indication ora 8. Additional resistive load 6 or 7razlichny largest and necessary to increase its coefficient Usto bility. The device works as follows. The choice of the place and method of switching on additional resistive loads 6 or 7, as well as their size (their ratio), are determined by the type of the measured (gay quadripole). Instead of a linear quadruple 4, a regular transmission line (jumper) is installed, matching transformers are output. 5 and a calibrated pass power level is displayed on the indicator 8. A linear four-port network 4 is installed together with an additional resistive load (connected to any of the four-terminal 4 terminals) with the value W, and measure the direct transmission coefficient of the system K "o". Swap the generator 1 and indicator B and measure the return coefficient of the system K p. Return the generator 1 and indicator 8 and place the input and output matching transformers 5 to obtain the maximum ratio transmission system K, with an additional resistive load 6 (7) of W ,. Replace the additional resistive load 6 (7) with an additional active immittance W and again with the help of matching transformers 5 achieve the maximum factor transmissions of a two-sided system K ,,, Compute the invariant coefficient, the stability by the formula: ISj1fli Y K where K y g is the invariant coefficient of stability of a linear quadrupole K y, is the stability coefficient of systems 1 consisting of the measured quadrupole and the additional active immitance (series-connected resistance or parallel-connected conductivity) value. W | ; Ku is the stability coefficient of the system consisting of the measured linear quadripole and the additional active immittance (series-connected resistance or parallel-connected conduction) with the value of W, oj, is the nominal transmission coefficient of the measured linear quadrupole or system; K orr is the return coefficient of the measured linear quadrupole or system; - the maximum coefficient of steady gain of the measured linear quadrupole; K is the maximum transmission coefficient of a two-way coordinated system with an additional active immittance of W ,;

rr

- maximum coefficient

transmission schedule of a two-way agreed system with an additional active imitance of W .; W,

- relation of additional

W, active imitats.

Claims (1)

Invention Formula The method for determining the invariant coefficient of stability of a linear quadrupole, which consists in applying a signal to the input of a linear quadrupole and measuring the transmission coefficient of a linear quadrupole, is different in that, linear quadrupole transmission coefficient when connected to its output or input, a resistive load of one values and resistive loads of a different size under the condition of two-sided matching, and the invariant stability coefficient Corr is determined by the formula TO U rf p-1 transfer coefficient; postback ratio; accordingly, the transmission coefficients in the two-way matching mode i are the ratio of resistive loads.