DE4204299A1 - Non-reciprocal waveguide coupler using magnetostatic surface waves - whose direction of propagation on epitaxial garnet film is at right angles to fundamental magnetic field - Google Patents

Abstract

An input port (1) and a bidirectional port (2) are connected by waveguides of different impedance to a transmitter (S) and an antenna (A) respectively. A third waveguide leads from an output port (3) to a receiver (E). The surface magnetostatic waves are propagated, on a YIG epitaxial film (16) over a pref. gallium-gadolinium granulate substrate, between an input transformer (6) and a bidirectional port transformer with a prim. part (10), a compensating part (11) and a half-wavelength contact bridge (12) connected to the output port. USE/ADVANTAGE - In e.g. radio direction-finding and radar, medical NMR tomography, device can be used as n-port directional coupler or circulator at frequencies of at least a few GHz.

Description

The invention relates to a non-reciprocal coupler with a magnetic film that has a feed gate and min at least one bidirectional gate and one decoupling gate and is provided with strip conductors for microwaves. This streak fenleiter are in a static magnetic basic field ordered, the ge parallel to the flat sides of the magnetic film is aimed.

Coupler with the function of an electronic switch, which as Directional couplers are known to find application in measurement technology for the separate measurement of a and returning wave of a line or a measurement object. Such transmission and reception switches are, for example, ver applies to a frequency range up to about 100 MHz in core spin tomograph for producing sectional images of a human body. In the process, transmission signals are used for excitation the nuclear spins from a transmitter through an entrance gate of the Directional coupler and a bidirectional gate an antenna leads. The nuclear spin signals are from the same antenna via the bi-directional gate and a decoupling gate to an emp catcher fed. Such directional couplers are reciprocal components elements and can for example consist of coaxial conductors or also consist of planar lines.

With a non-reciprocal directional coupler, the decoupling can gate also designed as a two-way gate and with the Infeed gate are coupled, then a circula is created gate. These are passive, non-reciprocal multi-gates with at least three gates, in which the one fed in at a feed gate Performance is only offered at another gate while  all other gates are largely decoupled. The nonrezi percent is made possible by a magnetic film from a gyrotropic medium, a so-called microwave ferrite, the under the influence of a static magnetic field gyrotropes Assumes behavior in a designated frequency range. These Ferrites are magnetostatically soft and dielectric loss poor materials, for example polycrystalline grenades and Spinels. The most common use of these circulators is in the decoupling of signal paths. Reflected performance or Foreign signals should also be kept away from active stages by the returning power in the two-way gate not to the feed gate, but to the following two directional gate and is absorbed there. The Circulator then acts as a one-way line (Meinke "paperback der Hochfrequenztechnik ", Vol. 1 (1986), 4th edition, pages L27 up to L36).

In a known embodiment of a miniature circulator a dielectric substrate is provided with a metal film, on which a magnetic film is arranged. The gates consist of frame-shaped strip conductors nested inside each other are and are arranged in a basic magnetic field that is directed perpendicular to the surface of the magnetic film. This Circulator has a narrow bandwidth and is proportionate moderately complicated structure (Proceedings of the IEEE, Vol. 76, No. 2, Feb. 1988, pages 188 to 200).

There are also components for signal transmission in the frequency range of at least a few GHz with magnetostatic surface waves MSW (magnetostatic waves) are known, which these microwaves propagate in a forward direction on a magnetic film consisting of a YIG film (yttrium iron garnet). Such magnetostatic surface waves have relatively low propagation losses. The center frequency of these surface waves is controlled by a basic magnetic field that runs parallel to the flat sides of the magnetic film. The magnetic film is designed as a microstrip with a width of, for example, approximately 25 μm and an impedance of approximately 50 ohms, and arranged on a substrate with a high dielectric constant. The basic magnetic field H _o runs in the plane of the magnetic film and perpendicular to the direction of transmission of the surface waves MSW (Proceedings IEEE, Vol. 76, No. 2, Feb. 1988, pages 159 to 170).

The invention is based on the object, a non-re ziproken directional coupler for microwaves specify that in a is constructed in a simple manner and by slight change in the Ge design as N-gate preferred directional distributor or as a circulator in the frequency range of at least a few GHz used for example for radar systems and directional radio systems can be.

This object is achieved with the characterizing features of claim 1. Feed gate and two directional gate are each provided with a converter, which consist of strip conductors. The converter of the bi-directional gate lies within the aperture of the converter for the feed gate and in the forward direction of the magnetostatic surface waves and contains a primary part and a compensation part each made of a strip line, which are arranged parallel to one another and connected to one another via a contact bridge and the coupling gate . The decoupling gate is connected to the primary part and the compensation part. The distance of the primary part from the compensation part is at least approximately half of a reference frequency λ ₀ in the frequency band of the surface waves.

Further particularly advantageous refinements of the directional coupler lers result from the subclaims.  

By designing the decoupling gate as two-way Gate and combination with the feed gate are available in one way a circulator.

To further explain the invention, reference is made to the drawing, in which FIG. 1 a directional coupler according to the prior art is schematically illustrated as a block diagram. Fig. 2 shows a simple embodiment of a circuit of a directional coupler according to the invention. In Fig. 3, a particularly advantageous further embodiment of the directional coupler is shown in Fig. 2 with a decreasing part of the A speisungstor associated converter and a Torteil for the receiver. In Figs. 4 and 5 each show a particular embodiment of the converter illustrated veran for Zweirichtungstor. A phase correction network for the converter of the two-way gate is shown in FIG. 6. An embodiment of the directional coupler with an additional bidirectional gate is illustrated in FIG. 7. Fig. 8 shows an embodiment of the directional coupler with several bidirectional gates, some of which are provided with a separation structure. FIG. 9 shows a more detailed illustration of these separation structures . A further embodiment of the directional coupler according to the invention as a circulator is shown in FIG. 10.

In a known embodiment of a directional coupler according to FIG. 1, a signal of a transmitter S is to be fed via an amplifier (not specified in more detail) and a feed gate 1 of a directional coupler R and a bidirectional gate 2, for example to an antenna A of an MRI scanner. With these signals, an imaging volume of a patient (not shown in the figure) is irradiated with a sequence of high-frequency pulses in the frequency range up to approximately 100 MHz. With the same antenna A, the nuclear magnetic resonance signals emitted by the examination object are detected and transmitted to the decoupling gate 3 via the bidirectional gate 2 and fed to a receiver E via an amplifier (not shown in the figure). The coupling gate 3 is isolated for the signals transmitted from the transmitter S to the antenna A; the feed gate 1 is isolated for the signals transmitted from the antenna A to the receiver E.

In the embodiment of a directional coupler according to the invention for higher frequencies, in particular in the GHz range, according to FIG. 2, a feed gate 1 is connected to a transmitter S via a waveguide with impedance Z ₁ , which can preferably be a waveguide. Furthermore, a bidirectional gate 2 is also connected via a waveguide with the impedance Z ₂ , which may preferably also be a waveguide, to an antenna A. At a decoupling gate 3 , a receiver E is connected via a waveguide with the impedance Z ₃ . The feed gate 1 is connected to a converter 6 , which consists of a strip conductor for magnetostatic surface waves MSW. This stripline can consist of metal, in particular gold or copper, such as aluminum. Within the dashed interpret th aperture of the surface waves, and in the forward direction 16 of the surface waves, a converter 7 for the two richtungstor 2 arranged, which comprises a primary part 10 and a Kom pensationsteil 11 λ at a distance _0/2 parallel to each other arranged and a contact bridge 12 are interconnected. λ ₀ is a reference frequency in the pass band of the surface waves. The free end of the primary part 10 is connected to the bidirectional gate 2 and the free end of the compensation part 11 is connected to ground. The contact bridge 12 is electrically conductively connected to the decoupling gate 3 . The converters 6 and 7 with their connecting conductors to the gates 1 , 2 and 3 are at least indirectly arranged on a magnetic film 16 which consists of a garnet, in particular a YIG film (yttrium iron garnet), and which is epitaxially separated a base body, which can preferably consist of a gallium-gadolinium granulate GGG. This directional coupler is generally arranged in a metallic housing, which also serves as a ground plane for the converter and the waveguide. The strip conductors of the converters 6 and 7 are arranged in a static magnetic basic field H _o , which is directed parallel to the strip conductors of the converters 6 and 7 and perpendicular to the forward direction 14 of the surface waves of the converter 6 .

This surface wave induces a voltage in the two strip conductors of the primary part 10 and the compensation part 11 , the currents I ₁₀ and I _{11 of} which are each indicated by an arrow in the figure. The characteristic impedance Z ₃ = Z _2/2 and the length l of the strip conductors of the converter 7 and their width and their distance are chosen so that these currents I ₁₀ and I _{11 are of} equal size. Their directions are chosen such that no signal is transmitted to the receiver E at the coupling gate 3 . If a signal is fed from the antenna A via the bidirectional gate 2, a surface wave is emitted from the primary part 10 , which induces a voltage in the compensation part 11 , the current of which is rectified with the current I ₁₀ . These currents thus add up in the contact bridge 12 , so that a corresponding signal via the coupling gate 3 to the receiver E is transmitted. For this upper surface wave, the converter 6 lies in the insulation direction 17 , so that no signal is received from the converter 6 and thus no signal can be transmitted via the feed gate 1 .

The size of the currents I ₁₀ and I ₁₁ in the primary part 10 and in the compensation part 11 is essentially determined by the line impedance Z ₂ between the bidirectional gate 2 and the antenna A and by the line impedance Z ₃ between the decoupling gate 3 and the receiver E. In In a preferred embodiment of the directional coupler, the impedance Z ₃ = Z _{2/2 is} selected.

For the impedance matching, in the embodiment of a directional coupler according to FIG. 3, the converter 7 can preferably also be provided with an acceptance part 20 and the receiver E can be connected via a gate part 22 . The narrowing part 20 is connected via the contact bridge 12 to the converter 7 and ent holds unspecified strip conductors that λ at a distance are _0/2 from each other and whose lengths and widths are chosen so that the impedance Z ₂₀ point between the intersection of Contact bridge 12 and the unspecified ground connection is equal to Z _2/2 , where Z _{2 is} the impedance of the connecting cable at the two-way gate 2 . This gives an impedance Z ₂₀ , which is equal to half the amount of the impedance Z ₇ . If a signal is transmitted from the antenna A to the converter 7 , a surface wave is emitted from the transmission conductors 21 of the receiving part 20 , in the transmission direction of which the reception conductor 23 of the gate part 22 is arranged. In this receiving conductor 23 , a voltage U _{E is} induced, which delivers a corresponding signal via the decoupling gate 3 to the receiver E. The length l of the strip line of the converter 7 is equal to the length l of the transmission line 21 of the receiving part 20 . The aperture of the converter 7 is thus the same as the aperture of the receiving part 20 .

The output impedance of the converter at the decoupling gate 3 is made equal to the connecting cable impedance by the geometry of the gate part 22 (usually Z ₂ ). So that the currents I ₁₀ and I ₁₁ remain in the required phase position even with a slight deviation of the surface waves from an assumed mean value λ ₀ , the converter 7 between the bidirectional gate 2 and the coupling gate 3 can be listed as a wavelength filter according to FIG. 4. For this purpose, a larger number of primary parts 10 and compensation parts 11 are preferably arranged on the surface of the magnetic film 16 in the form of a comb structure. The alternately arranged side by side primary parts 10 and Kompensa tion parts 11 are connected to the decoupling gate 3 via a common contact bridge. The free ends of the primary parts 10 are connected via a common bridge with the two-directional gate 2 and the free ends of the compensation parts 11 are connected to ground via an impedance Z ' ₂ .

Through the wavelength filter it is achieved that the wavelength λ ₀ can only deviate in a limited range and you thus get a narrow wavelength window. With the terminating impedance Z ' ₂ , a phase correction can then be performed.

In the embodiment of a wavelength filter according to FIG. 5, the converter 7 is composed of meandering primary parts 10 and compensation parts 11 , each of which consists of a strip line. In the illustrated embodiment, the two primary parts 10 between the bidirectional gate 2 and the coupling gate 3 and the two compensation parts 11 between the coupling gate 3 and the ground connection are net angeord. The two basic patterns with serial and parallel stripline grids can be combined as desired to achieve a desired K filter characteristic (K = 2 π / λ).

In the embodiment of a converter 7 according to FIG. 6 with the primary part 10 and the compensation part 11 , which is arranged between the bidirectional gate 2 and the coupling gate 3 , the terminating impedance Z ' ₂ consists of a phase correction network 24 , which contains an LC combination. An inductor 26 is formed from a strip conductor, which can preferably be designed as a meander and the legs of which run transversely to the basic field H _o . A capacitance 28 is formed by a plate capacitor, the upper plate of which is indicated in the figure and the lower plate of which can be arranged separately on the magnetic film by a dielectric intermediate layer, not shown in the figure. The phase position of the currents in the primary part 10 and the compensation part 11 can be fixed by the size of the inductance 26 and the capacitance 28 .

In the embodiment according to FIG. 7, a 4-gate directional coupler is provided which, in addition to the feed gate 1 , the two-way gate 2 and the decoupling gate 3 , also contains an additional two-way gate 4 . Within the aperture of the converter 6 , the converter 7 , to which a removal part 20 is assigned. A converter 35 of the bidirectional gate 4 lies within the aperture of this acceptance part 20 . The converter 35 is also assigned a removal part 32 , in the aperture of which the gate part 22 of the coupling gate 3 is arranged. In this embodiment, 4 signals can also be fed in or out via the bidirectional gate.

In the embodiment of the directional coupler according to FIG. 8, a further bidirectional gate 5 is provided, which is provided with a converter, not shown, to which a removal part 33 is assigned, in the aperture of which the gate part 22 of the coupling gate 3 is arranged. To shield the Abnah meteile 32 and 33 , a separation structure 36 and 37 are provided in this embodiment, which derive a portion of the surface waves not absorbed by the compensation part of the converter 7 or 35 . These derived parts NEN can not be noticed on the removal parts 32 and 33 disturbing. The separation structures 36 and 37 are inclined at a predetermined angle with respect to the basic field H _o , which parts in the direction of the strip line of the converter and removal and the gate part 22 extends.

In the embodiment, a separation structure 36 of Fig. 9 are therefore provided a plurality of reflectors 38, the strip conductors unspecified each of individual best hen, the mutual distance of λ _1/2 is. The strip head of the reflector 38 are arranged one behind the other with an inclination angle ϕ. The strip conductors of the further reflectors 39 and 40 are arranged parallel to one another in the manner of a Bragg reflector in the direction of the basic magnetic field H _o . The spacing λ _1/2 of the individual stripline ter of these reflectors 39 and 40 is selected so that constructive interference occurs for the derived at the reflectors 38 to 40 surface acoustic wave so that the waves between the reflectors 39 and 40 are reflected back and forth.

In the special embodiment according to FIG. 10, a directional coupler with at least two bidirectional gates 2 and 4 is provided, each of which is assigned a converter 7 or 35 and a receiving part 20 or 32 . This directional coupler is now designed to the circulator that the previous decoupling gate 3 is combined with the previous feed gate 1 to a bi-directional gate, the converter 8 is assigned a receiving part 34 , in the aperture of which the converter 7 of the bi-directional gate 2 is arranged. In this circular gate, the energy supplied to one of the gates is passed on to the next gate, while the other gates are insulated.

Claims (18)

1. Non-reciprocal coupler with a magnetic film, which is provided with a feed gate and at least one bidirectional gate and a decoupling gate and with strip conductors for micro waves, which are arranged in a static basic magnetic field, which is directed parallel to the flat sides of the magnetic film, thereby characterized in that magnetostatic surface waves MSW are provided for the transmission of energy , the transmission direction ( 14 ) of which runs perpendicular to the basic field H _o ( FIG. 2). 2. Coupler according to claim 1, characterized by the following features:

• a) The feed gate ( 1 ) is assigned a converter for transmitting microwaves, which consists of at least one strip line,
• b) the bidirectional gate ( 2 ) is assigned a converter for transmitting and receiving microwaves, which contains a primary part ( 10 ) and a compensation part ( 11 ) each consisting of a strip line, which are arranged parallel to one another and via a contact bridge ( 12 ) are connected to each other and are arranged for sending to within the apparatus and in the forward direction ( 14 ) of the converter ( 6 ),
• c) the decoupling gate ( 3 ) for reception is connected to the contact bridge ( 12 ) of the converter ( 7 ) for transmission and reception.

3. Coupler according to claim 2, characterized in that the distance of the primary part ( 10 ) from the compensation part ( 11 ) of the converter ( 7 ) for transmission and reception is at least approximately equal to half a reference frequency λ ₀ in the pass band of the surface waves MSW. 4. Coupler according to claim 3 is characterized, terized in that the distance between the strip conductor of the compensation and primary part λ _0/2 + n λ ₀ is wherein n is an integer. 5. Coupler according to one of claims 1 to 4, characterized in that a receiving part ( 20 ) with parallel strip conductors is connected to the converter ( 7 ) for reception, the impedance of which is at least approximately equal to half the impedance of a connecting cable at the two-way gate ( 2 ) and that the take-off part ( 20 ) is assigned a gate part ( 22 ) which contains strip conductors which are arranged parallel to the strip conductors of the take-off part ( 20 ) and in the aperture of the take-off part ( 20 ) and whose impedance is equal to the impedance of a cable at the decoupling gate ( 3 ) is selected ( Fig. 3). 6. Coupler according to one of claims 1 to 4, characterized in that at least the converter ( 6 ) for transmitting consists of several strip conductors, which are arranged at least partially parallel to one another and whose line connections are such that the strip conductors form a grid. 7. Coupler according to claim 7, characterized in that the acceptance part ( 20 ) and / or the gate part ( 22 ) consists of a combination of K-filter networks be. 8. Coupler according to claim 7, characterized in that the converter ( 7 ) is designed for transmission and reception as a wavelength filter, wherein

• a) individual pairs of strip conductors are pushed against one another by a distance λ ₀ in the forward direction of the surface waves,
• b) the contact bridges ( 12 ) of the individual pairs are connected to one another,
• c) the ends of the primary parts ( 10 ) facing away from the contact bridges ( 12 ) are metallically coupled,
• d) the ends of the compensation parts ( 11 ) facing away from the contact bridges ( 12 ) are metallically coupled ( FIG. 4).

9. Coupler according to claim 8, characterized in that the strip conductors of the converter ( 7 ) form a series connection of networks ( Fig. 5). 10. Coupler according to claim 2, characterized in that on the contact bridge ( 12 ) facing away from the compensation part ( 11 ) of the converter ( 7 ) for sending and receiving a phase correction network ( 24 ) is seen before ( Fig. 6) . 11. Coupler according to claim 10, characterized in that the phase correction network ( 24 ) contains a parallel connection of an inductor ( 26 ) with a capacitance ( 28 ) consisting of strip conductors which run perpendicular to the basic field H _o , and that the inductance ( 26 ) from narrow strip conductors and the capacitance ( 28 ) consists of a flat strip conductor, which forms a capacitor with a ground surface ( Fig. 6). 12. Coupler according to claim 2, characterized by an additional bidirectional gate ( 4 ) ( Fig. 7). 13. Coupler according to claim 12, characterized in that for an additional bidirectional gate ( 4 ) a converter ( 35 ) for transmitting and receiving is provided, which in the aperture of the receiving part ( 20 ) for the two-directional gate ( 2 ) and in the forward direction the surface waves is arranged and is connected to an additional removal part ( 32 ), in the aperture and in the direction of passage, the gate part ( 22 ) for the decoupling gate ( 3 ) is arranged ( Fig. 7). 14. Coupler according to claim 13, characterized by a plurality of bidirectional gates ( 4 , 5 ), each of which is connected to a converter ( 35 ), each of which is assigned an acceptance part ( 32 or 33 ). 15. Coupler according to claim 13 or 14, characterized in that between the converters ( 7 , 35 ) of the bidirectional gates ( 2 or 4 ) and each arranged in the passage direction receiving part ( 32 or 33 ) of the following bidirectional gate ( 4 or 5 ) a separation structure ( 36 , 37 ) is provided ( Fig. 8). 16. Coupler according to claim 15, characterized in that the separation structures ( 36 , 37 ) min least one to the forward direction oblique deflector ( 38 ) and at least one in the direction of the basic field H _o duri fenden further deflector ( 39 ) containing an absorber tion channel ( 40 ) form. 17. A coupler according to claim 16, characterized in that several strip conductors that λ at a distance are _half relative to one another, in each case a deflector (38, 39, 40) form, which are arranged such that the Oberflä chenwellen back and forth be reflected ( Fig. 9). 18. Coupler according to one of claims 1 to 16, characterized in that a circulator is formed in that the coupling gate 3 is converted into a bidirectional gate by connecting the contact bridge of the converter ( 8 ) to the feed gate ( 1 ), the The converter is then designed as an acceptance part ( 34 ) ( FIG. 10).