DE1275160B - Device for parametric excitation or amplification of electromagnetic waves - Google Patents

Description

Device for parametric excitation or amplification of electromagnetic Waves The invention relates to a device for parametric excitation or amplification of short and very short electromagnetic waves. Such a parametric vibration generator can be used, for example, as a parametron in computing machine technology Find application.

A parametron is an oscillatory structure in which at least one of the oscillating circuit parameters is controllably variable and in which the one to be excited Signal oscillation builds up as subharmonics of a pump oscillation that periodically and in the correct phase, energy to the signal oscillation to be fanned out again and again gives away. The parametron can, for example, be a conventional electromagnetic resonant circuit with concentrated reactive switching elements L and C, where either I. or but C is variable and can be controlled. The first case is with one ferromagnetic parametron, the second case with an electric parametron with varector diode.

These now common embodiments of parametrons with concentrated However, reactances L and C cannot be operated at the high operating frequencies, those in computing machine technology in the course of the general increase in the speed of operations Circuit arrangements have now become known which are used to achieve Use higher frequencies cavity resonators in which an oscillation is parametric is fanned. Such an arrangement is in the journal Proceedings of the IRE ", June 1958, p. 1301, as well as in the magazine" Fernmeldepraxis ", Vol. 37, No. 6, described. It consists of a cavity resonator that has three openings, two of which are equidistant from each end of the cavity resonator are arranged. The input and output signals become capacitive through these openings coupled in or out. The end face of the cavity resonator adjacent to the output contains the third opening provided for coupling the pump frequency. In the In the middle of the resonator there is a DC voltage insulated from the wall of the resonator body Varactor diode, the capacitance of which depends on the voltage or field strength. Will now a suitable input voltage matched to a resonance frequency of the resonator coupled in, it becomes twice as great as a result of the pump voltage, whose frequency is twice as high like that of the input voltage is amplified and can be taken from the output.

The disadvantage of this arrangement is that an adjustment of the working point of the varactor diode is not possible because it cannot be externally is accessible. However, an exact setting of the operating point is to be achieved a certain gain is necessary.

The object of the present invention was therefore to provide a parametron to create that does not have this disadvantage. This is done using a Line resonator, the effective length of which is equal to half the wavelength of the one to be excited Wave is and is connected to a pump and at least one signal line is achieved in that the resonator is at least partially covered with a material is filled with field strength-dependent dielectric constant that one of the outer Wall of electrically insulated inner conductor is present and that the outer Wall and inner conductor existing conductor system connected to a bias voltage source and that the signal line is in the middle and the pump line is one fifth of the resonator length is connected to the resonator away from the end of the resonator.

There is an advantageous further development of the subject matter of the invention in that the material filling the resonator has ferroelectric properties such as B. possesses barium titanate. The high dielectric constant makes this possible of the barium titanate particularly small spatial dimensions of the resonators. at according to a particularly advantageous further development and configuration of the device According to the invention, the line resonator is almost completely filled with barium titanate, the resonator expediently in the vicinity of the signal line connection remains free of barium titanate, because this reduces the damping. Of the Because of adaptation, it is advantageous to use a larger one for the inner conductor at this point To give diameter.

The invention is described below using an exemplary embodiment explained in more detail. F i g. 1 shows a metal closed on all sides Line resonator. The interior 1 between the outer walls 2 and the inner conductor 3 is filled with barium titanate. The inner conductor 3 is separated from the outer walls 2 electrically isolated by an insulating piece 4 and an insulating sleeve 5 and can be connected via line 6 to a bias voltage source, the other Pole is to be connected to the outer wall 2 of the resonator via the line 7. Of the The resonator thus forms a capacitor with barium titanate as the dielectric.

F i g. 2 a shows the stress distribution along the resonator at an oscillation with the pump frequency, which appears in the resonator as a standing wave can train. This pump wave has two amplitude maxima, so it is not the fundamental, but the first harmonic.

F i g. 2 b shows the voltage distribution along the resonator for a standing wave of the fundamental oscillation in the same resonator. This fundamental oscillation with half the pump frequency is used as a signal wave. Under suitable conditions, it can be fanned by the pump wave, ie it can be rocked to an ever greater amplitude. This parametric excitation of the signal wave occurs in detail as follows: The value of the dielectric constant of the barium titanate is changed most strongly in the voltage maxima of the pump wave. If one imagines the standing pump wave as a superposition of waves traveling back and forth, as is the case with the spatial voltage amplitude curve in FIG. 3 a shows, the voltage amplitude curve over time is obtained according to FIG. 3 b. For the sake of clarity, let this sine wave be replaced by the square wave according to FIG. 3 c; however, corresponding effects would also result in the case of the sine wave. The voltage has the one shown in FIG. 3 d shown the time course of the dielectric constant and thus the capacitance result. The capacitance is thus controlled back and forth between the value Co, which is preset by an electrical bias of the barium titanate, and the value Cl. Due to the periodic changes in the capacitance, the parametric oscillation according to FIG. 3 e fanned. At first it is still weak; its amplitude is denoted by U. The first capacity increase at the time To, has no effect on the voltage, because this is zero. The first reduction in capacitance at time T1 increases the voltage, however, because the inductance means that the charge on the capacitor cannot suddenly change. The increased voltage runs as if its amplitude had been UI. The second increase in capacity at time To 2 again has no effect on the voltage. The second reduction in capacitance at time T2 leads in turn to an increase in voltage, as if the amplitude were U2, etc. In this way, the parametrically excited signal wave oscillates to an ever greater amplitude, namely in the next half-cycle to the amplitude U3, etc. At the times T1, T2, T3, etc., the pump wave emits energy to the signal wave to be fanned out indirectly via the electrical energy content of the dielectric. This process is called parametric excitation.

When explaining the amplification of vibrations according to FIG. 3 e was assumed an already existing weak signal oscillation with the amplitude Uo. This oscillation can, for example, only occur before the pump voltage is switched on the coupled signal voltage. The oscillation can be in one of two order 180 ° different phase positions occur; in FIG. 3 e is one of them arbitrary accepted. The two phases are the binary information "0" and "1", with to which electronic calculating machines work, clearly assigned. Which of the two Phase positions are present, can be decided particularly easily by comparison with a reference oscillation of the same frequency. Therefore, in calculating machines that use Parametrons work, one of these designated as the reference parametron and his Signal oscillation is assigned the binary information »0«.

F i g. 4 shows an embodiment of a parametron according to the invention with connections 6/7 for the electrical bias voltage source, 8/9 for the signal line and 10/11 for the pump line. There is only one in this particular example Signal line provided, as is usual with parametrons, because namely the signals be coupled in or out at different times. The signal and pump lines are capacitive in the area of the maximum electric field strength of the signal or pump wave coupled. The purpose of mutual decoupling of the signal and pump lines is the signal line is connected in the middle of the resonator, because there (according to Fig. 2b) the maximum of the signal voltage and at the same time (according to FIG. 2 a) a minimum of the pump voltage occurs. In contrast, the center of the resonator is unsuitable for coupling the pump oscillation, rather, the second and fourth fifth of the resonator are suitable for this purpose.

The areas of the Ferroelectrics probably cause a damping of the system, because at this point the signal voltage reaches its maximum, but contribute little to the parametric Excitation because the pump voltage has a minimum at this point. It is therefore it is advisable to fill the resonator only partially with barium titanate and in particular to leave the environment 12 of the signal coupling point free in order to thereby to increase the circular quality of the resonator. By increasing the cross-section of the inner conductor accordingly 13 At this point, jumps in the wave resistance at the interface can be seen avoid the dielectric.

The invention was based on a specific embodiment described. It goes without saying that there are many modifications and further developments of the subject matter of the invention is easily possible. In particular, be on the possibility pointed out, the device also for the parametric amplification of signal oscillations to use, in that signal inputs and outputs are separated from each other, so that at the same time the signal to be amplified is coupled in and the amplified signal is coupled out can be.

Claims (3)

Claims: 1. Device for parametric excitation or amplification electromagnetic waves using a line resonator whose effective Length is equal to half the wavelength of the wave to be excited and the and at least one signal line connected is characterized by that the resonator is at least partially made of a material with a field strength-dependent Dielectric constant is filled that one of the outer wall electrically insulated inner conductor is present and that the outer wall and inner conductor existing conductor system is connected to a bias voltage source and that the Signal line in the middle and the pump line one fifth of the resonator length from Resonator end is remotely connected to the resonator. 2. Device according to claim 1, characterized in that the material filling the resonator is ferroelectric Properties such as B. possesses barium titanate. 3. Device according to claim 2, characterized characterized in that the resonator is at the level of the signal line connection of ferromagnetic material is free and that there the inner conductor a larger Has diameter. Publications considered: German Auslegeschrift No. 1099 007; "The natural sciences", H.10 / 1960, pp.220, 221; "Telecommunication Practice", from 15.3.1960, p.218 to 220; "Proceedings of the IRE," June 1958, p. 1301; “IBM Technical Disclosure Bulletin, December 1960, pp. 33-35.