RU2686584C1 - Controlled microwave signal coupler at magnetostatic waves - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to the radio engineering. Microwave signal coupler on magnetostatic waves contains a substrate of gallium-gadolinium garnet with two microwave generators placed on it with a gap in the form of parallel elongated strips of equal width from iron-yttrium garnet films (YIG). Besides, it comprises antenna for excitation of magnetostatic waves and antenna for reception of magnetostatic waves arranged at opposite ends of both microwave guides. Control elements comprise a constant magnetic field source configured to change the value and polarity of the magnetic field, and a magnetically sensitive element for changing the connection between the microwave guides, which is in form of a platform from a solid metal film placed over the YIG strips and overlapping both strips and the gap between them. Platform is in magnetic coupling with said source of magnetic field, and the size of the platform along the length is not less than 0.5 of the length of the strips.EFFECT: technical result is control of frequency range of division and width of frequency band by changing parameters of external magnetic field.4 cl, 4 dwg

Description

The invention relates to radio engineering microwave, in particular to devices based on magnetostatic waves and can be used as a frequency-selective power coupler.

Devices on magnetostatic waves (MSV) have the ability to rebuild parameters (transmission coefficients, delay time) and frequency modes of operation by changing both the magnitude and angle of the magnetic field (see, for example, the review “Magnonica - new direction of spintronics and spin-wave Electronics, UFN, Vol. 185, No. 10, 2015, pp. 1099-1128). Thus, a coupler on the MCB is known (DE 4204299 (A1), non-reciprocal waveguide coupler), SIEMENS AG, 09/18/1993. It contains a gallium-gadolinium garnet substrate, a film of iron yttrium garnet (YIG) grown on the substrate and microstrip antennas located on the film, providing the excitation of spin waves in the YIG film. The device can be used as an n-port directional coupler at frequencies of at least several GHz, as well as a phase shifter.

Known coupler, described in application JP 2003179413 (A) - MIC COUPLER, 06.27.2003. It contains a ferrite substrate with two waveguide lines, terminals at the ends of the waveguides and an electromagnet, which is located on a ferrite substrate. When a current is applied to an electromagnet, a DC magnetic field is applied to a ferrite substrate to generate an electron spin phenomenon, which changes the distribution of the electromagnetic field in the structure of the coupler, i.e. output level. The magnet is mounted on the non-working surface of the ferrite substrate.

The closest to the patented device is a microwave signal power coupler on surface magnetostatic waves (MSSV) (RU66410 U1, 11/27/2016), which contains a flat substrate, a signal transmission line located on the substrate, an input antenna, and first and second output antennas. The substrate is made of gallium-gadolinium garnet, the signal transmission line consists of two laterally coupled YIG films with a gap between them. The input antenna is located at one end, and the first output antenna is located at the other end of the first YIG film. The second output antenna is located at the end of the second YIG film from the side of the first output antenna. The coupler contains a ferroelectric layer located on the surface of the YIG films between the antennas. The disadvantage is the need to create an electric field to change the parameters of the ferroelectric layer.

The problem that the invention is directed to is to build a microwave power coupler for two outputs with the ability to control the mode of operation by changing the direction of the external magnetic field.

The patented microwave signal coupler on magnetostatic waves contains a gallium-gadolinium garnet substrate with two microfibres placed on it with a gap in the form of parallel elongated strips of equal width from YIG films, an antenna for exciting magnetostatic waves at one end of one microwave diode and an antenna for receiving magnetostatic waves, placed on opposite ends of both microwaves, controls.

The difference is that the controls include a source of a constant magnetic field, made with the possibility of changing the magnitude and polarity of the magnetic field, and a magnetically sensitive element for changing the connection between microwaves, made in the form of a platform made of a continuous metal film placed over the strips of YIG and overlapping both the strips and the gap between them, while the area is in magnetic communication with the said source of magnetic field, and the size of the area along the length is at least 0.5 of the length of the polo approx.

The coupler may differ in that the length of the microwave strips is 6 mm, the width is 0.2 mm, the gap between the strips is 0.04 mm, the pad length is 4 mm, and its width is 0.44 mm, and also because the saturation magnetization YIG films are M = 139Gs, their thickness is 10 microns, the thickness of a metal film is 5-10 microns.

The coupler may differ in that the area of a continuous metal film is applied through a sublayer of a dielectric to a strip of a film of YIG.

The technical result is the creation of a two-channel microwave power divider with control of the frequency range of the division and the frequency band of the divider by changing the parameters of the external magnetic field. This makes it possible to expand the functionality of the device.

The invention is illustrated by drawings, where:

FIG. 1 - device design;

FIG. 2 - dependence of the bond length on the frequency in opposite directions of the external magnetic field;

FIG. 3 - the results of a numerical experiment measuring the intensity of MSSW propagating in the structure under study at the same frequency value, but with opposite directions of the external magnetic field;

FIG. 4 shows the experimentally measured dependence of the transmission coefficient on frequency for various directions of the applied external magnetic field.

The design of the patented microwave signal coupler on spin waves is shown in FIG. 1. Positions denote: antenna 1 for exciting magnetostatic waves; microwaves 2,3 in the form of strips of films of iron yttrium garnet (YIG); antenna 4.5 for receiving magnetostatic waves; the substrate 6, the platform 7 of a continuous metal film placed over the strips of YIG and overlapping both strips and the gap between them. The external constant magnetic field source in FIG. not shown.

The electromagnetic coupling elements are made in the form of a microwave-like structure for magnetostatic waves on a substrate 6 of gallium-gadolinium garnet (GGG). The microwaves 2,3 are made on the basis of a YIG film in the form of two elongated strips of equal width h placed parallel to each other with a gap s chosen from the condition for providing the multimode coupling of magnetostatic waves. At the ends of the strip of the microwave 3, microstrip antennas 1 and 4 are made to excite and receive magnetostatic waves.

At the end of the microwave 2, there is a microstrip antenna 5 for receiving MSSW associated with the output port.

The substrate 6 of the film GGG has dimensions (W × D × T) 440 μm × 6000 μm × 500 μm. On the surface of the GGG film, a system of laterally-connected microwave guides 2 and 3 of 10 μm thick YIG is formed: the distance between the film strips in the bond region is 40 μm. Saturation magnetization М = 139Гс. Let us designate “first channel” microwave guide 2, “second channel” - microwave guide 3. On the system of laterally-connected microwave channels there are micro-band antennas 1,4,5, 30 microns wide for excitation and reception of PMSV. The input antenna 1 is located in the region of one end of microwave 2, the output antenna 4 is located in the region of the other end of microwave 2. The output antenna 5 is located at the end of microwave 3. The width of microwave diodes 2 and 3 is 200 µm. The length L of each waveguide is 6000 μm. The metal layer 7 covers the coupling region of two waveguides with a width of 440 μm and a length of 4 mm. An external magnetic field But is directed tangently along the Y axis (see Fig. 1).

The coupler operates as follows.

The input microwave signal, the frequency of which must lie in the frequency range determined by the external constant magnetic field, is fed to the input antenna 1. Next, the signal is converted into a MSSW propagating along microwave 3 (second channel). In such a system, spin waves are transferred from one microwave to another. If the metal layer 7 is placed near the laterally located microwaves 2 and 3, this will affect their dispersion characteristics: when the direction of the external magnetic field is changed by 180 °, the dispersion characteristic will take on a different appearance. Accordingly, it is possible to control the operation mode of this coupler by changing the direction of the external magnetic field H ₀ .

, где М - разница между волновыми числами первой симметричной и первой антисимметричной моды. Линией 8 показана указанная зависимость при распространении ПМСВ вдоль положительного направления оси X, а линией 9 - вдоль отрицательного направления оси X. Этого можно добиться путем изменения направления внешнего магнитного поля Н₀ на 180°.FIG. 2 shows the relationship of the bond length, which is calculated as

where M is the difference between the wave numbers of the first symmetric and the first antisymmetric mode. Line 8 shows the indicated dependence when MSSW propagates along the positive direction of the X axis, and line 9 shows the negative direction of the X axis. This can be achieved by changing the direction of the external magnetic field H ₀ by 180 °.

FIG. 3 shows the results of a numerical experiment measuring the intensity of MSSW propagating in the structure under study at the same frequency value, but with opposite directions of the external magnetic field. The top image corresponds to the direction of wave propagation along the positive direction of the axis X, the bottom image - along the negative direction of the axis X. It can be seen that the length changed when the direction of the external magnetic field H _0, which indicates a strong influence of the metal layer 7 on the propagation of surface magnetostatic waves in the structure .

The figure 4 shows a series of amplitude-frequency characteristics obtained by changing the direction of the external magnetic field H ₀ applied to the structure (along the positive direction of the X axis - line 10 and along the negative direction of the X axis - line 11). The failure on this characteristic means the transfer of energy from the first channel to the second. It is seen that when the direction of the external magnetic field H _{0 is} changed, the frequency range of this dip also changes.

Since, in a limited structure, a signal mode at each frequency has its own specific communication length, which is the distance over which the signal from microwave 2 is completely pumped into microwave 3, by supplying different frequencies to microwave 2, 3 different frequencies can be transmitted and separated. Due to the finite width of the microwave, the power coupler based on the laterally coupled structure operates in a multimode mode, which, in turn, allows the functionality of the coupler to be expanded in telecommunication systems with a high information signal density. This device also implements a method of controlling the length of the connection by changing the magnitude of the magnetic field.

Thus, the presented data confirm the achievement of the technical result, namely the ability to control the operation mode of the microwave power coupler by changing the direction of the external magnetic field, which allows you to expand the functionality of magnon logic devices.

Claims (4)

1. A microwave signal coupler at magnetostatic waves, containing a gallium-gadolinium garnet substrate with two microwaves placed on it with a gap in the form of parallel elongated strips of equal width from yttrium-iron garnet films (YIG), an antenna for exciting magnetostatic waves at one end of one microwave and antenna for receiving magnetostatic waves, placed at opposite ends of both microwave, the controls, characterized in that the controls include a source of oannogo magnetic field, made with the possibility of changing the magnitude and polarity of the magnetic field, and a magnetically sensitive element to change the connection between microwave, made in the form of a platform of solid metal film placed over the strips of YIG and overlapping both strips and the gap between them, while the platform is in magnetic coupling with the said source of magnetic field, and the size of the area along the length is at least 0.5 of the length of the strips. 2. A coupler according to claim 1, characterized in that the length of the microwave strips is 6 mm, width 0.2 mm, the gap between the strips is 0.04 mm, and the length of the pad is 4 mm, and its width is 0.44 mm. 3. A coupler according to claim 1, characterized in that the saturation magnetization of the YIG films is M = 139Gs, their thickness is 10 μm, the thickness of the metal film is 5-10 μm. 4. A coupler according to claim 1, characterized in that the area of a continuous metal film is applied through a sublayer of the dielectric to a strip of film of YIG.

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