DE2008584A1 - Waveguide circulator - Google Patents

Description

20085 * 4

Dipl.-Phys. Leo Thul
Patent attorney
7 Stuttgart 30
Short street 8

R. F. Skedd - 2nd

INTERNATIONAL STANDARD ELECTRIC CORPORATION, NEW YORK

Waveguide circulator

The invention relates to a waveguide circulator, which has a cavity resonator with ferromagnetic material, on the at least three gates are directly coupled.

It is the object of the invention to provide such a waveguide circulator to improve that the frequency band utilization is significantly improved. The waveguide circulator, which has a cavity resonator having ferromagnetic material, to which at least three gates are directly coupled, is characterized according to the invention, that each gate has a waveguide length which gives a cutoff frequency above the resonance frequency of the cavity resonator, so that in the Resonance frequency in these waveguide lengths only evanescent waves can occur, and that these waveguide lengths an imaginary one Have reactance and are disconnected by a reactance

12.2.1970

. "9 _

VO / St

ι 009887/1260 ORIGINAL INSPECTED

200858V

R. F. Skedd - 2 - 2 -

which is the conjugate value of the imaginary wave impedance of the waveguide length. Since this circulator is constructed according to the damping type, the better utilization of the frequency band is achieved.

The invention is explained in more detail with reference to the drawings. Show it:

1 shows a waveguide circulator with three gates which are rectangular in cross section,

L Fig. 2. a transmission line that has a section

of a gate of the circulator according to FIG. 1 is identical for decaying H waves,

3 shows an equivalent circuit diagram for a section, FIG. 4 shows the power parameters of a circulator according to FIG. 1,

5 shows a waveguide circulator with three gates which are rectangular in cross section and their inner side walls are covered with ferromagnetic material,

6 shows the effective permeability as a function of the frequency in the case of transversely magnetized ferrites,

7 shows the cross section of a section, the side walls of which carry ferromagnetic strips, and

Fig. 8 shows the transmission loss as a function of the frequency for a waveguide section from whose Side walls are covered with ferrite strips, in the range of the cutoff frequency at different sizes DC field strength.

009887/1260

R. F. Skedd - 2 - 3 -

Fig. 1 shows a circulator with three ports and a central one Cavity resonator 1 containing ferromagnetic material 2. The ferromagnetic material is a direct current magnetic field H- exposed in the indicated direction to a circulation counterclockwise to get.

The three gates 4 of the circulator are identical in structure and mode of operation. Each gate consists of a section of a waveguide with a rectangular cross-section and a length of 2f and two capacitive adjustment screws 6 and 7 on the longitudinal center line of the upper, wider wall of the waveguide. The longitudinal distance between screws 6 and 7 is £ and each screw is at a distance of S / 2 from the center point of the total length of the waveguide. Each screw protrudes into the associated waveguide.

The rectangular cross-section, i.e. H. the height and the width, des Waveguide is designed so that at the operating frequency of the circulator, that is at the resonance frequency of the cavity resonator 1, the cut-off frequencies of all waveguide lengths 5 are above the operating frequency. At an operating frequency of 4 GHz, each has length 5 is 0.4 inches high and 0.9 inches wide.

Assume that energy is at the required operating frequency in Η-mode at the outer end of the left entrance gate 4, then all wave types decay in the waveguide length, since their cutoff frequency is above the operating frequency.

At frequencies below the cut-off frequency, a waveguide shows a Behavior that is characteristic of all filters built with individual elements in the restricted area. The wave resistance is real in the pass band

009887/1260

and imaginary in the restricted area.

In FIG. 2, a transmission line is shown, which corresponds to a section having the length idea input gate. 4 This section has a positive imaginary wave resistance JZ and a real propagation constant y. Evanescent Η-waves, the waveguide portion is a pure inductance. The equivalent circuit diagram for the line according to Fig. 2 is shown in Fig. 3, namely alsJf-member, the inductive reactance is a function of Z ₁ y, and f / are.

When a waveguide section is terminated with a capacitor C.

is the capacitive reactance X_ for inductive blind

resistance of the section is conjugated, then lossless occurs Energy transfer through the section. However, the energy transfer is frequency-dependent and the section behaves like a bandpass filter.

The cutoff frequencies f and f of the bandpass filter are: il f tanh 2. ^y l. t

^{h z} oi · «" Γ- ^c

2)

z _ol .2JT. c

The geometric center frequency f ■ rf,. f_ of the bandpass filter is then:

0098Ö7 / 1260

R. F. Skedd - 2 - 5 -

3)

2JT. Z ₀₁ . C.

The bandwidth is a function of y. In the ideal, lossless case, y becomes. £, ■ "*" cx => and consequently tanh y. £, - ^ coth y

and the bandwidth (f - f ) - ψ- ο.

1. Ci

The entrance gate behaves like a bandpass filter with two sections, where the required value of the capacitance for each section for conjugate adaptation to the inductance of the relevant Section can be adjusted by the capacitive screws 6 and 7 of the entrance gate.

For this reason, the entrance gate becomes the central cavity resonator and after a counter-clockwise rotation to the neighboring gate, a lossless energy transfer is carried out. In the same way, energy transfer without loss can also be achieved in the exit gate.

Fig. 4 shows the performance levels of a waveguide circulator Fig. 1, of the rectangular cross-section sections with inner dimensions 0.622 inches χ 0.40 inches, capacitive adjustment screws 8 B.A. and has a ferrite body 0.32 inches in diameter and 0.40 inches in length.

The functioning of the circulator is normal when used for energy transfer from one entrance gate to an adjacent exit gate only the direction used by the ferromagnetic Material supplied magnetic field is determined.

Exercising a circulator is also normal when a

- 6 - ORIGINAL BATHROOM

R. F. Skedd - 2 - 6 -

Gate is coupled with an antenna, a gate with a microwave radio transmitter and a gate with a microwave radio receiver.

The energy transfer outside the circulator can be via normal Propagation waveguides are carried out. At each transition there is a waveguide, which is operated below its cut-off frequency, and the larger-sized propagation waveguide another capacitive adjustment screw is provided for adjustment. Notwithstanding this, the circulator can also be used in a microwave system be coupled, which consists only of waveguides, the underneath the cut-off frequency.

Fig. 5 shows another embodiment of a three port circulator, in which the same elements have the same reference numerals as in the circulator according to FIG. 1. Each port here behaves like a band-pass filter made of waveguides which are operated below the cutoff frequency in which lossless energy transfer takes place at the operating frequency.

Each gate 4 is constructed as a waveguide, its height and width on the spread of the operating frequency are matched. Each gate contains loading strips 8 made of ferromagnetic material, e.g. B. * Ferrite or garnet. These stress strips are symmetrically attached to all side walls and have a direct current magnetic field H-, exposed.

It is certain that with transversely magnetized ferrite s in a rectangular waveguide (H - mode) the cutoff frequency by a DC magnetic field can be controlled. The cutoff frequency

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H.F.S.cead-2 -7- 200858A

can be made smaller and larger than a waveguide without these strips. This is a consequence of the fact that the effective permeability AjU of a ferrite can be changed from positive to negative values by a direct current magnetic field.

In Fig. 6 this dependency is shown, where UfL, the limit

c ^ o

frequency and U9 mean the gyromagnetic resonance for the infinitely small ferrite medium. With (Ug,> O the RF field is concentrated in the ferrite, while with (U.> C O the RF energy is excluded from the ferrite, so that the effective width of the waveguide is reduced. This effect is illustrated in FIG .

In each port of the circulator according to FIG. 5, due to the applied magnetic field, the waveguide lengths operated below the cutoff frequency. This condition is illustrated in Fig. 8, where it is shown that the cutoff frequency of each goal depends on the size of the DC magnetic field is dependent. The magnetic field can be changed. If a permanent magnet is used, then are the magnetic poles adjustable. When using an electromagnet, the current can be adjusted.

Each port of the circulator is by changing the magnetic field in the frequency can be adjusted. A strengthening of the magnetic field leads to an increase in the frequency and a weakening of the magnetic field leads to a reduction in the frequency.

Since the resonance frequency of the cavity resonator 1 can be changed by the magnetic field, the frequency of the circulator can be adjusted.

The circulator can also be built with waveguide gates, which have a square or round cross-section.

R. F. Skedd - 2 - 8 -

In the circulators of Figures 1 and 5, each port can have one, three, or more sections, all of which have a single alignment screw wear.

In both circulators described, the capacitive screws can also by other types of capacitive balancing means, such as z. B. adjustable capacitive diaphragms are replaced.

The circulators described have a much wider frequency band utilization than conventional (dispersive) waveguide circulators. This is because the gates operated below the cut-off frequency behave like cables made up of individual elements.

11 claims

3 sheets of drawings, 8 figs.

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Claims (11)

R. F. Skedd - 2 - 9 - Claims 1.) Waveguide circulator, which has a cavity resonator with ferromagnetic material, to which at least three gates are directly coupled, characterized in that each gate has a waveguide length which results in a cutoff frequency above the resonance frequency of the cavity so that in the Resonance frequency in these waveguide lengths only evanescent waves can occur, and that these waveguide lengths have an imaginary reactance and are terminated by a reactance which is the conjugate value of the imaginary wave resistance of the waveguide length. 2. Waveguide circulator according to claim 1, characterized in that the waveguide lengths have rectangular cross-section. 3. waveguide circulator according to claim 2, characterized in that at least one waveguide length carries ferromagnetic loading strips which are exposed to a transverse magnetic field, and that the effective dimensions of the waveguide length can be adjusted to the desired cutoff frequency. 4. waveguide circulator according to claim 3, characterized in that the waveguide length is covered symmetrically on both side walls with ferromagnetic material. - 10 - 009887/1260 R. F. Skedd -2 - 10 - 5. waveguide circulator according to claim 3 or 4, characterized in that ferrite is used as the ferromagnetic material. 6. waveguide circulator according to claim 3 or 4, characterized in that garnet is used as the ferromagnetic material. 7. waveguide circulator according to claim 3, 4, 5 or 6, characterized in fc, that the magnetic field by a permanent magnets is generated. 8. waveguide circulator according to claim 3, 4, 5 or 6, characterized in that the magnetic field by an electromagnet is generated. 9. waveguide circulator according to one or more of claims 3 to 8, characterized in that the cutoff frequency and the resonance frequency can be changed by changing the applied magnetic field. 10. Waveguide circulator according to one or more of the claims 2 to 9, characterized in that capacitive balancing screws are used as termination blind resistors. 11. Waveguide circulator according to claim 10, characterized in that each waveguide length consists of one or more sections, each of which carries a capacitive adjustment screw in a wide wall of the waveguide. 009887/1260