SU141902A1 - Method for automatic measurement of slow drift frequency of reflective klystrons - Google Patents

Description

The present invention relates to methods for automatically measuring the slow drift of the frequency of reflective klystrons.

The proposed method differs from the known ones in that the frequency-modulated signal of the klystron is passed through a high-Q resonator, a bell pulse from resonator 1; it is transformed into a linearly growing and nod together with a sawtooth voltage, modulator) osh, the klystron frequency, the input amplitude discriminator (Schmidt circuit) and the frequency drift is determined by the duration of the discriminator output pulses measured by the magnitude of the constant co-current using, for example, the electronic electronic potentiometer EPP-09.

The use of this method increases the accuracy of the measurement} 11 Y.

FIG. Figure 1 shows a block diagram of a device using the proposed method; on . 2 - voltage diagrams in various elements of the device.

The electronic rearrangement of the reflective klystron / (within the limits determined by the linearity of its modulation characteristic and the maximum possible frequency drift over the considered period of time) and the shift (up to the trigger threshold) of the amplitude discriminator (Schmidt scheme) 2 is produced by the same sawtooth plane from the generator 5 sawtooth voltage

A high-quality wave-echo resonator 4, to which the matched load 5 is connected, is tuned to the klystron generation frequency /, corresponding to the optimum voltage Lo on the reflector. The klystron is connected to the echo resonator through attenuator 6. When the klystron is modulated by the reflector, the sawtooth is - voltage, its frequency will change around the carrier frequency / o according to the same law.

No. 141902-2 in the output, when the frequency of the klystron, changing, passes through the value of U1 A) the settings of the echo resonator fo, at the output of its crista | 1thly exguTopa there will be pulses having the form of a resonant characteristic | xr resonator. These pulses occur at the time of the UVE ShoyLuar sawtooth voltage (at the power supply and turn signal), when it passes through the value Uo, and |

corresponding to each other / o, is investigated with a doubled frequency of the product.

If the frequency of the klystron mixes with the frequency of the echo resonator setting and becomes equal to /, under the influence of the harsh and orbiting factors, pulses will occur at times t and T, i.e. values fo. Thus, the frequency shift of the klystron on Af fo-f leads to a proportional shift of the pulses from the echo resonator relative to the sweeping sawtooth voltage by the time D / 2-t. In this case, the pulses arising at the time point T in the reverse motion of the saw are not taken into account, since they are suppressed in the circuit.

The pulses of the echo resonator are amplified by a low-frequency amplifier 7 to the magnitude necessary for reliable operation of the amplitude discriminator 8, and then using a single-oscillator 9 and a generator 10 of linearly growing sawtooth voltage.

The duration and amplitude of these pulses do not depend on the frequency deviation and are mainly determined by the parameters of the one-shot circuit. The linearly expanding sawtooth pulse from the output of the shaping circuit and the sawtooth voltage from the generator 3 are summed and fed to the input of the discriminator 2.

As can be seen from the voltage diagram, depending on the position of the sawtooth pulse relative to the reference sawtooth voltage, a square pulse appears at the output of the amplitude discriminator 2, the duration of which is equal to the duration of the sawtooth voltage at the amplitude discriminator triggering threshold.

Thus, changing the frequency of the klystron / from / o to / i leads to a proportional increase in the duration of the pulses at the output of the amplitude discriminator 2.

An automatic electro potentiometer / L for example, such as EPP-09, which records changes in the constant component of these pulses with changes in the frequency of the klystron under study, is installed at the output of the device.

For all other equal conditions, a higher accuracy of measurements using this device is achieved due to the high stability of the frequency of the echo resonator, which is the reference frequency during the measurements.

P r e l m u z o f e i u

A method of automagical measurement of the slow drift of the frequency of reflective klystrons, characterized in that, in order to increase the measurement accuracy, the frequency-modulated signal of the klystron is passed through a high-quality resonator, the bell 1 megapulse from the resonator is converted into linearly growing, and served together with a sawtooth voltage modulating the klystron frequency, to the input of the amplitude discriminator (Schmidt scheme) and the frequency deviation is determined by the duration of the output pulses of the discriminator, measured by the value of component of the current using, for example, an automatic electronic potentiometer EPP-C9.