DE1110704B - Cavity resonator tuned by rotary movement, especially for directly readable frequency meters - Google Patents

Description

When designing broadband frequency meters for maximum frequencies - e.g. B. over 3000MHz - prepares the simultaneous assertion of two important aspects great Trouble. The first is to ensure a relatively quick service and an immediate one Reading, the second ensuring contactless voting without the use of Line sections of different impedances or contactless »Sa short-circuit pistons.

The fast operation and the immediate read-off mean that there is no need to use Feed mechanisms with micrometer drive advance, the penetration of a not too wide Frequency range of the repeated rotation of the tuning element with screw drive requires. the Solution by means of contactless voting is essential because of the transition resistance the sliding contacts and the relatively large development of force required to operate them is, the reproducible setting accuracy of the resonator - d. H. the possibility of repeating the Measurements from the same measurement result - very unfavorably affected. The same applies in the case of application of contactless "S" short-circuit pistons, which create a high-frequency short-circuit in a resonator plane without contact between the piston and the Enable resonator wall; there, in turn, the necessity of a straight movement arises of the tuning element, which, however, requires the feed mechanisms assessed above.

Such feed mechanisms of tedious operation can hardly be used, particularly in the case of operational high frequency meters. The use of such a drive cannot, however, _{be dispensed with in the usual tuning of a cavity resonator of the type TM 100} , whereby a conductor representing a concentrated capacitive load is inserted into the cavity, the advance of which of a few millimeters already results in the tuning of the entire frequency range; there is still the need for sliding contacts and terminating members, the production of which causes great technical difficulties.

The same problems are also present in the tuning of coaxial cavity resonators, in which the tuning takes place by means of a short-circuit piston moved in the coaxial line. In the case of the _{cavities oscillating in the TE 101} vibration mode, the length of the cavity is more coordinated by means of a conductive rotary movement which can be moved from the outside along the cavity

Cavity resonator, in particular

for directly readable frequency meters

Applicant:

Electronicsus Merökeszulekek Gyära,
Budapest

Representative: Dipl.-Ing. W. Meissner,

Berlin-Grunewald, Herbertstr. 22

and Dipl.-Ing. H. Tischer, Munich 2, patent attorneys

Claimed priority:
Hungary from July 8, 1959

Mihäly Wodicska, fird (Hungary),
has been named as the inventor

Disc changed, of course also here using a micrometer drive. However, cavity resonators of this type have a very considerable volume and are particularly suitable for precision measurements. The invention relates to such a design of a _{cavity resonator, preferably in the mode of vibration TM 100} - or the other widespread designation corresponding to E ₀ - vibrating cavity resonator, which a frequency range of at least 1: 2 comprehensive tuning directly by rotary movement without the use of sliding contacts or these corresponding terminating elements with immediate, quick readability is guaranteed in such a way that the relationship between the angle of rotation and the resulting change in frequency remains approximately linear.

The solution according to the invention achieves this goal by such a design of the oscillation space of the cavity resonator, the height dimension of the resonator in the middle of the room by - preferably on both sides - increases The width of the room, on the other hand, is locally enlarged by a wall bulge, whereby one moving on a circular arc path between the center of the cavity and the wall, according to its size

109 647/365

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come close to the useful height of the cavity - Fig. 6 shows three frequency range or frequency

the metallic tuning body shows the electromagnetic characteristic curves when using the

table force space of the resonator in decisive known solution (I), in the case of further development

Way changed in such a way that a jump-free environment of this known solution (II) and according to the invention

formation of the type of oscillation occurs, whereby the formation (III).

change in frequency of the cavity in a linear from Fig. la, Ib and 2a, 2b and the characteristic curves I.

Relation to the angle of rotation ψ of the tuning and II of Fig. 6, it can be seen that for the Fre-

body and the frequency penetration of the resonance range of a cavity resonator according to the

nators has a value number of about 1: 2.2. known solution — with non-linear frequency response—

There is a known solution for the tuning io only a ratio of about 1: 1.2 characterizes cavity resonators after which a downturn is; this ratio value cannot even be rotated around an axis in a geometrically regular cavity formed by further development of the known solution. thought to be increased by a value of 1: 1.5. This solution calls, however, because of the design of the additional, the course of the characteristic cavity and the dimensioning of the tuning body 15 line is just in an unfavorable sense,
only a limited, quantitative and by no means a qualitative change in the electrical space resonator, which is shown in FIG. 3 and which is essential to the invention, contains geomemagnetic force space of the resonator in two dimensions. The Irish irregular shapes.
Ratio of the frequency change of the room First: The cavity U is enclosed by a non-rectilinear wall F, which is not designed in this way; also contains the bulge KiI , in which the full height of the room, in the case of a further development of this solution through an axis T arranged between the approximate center of the room K and the elevation of the tuning body up to the approximate wall F , the resonator only reaches metallic tuning body Ft in its Wall stones frequency penetration of about 1: 1.5. That is in part.

indicates in frequency values that a cavity resonator The second geometric irregularity of the

of 3500 MHz minimum frequency only a maximum training of the cavity resonator is more detailed

Frequency of about 3900 MHz or 5200 MHz can be seen from FIGS. 4 and 5: Preferably both

ranges, with the relationship between the end faces of the resonator in their

Angle of rotation ψ of the tuning body and the Fre- 30 center, where the metal tuning body Ft in its

The frequency change of the resonator is in no way appropriate as a linear starting position, an increase Kt each

can be considered. Today's requirements affect the useful height of the cavity resonator

but only such a cavity can sufficiently diminish; this structure follows in its curved

perform, which has a frequency range of 1: 2, preferred shape of the movement path of the tuning body Ft,

wise 1: 2.2, with a linear frequency response, i. H. 35 but increases in height in the direction of the wall

from Z. B. 3500 MHz up to 7500 MHz as constantly as possible. So the on a semicircular arc

is linearly tunable. The solution according to the invention consists of web-moving metallic tuning bodies Ft

and a possible embodiment of this idea a resonator chamber of reduced dimensions in

becomes a room full height using the following description and drawing, but then he leaves with

explanations: 40 its predominant volume the vibration

In the cavity resonators the mode of oscillation space of the resonator and takes in the wall

TMj ₀₀ (E ₀ ) there is a bulge Kü position in the middle of the resonator.

Maximum electric field strength E, in the wall The preferably cylindrical metallic seam, on the other hand, a maximum magnetic field tuning body takes up the majority of the load in its central position (low strength M. Due to a concentrated capacitive higher frequencies), this weight room arrangement is dependent on Reduced height of the resonator chamber in claim and consistency of the formal design of the resonator - in this position the electrical force chamber, the dimensioning of the tuning body and space in the center line of the resonator are centered. Changed in its trajectory. Wall position (higher frequencies) is

Fig. 1 a, 1 b illustrate the power space arrangement 50 but the metallic tuning body in the well of a known, geometrically regular right bulge Kü, so predominantly outside of the angular cavity resonator in the middle position of the electrical and inside the magnetic a cylindrical tuning body from an angle. Force space of the resonator, the magnetic dimensions of which, which takes up only a fraction of the resonator force space arrangement in comparison with the height of the electrical space; 55 Irish influenced in the opposite sense. the

FIGS. 2 a, 2 b show the same arrangement in the wan characteristic curve III of FIG. 6 shows its essence

close position of the tuning body; after reshaped electromagnetic space des

Fig. 3 shows the inventive geometrically un-resonator, with regard to its frequency range and regular configuration of a cavity resonator frequency response, wherein for the first a ratio in cross-section with reference to the position 60 number of about 1: 2.2 and for the second a wide tuning body approximately is characteristic in the middle of the room and in going linearity.
Wall proximity; About the basic mode of action of the invented

4 shows the electromagnetic force space solution, it should also be noted that as long as

arrangement of an inventive designed Reso- the known solution only a perturbation line

sets the nator in motion in the middle position of the ventilating body according to the invention in the resonator space,

measured tuning body; the invention in the wall position of the metallic

Fig. 5 shows the weight room arrangement in the wall see tuning body (higher frequencies), meanwhile

close position of the tuning body; he see almost the full useful resonator height in

Claim, the design of the power room arrangement of a pot resonator, in the middle position of the tuning body (lower frequencies) that of one on both sides with termination capacities limited coaxial resonator achieved. The solution according to the invention differs qualitatively the electromagnetic force space image in the two extreme positions of the metallic tuning body; in the wall position there is a common, divided electrical and magnetic force space, characteristic for the pot resonators, but in the middle position of the tuning body it is in the middle of the room from the termination capacitances created between the tuned resonator and the tuning body a concentrated electric, in contrast to the wall near a cylinder-symmetrical one arranged magnetic force space, while the inventive solution a jump-free resonator mode transition and ensures a linear oscillation frequency response. The frequency response can be determined by the appropriate design of the Hold closing capacities in hand.

For the fundamental redesign of the power space order of the cavity resonator according to the invention Solution is also characteristic of the fact that the natural frequency of a per se known cavity resonator with the help of the so-called perturbation theory with good approximation can be calculated, with the complete immutability of the weight room arrangement for such a calculation is an essential requirement. In a cavity resonator according to the invention, however this type of calculation leads to completely wrong formal results, and the natural frequency of an inventive Cavity is only due to a different method, i. H. the doctrine of radial waveguides, ascertain.

The solution according to the invention enables in this way the formation of such a cavity resonator, which by the design of the cavity and the dimensioning of the tuning body a substantial redesign of the resonator force space and thereby a significant expansion of the frequency range guaranteed with as linear a frequency response as possible. This makes it possible to use a broadband Cavity resonator - preferably as a frequency meter for maximum frequencies - by To vote rotary movement so that by means of the rotary movement of the tuning body the extent of Frequency change can also be read immediately - in a manner known per se - without rectilinear movement of the tuning body, without sliding contacts or these corresponding terminating elements.

Claims (2)

PATENT CLAIMS: 1. Cavity resonator tuned by rotary movement, in particular for directly readable frequency meters, in which a metallic tuning body moved on a semicircular arc path, the electromagnetic force space arrangement and at the same time the mode of vibration of the cavity resonator for the expansion of the frequency range, furthermore for the linearization of the relationship between the angle of rotation y: of the tuning body and the change in the natural frequency of the cavity resonator largely redesigned, characterized by a geometrically irregularly formed resonator chamber, the height dimension of which in the initial position of the metallic tuning body in the middle of the room is reduced by preferably an increase in each of the two end surfaces of the resonator, and its width dimension in the wall position of the metallic tuning body by a wall bulge serving to partially accommodate the metallic tuning body is locally enlarged, while the height dimension of the metallic tuning body comes close to the useful height of the cavity resonator. 2. Device according to claim 1, characterized by an arcuate end surface elevation in the middle of the resonator, the height of which is in the direction of movement of the metallic swiveled out of the central position Tuning body reduced evenly. 1 sheet of drawings © 109 647/365 7.61