SE518679C2 - Microstrip transition - Google Patents

Abstract

A device for transferring microwaves between a mechanical waveguide (115) and a microstrip line, which microstrip line comprises a conductor (140) and an earth plane (150), which are arranged on each side of a dielectric substrate (130). The microstrip line is plane-parallel to the waveguide and the waveguide has a cavity (124) adjacent to that end of the waveguide into which the microstrip line is partly inserted. The cavity is formed, for example, in the bottom (120) of the waveguide and extends perpendicular to the direction of the microstrip line. The distance (D2) between the plane in which the centre axis of the microstrip line is located and the bottom of the cavity is between lambda /8 and 3 lambda /8.

Description

»Crank 10 15 20 25 30 35 518 679 2 a circuit board with the microstrip technique is to create contact between the waveguide's roof and the microstrip conductor at the end of the waveguide. The contact is achieved by e.g. a metal sheet or solder between the guide wall and the microstrip conductor. However, applying this metal sheet or effecting this soldering is a cumbersome and laborious step and thus poses problems in automated fabrication of the transition. Furthermore, there is a not insignificant risk that the metal plate or the solder does not provide the desired contact, or that over time due to e.g. temperature variations become an interruption at the previous contact. An additional disadvantage of these types of transitions is that the microstrip line is grounded in direct current.

SUMMARY OF THE INVENTION An object of the invention is to provide an improved construction for transmitting microwaves between a mechanical guide and a microstrip line.

Another purpose is that this design should be easy to implement and well suited for automated manufacturing.

According to the invention, these objects are achieved by a device for transmitting microwaves between a mechanical guide and a microstrip line having a constructive design in accordance with the features specified in the appended claims.

According to the present invention, the waveguide has at its end a cavity extending perpendicular to the other planar direction of propagation of the waveguide.

The microstrip line is arranged in parallel with the direction of propagation of the waveguide and inserted at the end of the waveguide which has said cavity.

The cavity here constitutes a microwave resonator which is created, for example, by a delimited waveguide section.

The cavity can advantageously be achieved by a part of; || o | 10 15 20 25 30 35 518 679 3 the guide, in connection with its end into which the microstrip line is inserted, bends perpendicular to the direction of propagation of the rest of the guide.

Because waveguides are formed with a cavity at its end, the electromagnetic field in the part of the guide that precedes the cavity will interact with the electromagnetic fields in the cavity. Thus, the electromagnetic field will be strongest at the point where the microstrip wire is inserted into the guide. If the guide ends with a perpendicular deflection, the interaction between electromagnetic fields and the electromagnetic field will correspondingly be the strongest immediately for the perpendicular deflection, ie. in the place where the microstrip line is inserted.

The construction according to the present invention thus satisfies the need for a microwave transition between a waveguide and a microstrip line where the microstrip line is located in the same plane as the waveguide. It is advantageous to construct a microwave transition in a plane, e.g. This allows a common cover to be placed over the guide, forming its roof, and the circuit board on which the microstrip line is mounted. By designing the guide's floor and walls as a base plate and the guide guide's roof as a cover, the base plate and cover being formed in blocks by, for example, casting or other mechanical processing, this means that the cover can be easily applied on top of the base plate and the microstrip line , or the whole, belonging to the circuit board in an automated manufacture. Thus, a device that incorporates the circuit board, the guide and the transition between them can be manufactured in a much simpler way. The construction also enables the microstrip line to be plane-parallel with the guide, at the same time as the guide has a cavity at the end which communicates with the microstrip line. The construction m .. ~ o ~ 10 15 20 25 30 35 518 679 4 thus provides manufacturing advantages with respect to, among other things, complexity and price, while at the same time providing high efficiency.

The present construction shows the lack of a direct connection between the roof of the waveguide and the conductor of the microstrip line. Preferably, an air gap is found between the roof of the waveguide and the conductor of the microstrip line. This makes the above-mentioned cover very easy to mount. Thus, the lack of metal sheets, solder, and the like between the waveguide roof and the microstrip conductor conductor further contributes to a simpler automated fabrication of the structure that includes the microstrip transition. The construction requires only a careful placement of the microstrip line, but not of the waveguide roof, any metal sheet, or soldering point. Furthermore, the construction thereby avoids any fractures which may otherwise arise from the contact to which such metal sheets and solders are intended.

Preferably, the internal dimensions of the mechanical waveguide are such that the mechanical waveguide is limited to form at its end a narrow section into which the microstrip line is inserted. This section is narrower than 1/2 wavelength in free space to prevent the waveguide mode from leaking out of the waveguide.

It is further preferred that the part of the guide which constitutes the wall of the cavity closest to the end in which the microstrip line is inserted at the top has a bevel of the edge facing the cavity. It has surprisingly been found that this phasing results in the efficiency of the transmission of microwaves between the waveguide and the microstrip line being enhanced.

The frequency range for which the cavity resonates can advantageously be made trimable after the manufacture of said cavity. One way is to make at least one of the walls of the cavity movable, whereupon movement of this wall, with e.g. a screwdriver, affects the resonant frequency of the cavity 10 15 25 25 35 518 679. Alternatively, a screw can be screwed directly into said cavity, the length of the part of the screw being screwed into the cavity affecting the resonant frequency of the cavity. Those skilled in the art will appreciate how other appearances on the cavity can also be selected.

The microstrip line inserted at the end of the guide has no ground plane at the portion of the microstrip line found in the cavity, while the line on either side of the cavity comprises a ground plane. According to an embodiment of the invention, the conductor of the microstrip line is connected to the ground plane of the microstrip line in connection with the end of the line which is inserted into the mechanical waveguide and which is located just beyond the cavity. The cavity will then strengthen the connection between the magnetic field of the guide and the current loop which is thus formed at the end of the microstrip conductor, which current loop consists of the conductor, the ground plane and a part of the guide which delimits the cavity. According to one embodiment, the conductor of the microstrip line is connected to the ground plane over the end of the substrate and according to another embodiment via a bushing in the substrate. Both of these embodiments make it easy to fabricate a microstrip transition in a plane where the conductor of a circuit board is inductively coupled to the magnetic field of the guide.

In an alternative embodiment, the conductor of the microstrip line at the mechanical waveguide is unearthed and thereby has the function of a capacitively acting antenna. The conductor of the microstrip line thus has no connection with the ground plane of the microstrip line, and the cavity will then strengthen the connection between the electric field of the guide and the microstrip conductor. With this embodiment, it is easy to manufacture a microstrip transition in a plane where a circuit board has a conductor that is capacitively connected to the guide's electric field in the same way as an antenna. nynuo nanm; 5 15 67 25 In addition to the present invention providing a simpler way of providing the circuit board with a lid, the invention thus also allows simplifications in the construction of the circuit board itself, regardless of whether the microstrip conductor is inductively or capacitively coupled to the microwave conductor electromagnetic fields.

The cavity described above enables a high power output in the microstrip conductor, even though this is plane-parallel with the guide direction of propagation.

However, since it is desirable that the power supplied to the microstrip conductor is substantially equal to the power supplied to the waveguide, there is a need to further try to increase the efficiency, i.e. further increase in field strength in the guide. Normally, the width of the guide is twice as high as its height. With these dimensions, an optimal power output is not obtained in a plane-parallel microstrip conductor arranged according to the invention. One way to further increase the field strength is to reduce the height of the guide. Since the power in the waveguide is advanced in the form of electric and magnetic fields, then the passage area will decrease, whereby the field strengths will increase to maintain the power level.

It is thus preferred that the perpendicular distance between the inner floor of the guide and the inner roof of the guide is gradually decreasing for a portion of the guide in the direction of, and adjacent to, the part of the guide end which communicates with the microstrip line. This can be done in two alternative embodiments either in discrete steps or continuously. In addition to the decreasing distance between floor and ceiling enabling a higher power output at a plane-parallel microstrip conductor, this also entails an adaptation of the guide's impedance to the microstrip line impedance by reducing the guide's impedance in the direction of the microstrip line. When the magnitude changes in discrete steps, the steps are adjusted so that the desired impedance is obtained for the end of the waveguide. When the magnitude changes continuously, the magnitude change is made over a longer portion of the waveguide, than in the case of discrete steps, to obtain the desired impedance.

It is further understood that the conductor of the microstrip line may not only be grounded to the ground plane belonging to the microstrip technology, or ungrounded with respect to this ground plane, but it may also be connected to an adaptation network made of microstrip technology. The conductor can be made with a shape that is straight, zigzag-shaped for longer conductor length with maintained insertion depth, or with some other shape.

In the above-mentioned embodiments of the present invention, there are various shapes of the mechanical waveguide and its cavity, as well as variants of the design of the conductor of the microstrip line for providing a capacitive / inductive connection between the conductor and the electric / magnetic field of the cavity. It is within the scope of the invention to combine these shapes, alternatives and variants to provide an embodiment suitable for the current application. Thus, for example, the junction can be constructed by inserting a printed circuit board, where no pull-down of the microstrip conductor conductor has been made to the ground plane of the microstrip conduit, into a waveguide end, which end includes a cavity whose resonant frequency can be adjusted with a screw, edge, and where the waveguide of a portion beyond the cavity has an internal size that increases continuously along the waveguide in the direction away from the printed circuit board microstrip line.

The following exemplary embodiments are only a selection of all the combinations of features that may be made within the scope of the invention for the purpose of: true apps: obtaining an embodiment of the invention suitable for a particular application.

Brief Description of the Drawings Exemplary embodiments of the invention will now be described below with reference to the accompanying drawings, in which: Figure 1a shows a top view of a transition between a mechanical guide and a microstrip line according to an embodiment of the invention; Figure 1b shows a section along the line I-I in Figure 1a; Figure 2a shows a top view of a transition between a mechanical waveguide and a microstrip line according to another embodiment of the invention; Figure 2b shows a section along the line II-II in Figure 2a; Figure 3a shows a top view of a transition between a mechanical guide and a microstrip line according to a further embodiment of the invention; Figure 3b shows a section along the line III-III in figure 3a.

Description of Preferred Embodiments An exemplary embodiment will now be described with reference to Figures 1a and 1b, which show a transition, also called a microstrip junction, between a mechanical guide and a microstrip line.

Figure 1a shows a top view of the microstrip transition and Figure 1b shows a section through the microstrip transition along the line I-I in Figure 1a. In order to simplify the description, the plane shown in Figure 1a below will be called the horizontal plane.

The conductive walls of the mechanical guide 115 are formed by a base plate 120 and a cover 1010. The part of the cover which lies over the waveguide part is in the embodiment shown completely flat. The base plate forms the floor and walls of the waveguide, while the lid only forms the roof of the waveguide. The base plate and the lid can be formed in blocks by, for example, casting or other mechanical processing. It should be pointed out here that the lid does not necessarily have to be flat with the grooves formed in the bottom plate, but the grooves may very well, in whole or in part, be shaped in the lid which is consequently not flat. As indicated in Figure 1b, the cover not only forms a roof for the waveguide but also a cover for the circuit board on which the microstrip line is located.

The microstrip line comprises a conductor 140, also called a microstrip, which is arranged on one side of a dielectric substrate 130, and a conductive ground plane 150, 151 arranged on the other side of the substrate.

The microstrip line is attached with its ground plane directly to the base plate 120 by means of adhesive layers 160, 161 which have electrically conductive properties. Alternatively, direct contact is achieved by soldering. The microstrip line is fixed in such a way that the dielectric substrate is plane parallel to the mechanical waveguide 115, i.e. so that the spread of the microstrip line is horizontal at least in connection with the waveguide.

As shown in Figure 1b, there is a gap, or an air gap, 145 between the roof 110 of the waveguide and the conductor 140 of the microstrip line. The conductor 140 consequently has no contact with the cover 110. The conductor will have the function of an antenna which provides a capacitive connection to the electric field. i vàgledaren.

Adjacent the end of the mechanical waveguide into which the microstrip line is inserted, the walls of the groove at the bottom have a pair of projecting portions 128 which extend perpendicular to the direction of propagation of the waveguide. The microstrip line is inserted in the section formed between these projecting portions. In connection with said end, a portion of the guide conductor forms a cavity 124 which communicates with the remaining part of the guide conductor.

The cavity 124 has been formed in the bottom of the guide by a perpendicular deflection of the guide in relation to the other direction of propagation of the guide. The cavity is a microwave resonator that amplifies the electromagnetic fields of the microwaves within a frequency range that is desirable for the application. The bottom of the cavity 124 is at a distance D2 from the conductor 140 of the microstrip line which preferably corresponds to 1/4 of the guide wavelength.

The bottom of the cavity is a short-circuit plane, whereby a maximum for the electric field of the microwaves will arise 1/4 wavelength from the bottom, ie. at the site of conductor 140.

The gain of the electromagnetic field depends on the loaded Q-value and is proportional to \ ߤ. The loaded Q value indicates the relationship between the reactive power that spins around the cavity, or the microwave resonator, and the power that is taken out. High Q value gives high fields, but at the same time the resonator functions as a bandpass filter with a relative bandwidth that is 1 / Q. It is desirable that the Q-value of the resonator be selected as low as possible. However, it should be borne in mind that high Q-values also place higher demands on manufacturing tolerances.

The resonant frequency should be accurate so that the transmitted frequency does not fall outside the desired frequency band.

In the embodiment shown in Figures 1a and 1b, power transmission takes place between the waveguide and the conductor of the microstrip line through a capacitive coupling.

In the embodiments referred to in Figures 2a and 2b and 3a and 3b, respectively, the conductors of the microstrip line form a current loop and power transfer between the waveguide and the conductors of the microstrip line through an inductive coupling. - -. In Fig. 1b it can be seen that on the other side of the cavity, seen from the microstrip line, the mechanical waveguide 115 has an inner size which in height, ie perpendicular to the horizontal plane, increases gradually and continuously along the waveguide in the direction away from the microstrip line for a portion of the waveguide. This is achieved by the groove in the upper side of the bottom plate gradually and continuously becoming deeper in the direction away from the microstrip line, whereby an inclined floor 126 is formed for a portion of the waveguide. This sloping floor will effect an adaptation of the impedance of the waveguide to the impedance of the microstrip line by decreasing the impedance of the waveguide in the direction of the microstrip line.

A second embodiment will now be described with reference to Figures 2a and 2b, which show a microstrip junction between a mechanical waveguide and a microstrip line. Figure 2a shows a top view of the microstrip transition and Figure 2b shows a section through the microstrip transition along the line II-II in Figure 2a. In analogy to the first embodiment, the plane shown in Figure 2a below will be referred to as the horizontal plane. Numbering of the reference numerals in Figures 2a and 2b has been done in analogy to the numberings in Figures 1a and 1b, note, however, that in Figures 1a and 1b the designations begin with the number 1 and in Figures 2a and 2b they begin with the number 2. In the description of this second embodiment, only those that distinguish it from the first embodiment are specified.

On the other side of the cavity 224, seen from the microstrip line, the mechanical waveguide 215 has an internal size which in height, i.e. perpendicular to the horizontal plane, gradually increases in discrete steps along the waveguide in the direction away from the microstrip line for a portion of the waveguide. This is accomplished by making the groove in the top of the bottom fun; 515 679 12 gradually and in discrete steps becomes deeper in the direction away from the microstrip line and thus forms a step-shaped floor 226 for a portion of the waveguide.

This step-shaped floor involves an adaptation of the impedance of the waveguide to the impedance of the microstrip line.

In Figures 2a and 2b, the microstrip conductor conductor 240 is connected to the microstrip conductor conductive ground plane 251 via a metallization 242 extending from the conductor to the ground plane over the end of the dielectric substrate 230 located beyond the cavity of the waveguide 215. In this way, an electrical loop is created. of the conductor 240, ground plane 250, 251 and the part of the waveguide bottom which delimits the cavity. This loop provides an inductive connection to the magnetic field in the cavity.

Figure 3a shows a microstrip junction between a mechanical waveguide and a microstrip line according to a third embodiment of the invention. Figure 3a shows a top view of the microstrip transition and Figure 3b shows a section through the microstrip transition along the line III-III in Figure 3a. In analogy to previous embodiments, the plane shown in Figure 3a below will be referred to as the horizontal plane. The numbering of the reference numerals in Figures 3a and 3b has been made in analogy to the numbering in Figures 1a and 1b and 2a and 2b, note, however, that in Figures 3a and 3b the designations begin with the number 3. In the description of this third embodiment only such as distinguishes it from the first and second embodiments.

In this embodiment, the cavity 324 has a bevel 325 of the edge closest to the end of the waveguide into which the microstrip line is inserted. It has surprisingly been found that this phasing results in the efficiency of the transmission of microwaves between the waveguide and the microstrip line being enhanced. 1: 1; - 10 15 20 25 30 518 679 13 The conductor 340 of the microstrip line is here via a bushing 342 in the part of the dielectric substrate 330 which is beyond the cavity of the waveguide 315 recessed to the conductive ground plane 351 of the microstrip line.

In the exemplary embodiments described above, different shapes of the mechanical guide wire beyond the cavity seen from the microstrip line have been described, different variants of the design of the microstrip wire conductor to provide a capacitive / inductive connection between the conductor and the cavity electric / magnetic field have also been shown. In one embodiment, a beveling of the edge of the cavity located at the end of the waveguide into which the microstrip line is inserted has also been described. To limit the number of embodiments to a manageable number, all combinations of these shapes, alternatives and variants have not been described. However, it is within the scope of the invention to combine these forms, alternatives and variants to achieve an embodiment suitable for the current application. Thus, for example, the transition can be constructed with a chamfer of the edge of the cavity and where no reduction of the conductor of the microstrip line has been made to its ground plane. This can then be combined with a guide that has a sloping floor or a stepped floor on the other side of the cavity seen from the microstrip line.

Claims (12)

: srxn: sme 10 15 20 25 30 35 518 679 14 PATENTKRAV Device for transmitting microwaves between a mechanical guide (115) and a microstrip line, said microstrip line comprising a conductor (140) and a ground plane (150) arranged on either side of a dielectric substrate (130), characterized in that the microstrip line is plane parallel to the guide and partially inserted into one end of the guide and that the guide has a cavity (124) adjacent said end, which cavity extends in a direction perpendicular to the direction of the microstrip line, the distance (D2) between the plane in which the microstri the center axis is located and the bottom of the cavity is between 1/8 and 3/8 of a guide length. The device of claim 1, wherein said distance between the center axis of the microstrip line and the bottom of the cavity is substantially 1/4 of the guide length. Device according to claim 1 or 2, wherein the waveguide and the conductor (140) of the microstrip line are arranged in such a way that an air gap (145) is formed between the roof (110) of the waveguide and the conductor of the microstrip line. Device according to any one of the preceding claims, wherein the internal dimensions of the mechanical guide are such that the mechanical guide is limited to form a narrow section (D1) into which the microstrip line is inserted, the section not being wider than 1/2 wavelength in free space. . »~ 10 15 20 25 30 35 518 679 15 Device according to any one of the preceding claims, wherein the part of the guide which constitutes the wall of the cavity (324) closest to said end of the guide of the guide has a bevel (325) of the edge facing the cavity. Device according to any one of the preceding claims, wherein the conductor (140) of the microstrip line is unearthed. Device according to any one of claims 1 to 5, wherein the conductor (140) of the microstrip line is connected to the ground plane (150) of the microstrip line in connection with the end of the microstrip line which is partially inserted into the mechanical waveguide. The device of claim 7, wherein the conductor (240) of the microstrip line is connected to the ground plane (250) of the microstrip conduit by the conductor being pulled down (242) over the substrate (230) of the microstrip conduit and over the end of the microstrip conduit partially inserted into the mechanical waveguide. The device of claim 7, wherein the conductor (340) of the microstrip line is connected to the ground plane (350) of the microstrip line via a bushing (342) through the substrate (330) of the microstrip line. Device according to any one of the preceding claims, wherein the distance between the inner floor of the guide and the inner roof of the guide is gradually decreasing towards the end of the guide into which the microstrip line is inserted and for a portion of the guide adjacent this end. The device of claim 10, wherein said successive decrease occurs in discrete steps (226). 518 679 16 The device of claim 10, wherein said successive decrease occurs continuously (126).