SU493178A1 - System v.ch. powering a linear accelerator resonator - Google Patents

Description

the linear accelerator resonator into two identical parts located at a fixed distance, to stabilize V. ch. floor in the resonator by applying feedback on the reflected wave, to simplify the tuning of B. ch. generator, reduce the operating power level in the device elements and increase stabilization accuracy.

This is achieved by the fact that, in the proposed device, the accelerator resonator is supplied from two identical outputs of the end stage V. A generator. Through directional couplers with a power division factor of 1/2, the second output arms of each of which are also connected to the resonator through nonvariant phase shifters with nonreciprocal phase shift. . The feedback ring covers only the end stage of the V.C. generator, and the feedback signal is a signal proportional to the sum of the waves reflected from the resonator inputs, which are extracted in the separated arms of two directional couplers and fed to the input of the G-bridge, which together with two variable length lines is a smooth attenuator of the reflected wave and performs a smooth adjustment of the feedback signal. The feedback signal in the desired phase is formed by a stable wave falling from the preliminary stage of the generator with the power: T-bridge. The output arm of the 7-bridge addition, in which the difference signal is separated, is connected to the input of the final stage of the generator, thereby automatic power output of the output stage of the generator is implemented and the amplitude and phase V are stabilized. A beam in the resonator is loaded. In addition, due to the resulting branching of the lines of communication, the level of working power in the passive elements of the device is reduced.

The drawing shows a diagram of the device proposed by V. Ch. Powering a linear accelerator. The resonator / is connected to the final stage 2 of the generator using two directional couplers 3, one of the output arms of each of which includes a non-reciprocal phase shifter 4 with a non-reciprocal phase DD shift. Here it is assumed that the phase lengths of the communication lines between the resonator / and the output arms of each of the directional couplers 5 for the waves falling from the couplers differ by 1/2. The arms of the directional couplers 3, in which the waves reflected from the resonator are extracted from the resonator, are connected to the output arms of the T-bridge o, which is a weakening of the reflected wave, through lines 6 of variable length.

By simultaneously shortening one line 6 and extending another line 6 (which can be done by moving the G-bridge 5), it is possible to vary the distribution of power between the output arms of the G-bridge 5, thereby adjusting the feedback signal.

One of the output shoulders of the G-bridge 5 is loaded for a matched load 7, and the second output shoulder from which the feedback signal is taken is connected to one of the input shoulders 7; the addition bridge 5 via a phase shifter .9. Phaser 9 is the initial setting of the phase ratio in the control ring.

Another input shoulder of the G-bridge 8 is connected to the output of the pre-terminal cascade 10 of the generator. One of the output shoulders of the G-bridge of addition 8 is loaded on a matched load 7, and the other output arm is connected to the input of the final stage 2 of the generator.

The end stage 2 of the generator has two identical outputs that are connected to the input arms of the directional couplers 3 via the same communication lines.

iB of the initial state, the resonator / is tuned and loaded with the nominal beam current; all the inputs of the resonator are electrically identical and matched to the communication lines. The terminal stage 2 of the generator is set in a somewhat undercontrolled mode, in order to ensure the linearity of the amplitude response, and has a predetermined gain factor. The power required by the end stage cascade 2 of the generator is taken from two identical outputs of the cascade and through two lines of communication of the same phase length is fed to the input of the directional couplers 5. The power supplied to the input of each coupler is divided in half between the two output shoulders. The ratios of the phase lengths of the communication lines of each coupler with a resonator are the same for the waves incident on the resonator and reflected from the resonator. The phase lengths of the links of the coupler with the resonator for the incident waves differ from each other by / 2. Such a choice of the ratio of phase lengths ensures the complete addition of the powers in the resonator, which arrive at its four inputs. Thus, when the loaded resonator is matched with the communication lines, all the power generated by the final stage is introduced into the resonator and provides the necessary level of accelerating field with a predetermined phase. When the load of the resonator is changed by a beam or its detuning, the amplitude and phase of the V.Ch. floor in the resonator changes ωg, and at all inputs of the resonator there appear reflected waves with the same amplitudes and phases. A nonreciprocal phase shifter 4 is connected to one of the communication lines of the output arms of each coupler with a resonator, which provides for the incident and reflected waves in this communication line a phase difference difference of l. In this case, the phase difference between the waves reflected from the resonator in the cross sections of the output arms of each directional coupler will be a multiple of the corresponding phase difference for the waves incident from the resonator in these sections with an accuracy of 2 l / g, where, l, 2. . . Under these conditions, the reflection from the advertisement is fully branched off into the expanded shoulders of the directional bearers. which are connected to the input shoulders G -:,; 5; via 5 lines 6 of the length of the circuit.

The amplitudes and phases of the waves reflected from the resonator inputs in its unfolded arms are equal to each other. 7-bridge 5, together with the variable-length line 6 of the axis 1, allows smooth control of the power of the reflected wave that enters the feedback link. This adjustment is carried out at a tune of stabilization for a given gain of the final stage. While simultaneously shortening one and extending another line 6 (which is easily accomplished by moving the G-bridge 5), the ratio of the phases of the waves reflected from the resonator in the input sections of the G-bridge 5 changes. This allows the power of the reflected wave to be redistributed and the ballast matched load. Thus, the amplitude of the feedback signal is continuously controlled and the stabilization is adjusted.

The feedback signal in the form of a voltage wave with amplitude, proiortial amplitude reflected from the resonator wave, and with the phase corresponding to the phase reflected from the resonator wave, goes to one type of inputs of the G-bridge of addition 8, to the second input of the G-bridge of addition comes voltage wave from the finite generator cascade 10 with a stable amplitude and phase. At the output of the G-bridge, connected: /: to the input of the generator end stage, a wave is emitted, proportional to the algebraic difference of the incident waves, and on the ballast load 7 connected to the second G-bridge, a wave is proportional to the sum of the padak waves.

The initial phase relationships in the feedback ring are established by the phase shifter 9 when setting up the device. Thus, the IRI is changed by 1 and the load of the resonator by a beam or its amplitude and the phase of a stable voltage wave supplied to the excitation of the eye cascade using feedback through the reflected wave are changed according to the amplitude and phase reflected from the wave resonator, but only with a counter sign. Accordingly, the amplitudes and phases of the waves incident from the terminal stage of the generator vary. and the amity and phase of the radiation at a given cross-section of the resonator (determined by the initial setting of the phase ratio in the feedback ring, for example, at the ce-maximum of the electric field) and in the cross-section of the communication lines of the resonator with - distance, multiple I / 2 (I - working wavelength) from a given cross-section of the resonator, remain constant regardless of load changes. Wherein

The values of the glides and phases of the voltages in y are; the data sections always correspond to the values established for the coordinated operation of the resonator, i.e., when there is no wave reflected from the resonator, and hence the feedback signal.

The amplitude and phase of a V.Ch. the floor in the resonator is controlled by changing the amplitude and phase of the wave incident from the pre-terminal cascade.

10 of the generator, the mode of operation of which can be arbitrary.

In the “classical stabilization devices of V. Ch. Iol with negative feedback signals. feedback is the signal

proportional to the level of V. C. the field in the resonator, which is equalized with the reference one, in the comparison device, an error signal is extracted, which is amplified by an amplifier located in the control ring,

The most guaranteed level is provided by V. Ch. The floor in the resonator and its stability. In this case, the stabilization accuracy is determined by the magnitude of the gain on the feedback ring / Cp. In such systems, always / С (. When the load of the resonator changes with an intense beam, as well as with external irritations, the resonator can be significantly upset. This leads to a change in the initial phase of the reverse signal

connection, which significantly reduces the region of stability of the device to self-exclusion: nd (reading. While maintaining the necessary stability region, the values of K are found to be high. That does not allow achieving the required accuracy

V. Ch. stabilization of the floor during the acceleration of intense beams. In addition, the GROMOUD1-: systems are complex and require fine paste building.

In the proposed device, a signal in the form of a reflected wave is allocated: :: at the nodes of communication with the resonator, n the amplifier covered by the feedback ring amplifies not the error signal, but the algebraic difference between the stable amplitude of the wave incident from the subarranged amplifier and the reflected a wave of errors. Therefore, the stabilization accuracy is not determined by the gain of the amplifier enclosed by the reverse link ring. The presence of an amplifier in the feedback ring is due only to the properties of the G-bridge, where some of the power of the reflected wave is lost, and the need to increase the device efficiency due to losses

power on the ballast load of the G-bridge of the compound coming from the pre-terminal cascade. This device is used to stabilize the amplitude and phase of the V.C. floor in the resonator only when the load is changed by the beam current and the resonator's own parameters. The error of stabilization in the stationary state in a given generator cross section is zero1 if the following amplitude

and phase relationships

; K - 1/2; FROM/

where K: is the modulus of the gain of the terminal cascade according to a nanr; t is the modulus of the attenuation coefficient of the attenuator colony.

G, G2 A

where G is the reflection coefficient from the n-th communication node with the resonator p 1,2,3,4.

2f (1 + 2p) l.

where p 0,1,2,3 ,. . . ;

2f is the total phase incursion in the communication lines of the control ring taking into account the phase shift in the final stage of the generator. In the device under consideration, the gain modulus but the feedback ring, taking into account the amplitude condition of the device tuning, / 1 - 1/2 t, is equal to the reflection coefficient from the resonator, i.e.; - / C (3 g / G /.

Since r 1, the device is resistant to self-excitation, regardless of the phase of the feedback signal up to T 1. But; L 1 corresponds to the short circuit or idling mode of the resonator and is not a working value. Therefore, the device is resistant to self-excitation in a wide range of resonator detunings and changes in its load, and it stabilizes the V.C. floor with a zero fiber provided that the amplitude and phase conditions are fulfilled with an accuracy dependent on the constant gain of the end stage, amplitude and the phase of the wave incident from the pre-final cascade, the ratio of the phases in the feedback ring and the quality of matching of the communication lines in the control ring.

The device provides high accuracy in stabilizing the amplitude and phase of a V.Ch. floor in the resonator while ensuring the stability of the V.H. generator parameters in the usual way of stabilizing the constant supply voltage of the generator stages.

Ferrite coaxial strip or waveguide phase shifters can be used as nonreciprocal phase shifters 4, while operating the device at higher frequencies, in particular at frequencies higher than 800 A1Hz, the directional coupler 3 together with nonreciprocal phase shifter 4 can be replaced with a three-shoulder circulator toors As a three-shoulder circulator, a ferrite waveguide diverter can be used, in particular, a phase circulator, Y, and a L-shaped circulator.

The feasibility of adjusting the feedback signal using a G-bridge connected to the arms of two directional couplers via variable length lines is based on the fact that modern linear accelerators B. A frequency generator is usually a multi-stage V. A frequency amplifier driven by a low-power driver. When stabilizing V. Ch. The field in the accelerator cavity by applying feedback on the reflection wave, the accuracy of the stabilization is not determined by the gain of the amplifier covered by the feedback.

P1start from this, to ease the tuning of the multi-stage V.Ch. amplifier, it is advisable to cover only the terminal stage of the amplifier with a feedback ring, and most of the reflected power should be added to the power from the preliminary cascade, and the attenuation coefficient of the reflected wave is low.

The accuracy of the stabilization strongly depends on the quality of the matching of the communication lines in the feedback ring and the arms of the I-bridges, since the mismatch leads to multiple reflections, which causes a distortion of the signal in the control ring. Therefore, when adjusting the device, it is necessary to adjust the attenuation coefficient of the reflected wave when the gain of the terminal stage changes, without violating the matching conditions of the shoulder of the directional coupler, in which the reflected wave power is released. It is rather difficult to make this adjustment by changing the coupling with the ballast load, at which the power of the wave reflected from the resonator is released at small attenuation factors, because the link between the feedback link and the ballast load is quite strong and the link adjustment leads to a significant change in shoulder load directional coupler, which leads to misalignment of the shoulder of the directional coupler, the deterioration of the accuracy of stabilization.

The attenuator, made in the form of a G-bridge, connected to the arms of two directional couplers through variable length lines, allows for the complete redistribution of the power reflected from the resonator wave between the two output arms, one of which includes a matched load, and the other is feedback circuits. In this case, the arms of the directional couplers with the waves reflected from the resonator always remain consistent, and the magnitude of the feedback signal can be controlled practically in the whole range of possible gain values of the amplifier covered by the feedback.

Claims (2)

1. V. Ch. Power supply system of the resonator is a Ly65 bit accelerator consisting of a generator, a G-bridge, a phase shifter, ballast loads and a resonator, characterized in that, in order to simplify the design and increase the accuracy of stabilization, the resonator is connected to two identical outputs of the V.C. generator cascade with the help of directional couplers with a power division factor of 1/2, the second output arms of each of which are also connected to the resonator through nonreciprocal phase shifters with a reciprocal phase shift The electrically-coupled waves from the resonator are connected to a smooth attenuator, while the attenuator itself is connected to the G-bridge cm of the slolse-power connected between the rare-end and terminal stages of the generator. 2. The system of claim 1, in connection with the fact that the smooth attenuator of the reflected wave is made in the form of a G-bridge, which is connected to the arms of the directional taps through the lines of variable length.