KR101496302B1 - Millimeter Wave Transition Method Between Microstrip Line and Waveguide - Google Patents

Abstract

The present invention relates to a method of manufacturing a microwave transmission line in which a microstrip line and a waveguide transition section are formed on the same plane of the substrate or between the microstrip line and the waveguide section in order to transmit the millimeter wave signal with a very low loss between the microstrip line and the waveguide patterned in the millimeter frequency band, And a transition method of the broadband millimeter wave signal by the transition portion when the signal is on the opposite surface.

Description

(Millimeter Wave Transition Method Between Microstrip Line and Waveguide)

The present invention relates to a method of millimeter wave signal transitions between a microstrip line and a waveguide, and more particularly, to a method of millimeter wave signal transitions between a microstrip line and a waveguide using a single dielectric substrate, To a wideband low loss signal transition for delivering a millimeter wave signal with very low loss.

1) Papers: Kunio Sakakibara, Fuminori Saito, etc, 'Microstrip line to waveguide transition connecting and backed RF circuits', IEEE International symposium on antennas and propagation 2003, Vol. 3, pp. 958-961, June, 2003. In this paper, a structure using a metal waveguide and a microstrip line transition is proposed. A slot is used for coupling to the waveguide. That is, the signal input from the microstrip line carries the signal through the capacitive coupling and transfers it to the slot on the opposite side.

In this paper, we describe various structures for square waveguides and microstrip lines. In this paper, we describe the various structures of square waveguides and microstrip lines.

US Provisional Patent Application Publication No. 2003-0085626 A1 proposes a transition structure using a multi-layer substrate, and discloses a multi-layer structure using a multi- It is a structure that extends bandwidth by using patch structure among several boards. However, it is difficult to manufacture in a millimeter wave band.

In this paper, we propose a microstrip line and waveguide transition fabricated on a single-layer dielectric substrate using a single substrate. A patch is used for the waveguide, and the microstrip line and the patch are on opposite sides.

Among these prior arts, a transition using a multi-layer structure is complicated, the manufacturing cost is high, and the tolerance becomes very large when stacking. For the application in the millimeter wave band, a structure for minimizing the loss due to the parallel flat plate mode is required at the time of fabricating the pattern, and a transition structure for the case where the microstrip line and the waveguide are opposite to each other is required It is true.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a microwave oven capable of reducing millimeter wave signals between a microstrip line patterned in a millimeter frequency band and a waveguide, The present invention provides a method of transitioning a broadband millimeter wave signal by a transition portion when the microstrip line and the waveguide transition portion are on the same plane or opposite sides of the substrate.

In order to accomplish the above object, according to one aspect of the present invention, a transition for millimeter wave signal transition between a microstrip line and a waveguide includes: And a dielectric substrate having a metal pattern formed at an entrance end of the line and coupled to the waveguide to enclose the metal pattern in one end region of the oval waveguide as the waveguide, Symmetrical slits in which the microstrip line enters at one end of the dielectric substrate and extends to a predetermined length inside the metal pattern and has a predetermined width from both sides of the corresponding portion extending inward, Wherein the microstrip line and the dielectric substrate are coplanar Wherein the microstrip line and the ohmic-type waveguide are connected to each other through the metal pattern.

In order to tune the frequency of the signal, the width and length of the left and right symmetrical slit are determined according to the shape of the waveguide.

The dielectric substrate includes a top metal pattern formed at a predetermined distance from an entrance portion of the microstrip line and around the metal pattern, and a rear metal pattern formed entirely on a rear surface of the dielectric substrate. The top metal pattern and the rear metal pattern And is electrically connected by a via connection for ground.

Holes of a plurality of square arrays formed along the entrance of the microstrip line and around the metal pattern for the via connection.

The via-holes of the plurality of square arrays for via connection of the top surface metal pattern and the back surface metal pattern are minimized and signal loss due to failure of the via hole is minimized, and parallelism formed by the top surface metal pattern and the back surface metal pattern You can minimize the signal loss by removing the plate mode.

According to another aspect of the present invention, a transition for millimeter wave signal transition between a microstrip line and a waveguide includes a metal patch on the opposite side connected to the microstrip line formed on one side by a via connection And a dielectric substrate bonded to the waveguide so as to surround all of the metal patches in one end region of the waveguide, wherein the microstrip line extends from one end of the dielectric substrate and extends for a predetermined length, Wherein the metal patch and the via connection are made for signal transition between the microstrip line and the waveguide through the metal patch formed on the opposite plane in the microstrip line and the dielectric substrate.

The waveguide may comprise a spherical waveguide or an oval waveguide.

The metal patch may include a square patch or a false patch.

Wherein the dielectric substrate has a first metal pattern formed on the one surface at a predetermined distance from a portion extending from the end of the microstrip line and a second metal pattern formed on the opposite side of the metal patch, wherein the first metal pattern and the second metal pattern are electrically connected by a via connection for ground.

And via holes formed along the periphery of the metal patch for the via connection.

Wherein a via hole for connection of the first metal pattern and the second metal pattern is minimized, and a parallel plate mode formed by the first metal pattern and the second metal pattern is minimized So that signal loss can be minimized.

Symmetrical slits in which the metal is removed by a predetermined width and length at symmetrical positions at the center of the metal patch.

The width and length of the left and right symmetrical slit are determined according to the shape of the waveguide for tuning the frequency of the signal.

The microstrip line may be connected to a front end of an RF board in a radio frequency (RF) communication system to transmit / receive signals to / from each other.

The microstrip line may be connected to a transmission / reception antenna in a radio frequency (RF) communication system to transmit / receive signals to / from each other.

According to another aspect of the present invention, there is provided a signal transmission method for millimeter wave signal transition between a microstrip line and a waveguide, comprising the steps of: forming a metal pattern or metal patch electrically connected to a microstrip line formed on a dielectric substrate, And the waveguide is coupled with the microstrip line so that the microstrip line and the waveguide are both wrapped in one end region of the dielectric substrate, so that signal transitions are made between the microstrip line and the waveguide, Wherein the via connection is made by connecting the first metal pattern and the second metal pattern formed on the metal pattern or via the via hole formed along the periphery of the metal patch or the metal patch.

According to a millimeter wave transition method between a microstrip line and a waveguide according to the present invention, a microstrip line is formed between a microstrip line of a substrate and a corrugated waveguide, The frequency can be optimized. Also, for signal transmission between the microstrip line of the substrate and the waveguide on the opposite side of the substrate, the end of the microstrip line is connected via a via connection to a patch with a patch or slit on the opposite side, The frequency can be tuned to optimize the resonant frequency.

In such a structure, the transmission characteristics of the signal through the removal of the parallel plate mode is increased according to the via ground connection structure with the rear surface of the substrate by using the rectangular via arrangement around the end of the microstrip line, It is possible to minimize the signal loss caused by the noise.

The transitional unit structure of the present invention can easily transmit a millimeter wave signal with a low loss in a signal transmission using a waveguide between an RF front end and an antenna feeding part in a radar and a communication system.

FIG. 1 is a view for explaining a signal transition using a wave guide between an RF circuit board and a transmitting / receiving antenna according to an embodiment of the present invention.
2 is a view for explaining a transition structure between a microstrip line and a waveguide according to an embodiment of the present invention.
3A and 3B show simulation results of the reflection coefficient (S11) according to the structure without the slit at the end of the microstrip line and the rounding degree of the rectangular patch.
4A, 4B, 4C, and 4D are diagrams showing the structure in the case where there is a symmetrical slit at the end of the microstrip line in FIG. 2, a reflection coefficient S11 according to the change of g at L = 0.68 mm and L = (S11) and reflection coefficient (S11) and transmission coefficient (S21) at L = 0.68 mm, g = 0.18 mm.
5 is a view for explaining a transition structure between a microstrip line and a waveguide according to another embodiment of the present invention.
6A and 6B show simulation results of the reflection coefficient S11 and the transmission coefficient S21 in the structure of FIG.
7 is a diagram for further illustrating an example of a transition structure including a patch having a slit instead of a square patch in the structure of FIG.
FIG. 8 shows a simulation result of the transmission coefficient S21 for the structure of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

FIG. 1 is a view for explaining a signal transition using a wave guide between an RF circuit board and a transmitting / receiving antenna according to an embodiment of the present invention. The present invention relates to a method and apparatus for transmitting a millimeter-wave signal (for example, a frequency of 30 to 300 GHz and a wavelength of 30 to 300 GHz) with a low loss at the time of signal transmission using a waveguide between a radio frequency (RF) front end and a transmission / reception antenna 1 < / RTI > to 10 mm) of the waveguide as shown in FIG. The waveguide may be a variety of waveguides such as spherical waveguides, oval waveguides, flat waveguides such as microstrip lines, and the like.

The multi-beam array antennas for transmitting and receiving signals must be spaced apart by a certain physical distance, but the RF front end is highly compact and integrated. In general, signal transitions can be made using vias and microstrip lines at frequencies below about 30 GHz. However, in the millimeter band, transmission loss of vias and precision fabrication are difficult to use. Therefore, a final input / output part of a TRX RF transmission / reception circuit (e.g., a LNA (Low Noise Amplifier), a power amplifier, a mixer, etc.) and a transmission / reception part of a TRX RF board are connected between the input / There is a waveguide for signal transmission between the antennas and there is a structure in which the respective transition parts for signal transmission between the microstrip line and the waveguide exist at both ends of the waveguide for signal transmission with the waveguide use. That is, a u-strip line connected to each TRX RF board or antenna can exchange signals with the waveguide through the transitions.

2 is a view for explaining a structure of a transition portion 100 between a microstrip line 110 and an oval type waveguide 120 according to an embodiment of the present invention. Where the microstrip line 110 is extended or connected to the TRX RF board or antenna via another microstrip line.

The oval type waveguide 120 is easier to manufacture than a square waveguide according to the fabrication method, and is used when it is difficult to process a spherical waveguide at the time of manufacturing the system. When a waveguide waveguide is used, a special structure for signal transition with the microstrip line 110 is required because it differs from the electrical characteristics of the spherical waveguide.

2, a transition unit 100 according to an embodiment of the present invention includes a dielectric substrate 10 for signal transition between a microstrip line 110 and a waveguide 120 A rear metal pattern 20 for grounding is formed on the rear surface of the dielectric substrate 10 so that signal transitions can be made on the same plane through the upper surface of the dielectric substrate 10. [ A metal pattern 115 having a slit 117 formed at the end of the microstrip line 110 extending from one end of the dielectric substrate 10 by a predetermined length, The upper surface metal pattern 30 formed by being electrically isolated from the upper surface metal pattern 30 is formed. The rear surface metal pattern 20 and the top surface metal pattern 30 are electrically connected to each other by a metal connection via a plurality of via holes 21, that is, via connection.

More specifically, the end of the microstrip line 110 formed on the upper surface of the dielectric substrate 10 has a metal pattern 115 having a rounded corners (rectangle to rounded corners) The microstrip line 110 extends inwardly of the metal pattern 115 by a predetermined length and is provided with left and right symmetrical slits (metal removed) 117). The resonance frequency can be optimized by tuning the frequency using the slit 117 as described below.

The top metal pattern 30 is formed at a predetermined distance from the entrance of the microstrip line 110 and the metal pattern 115 having the slits 117. The top metal pattern 30 is formed on the rear surface And are electrically connected to each other via via-holes 21 in a plurality of square arrangements through the metal pattern 20 for use in via connection at a plurality of locations. It is preferable that the via connections are made as close as possible to the entry of the microstrip line 110 and as far as possible along the metal pattern 115 with the slits 117 therein. The via holes 21 of the square arrangement minimize the signal loss due to the failure of the via hole generated during fabrication and eliminate the parallel plate mode formed by the back surface metal pattern 20 and the top surface metal pattern 30, Thereby minimizing signal loss.

As shown in the left side of FIG. 2, one end of an oval waveguide 120 is placed on a corrugated metal pattern 115 (rounded corners in a rectangular shape or a semicircular shape in both sides of a rectangle) One end of the waveguide waveguide 120 is coupled along the part where the metal pattern 115 and the upper surface metal pattern 30 are separated from each other, Type metal pattern 115 so that signal transitions between the microstrip line 110 and the waveguide 120 can be performed.

3A and 3B illustrate the structure of the structure without the slit 117 in the square pattern 170 at the end of the microstrip line and the simulation result of the reflection coefficient S11 according to the edge rounding degree of the rectangular pattern 170 in the structure of FIG. . Here, for the simulation, the frequency used was 77 GHz as the center frequency, the thickness of the dielectric substrate was 5 mil, the thickness of the metal was 1 / 2OZ, and the relative permittivity was 2.2@77 GHz.

3A, the basic structure of a waveguide is a standard WR-10 (i.e., width x length: 2.54 x 1.27 mm), and a radius R = 0.635 mm is used to form an oval shape. The size of the square pattern 170, which is a spurious pattern without the slits 117, is 2.0 x 1.07 mm in width x length. Since the rectangular pattern 170 is overlapped with a desired waveguide to be used, the rectangular pattern must be deformed.

FIG. 3B shows the reflection coefficient S11 according to the degree of rounding each corner in the rectangular patch 170. FIG. In the case of r = 0, as the radius r increases, the oval waveguide and the pattern do not overlap with the corrugated waveguide, but the center frequency, 76.5 GHz, gradually deviates. Therefore, it can be seen that, in the case of a waveguide with a waveguide, only the basic wave pattern can be used to tune the target center frequency.

4A, 4B, 4C, and 4D are diagrams showing the structure in the case where the symmetrical slit 117 at the end of the microstrip line 110 is present in FIG. 2 and the reflection coefficient according to the variation of the width g at the length L = 0.68 mm of the slit 117 (S11), a reflection coefficient S11 according to a change in L at g = 0.18 mm, and a reflection coefficient S11 and a transmission coefficient S21 at L = 0.68 mm, g = 0.18 mm.

Here, except for the slit 117 and the length L and the width g, the remaining conditions such as the waveguide 120 are set as in FIG. 3A. Here, the variable of the size adjustment of the slit 117 is g, L. Another variable is the position of the slit 117 and the slit 117 may have an offset of a predetermined distance from the center of the microstrip line 110. [ That is, when the micro strip line 110 is extended by a predetermined length L into the metal pattern 115, the width of the line 110 of the corresponding portion extended inside the metal pattern 115 It is not necessarily the same as the line width of the entrance portion before entry, but may be larger or smaller.

As shown in FIG. 4B, in the reflection coefficient S11 characteristic according to the change (0.1 to 0.2 mm) of the width g at the length L = 0.68 mm of the slit 117, the center frequency becomes gradually smaller as g becomes larger, For a frequency of 77 GHz, g = 0.18 mm is optimal.

As shown in FIG. 4C, in the reflection coefficient S11 characteristic according to the change of L at g = 0.18 mm, the center frequency gradually decreases with increasing L, and L = 0.68 mm is optimal for 77 GHz as the target frequency.

As shown in FIG. 4 (d), the reflection coefficient (S11) and the transmission coefficient (S21) characteristics at L = 0.68 mm and g = 0.18 mm were found to match the results simulated by using ANSYS HFSS and CST Microwave Studio . The left Y axis of the graph represents the reflection coefficient S11, and the right Y axis represents the transmission coefficient S21. As shown, the transmission coefficient (S21) is -0.4dB near 76.5GHz and the 10dB bandwidth is about 4GHz.

5 is a view for explaining a structure of a transition portion 200 between a microstrip line 110 and a waveguide according to another embodiment of the present invention.

5, a transition unit 200 according to another embodiment of the present invention includes a dielectric substrate 10 for signal transition between a microstrip line 110 and a rectangular waveguide 220, In order to perform a signal transition between the microstrip line 110 formed on the upper surface of the dielectric substrate 10 and the rectangular waveguide 220 coupled to the back surface of the dielectric substrate 10, A rectangular metal pattern 231 is formed on the rear surface of the substrate 10 for rectangular patches 240 (which can be patch patterned as occasionally) and a ground for surrounding the periphery of the rectangular patches 240 A microstrip line 110 extending from one end of the dielectric substrate 10 and extending by a predetermined length is formed on the upper surface of the dielectric substrate 10 and an upper surface The metal pattern 230 . The rear surface metal pattern 231 and the top surface metal pattern 230 are electrically connected using a metal connection, that is, a via connection, through the plurality of via holes 21. The square patches 240 on the back side are electrically connected to the via connection through the via hole 22 formed at the end of the upper microstrip line 110.

5, one end of the spherical waveguide 220 along the part where the square patch 240 on the rear surface of the substrate 10 and the rear surface metal pattern 231 are spaced apart from each other, that is, The signal path between the microstrip line 110 and the waveguide 220 through the via-coupled square patch 240 is coupled to the waveguide 220 in such a manner that the waveguide 220 is completely surrounded by the rectangular patch 240 in the region of the end of the waveguide 220 Transition can be made.

In this case, the number of the via holes 21 formed in the vicinity of the square patch 240 as much as possible makes it possible to minimize the signal loss due to the failure of the via hole, And the parallel plate mode formed by the rear metal pattern 231 is removed to minimize the signal loss.

Although an example of the rectangular waveguide 220 is shown here, it may be replaced with an oval type waveguide.

6A and 6B show simulation results of the reflection coefficient S11 and the transmission coefficient S21 in the structure of FIG. Here, the center frequency is 76.5 GHz. 6A is less than 10 dB in the frequency band from 74 GHz to 81 GHz, and the transmission coefficient S21 characteristic of FIG. 6B shows that the signal transition is well performed with a low loss of 3 dB or less .

7 is a diagram for further illustrating an example of a transition structure including a patch 250 having a slit 257 instead of the rectangular patch 240 in the structure of FIG.

7, the back patch 250 connected to the via connection through the via hole 22 at the end of the microstrip line 110 formed on the upper surface of the dielectric substrate 10 is formed in the right and left sides of the via hole 22 And has a symmetrical rectangular slit 257. That is, left and right symmetrical slits 257 are formed by removing a metal by a predetermined width and length at symmetrical positions at the center of a square patch (possibly in the form of overcurrent patching), and accordingly, Holes 22 through the via-holes 22 through the via-holes 22.

The structure having the slits 257 as described above is different from the structure shown in FIG. 5 by the rectangular patch 240 only in that the shape of the waveguide 220 (such as horizontal, vertical length, The length (or the width) of the slit 257 may be adjusted according to the shape (e.g., rounding shape, etc.). 5, when the waveguide 120 is replaced with an oval waveguide 120 as shown in FIG. 2, the waveguide 220 may have a slit 257 (see FIG. 5) ) Can be adjusted to adjust the optimum frequency.

FIG. 8 shows a simulation result of the transmission coefficient S21 for the structure of FIG. Here again, it is confirmed that the signal transitions operate at a center frequency of 76.5 GHz with a low loss of 3 dB or less.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

The microstrip line (110)
An oval type waveguide 120
In the dielectric substrate 10,
Back metal pattern (20)
The via hole (21)
The upper surface metal pattern 30,
The slit (117)
A rectangular waveguide (220)
Rectangular patches (240)
The upper surface metal pattern 230,
The back metal pattern (231)
The slit (257)

Claims (16)

In a transition for a millimeter wave signal transition between a microstrip line and a waveguide,
A dielectric substrate having a metal pattern formed at an entrance end of the microstrip line and coupled to the waveguide to enclose the metal pattern in one end region of the oval waveguide as the waveguide, / RTI >
The microstrip line includes left and right symmetrical slits extending from one end of the dielectric substrate and extending to a predetermined length inside the metal pattern and having a predetermined width from both sides of the corresponding portion extending inwardly In addition,
Wherein the transition is for signal transition between the microstrip line and the corrugated waveguide through the corrugated metal pattern formed on the same plane in the microstrip line and the dielectric substrate. The method according to claim 1,
Wherein a width and a length of the left-right symmetrical slit are determined according to the shape of the waveguide for tuning the frequency of the signal. The method according to claim 1,
The dielectric substrate includes a top metal pattern formed at a predetermined distance from an entrance portion of the microstrip line and around the metal pattern, and a rear metal pattern formed entirely on a rear surface of the dielectric substrate. The top metal pattern and the rear metal pattern Wherein the transition is electrically connected by a via connection for ground. The method of claim 3,
And a plurality of square-shaped via holes formed along the periphery of the microstrip line and around the metal pattern for via connection. 5. The method of claim 4,
The via-holes of the plurality of square arrays for via connection of the top surface metal pattern and the back surface metal pattern are minimized and signal loss due to failure of the via hole is minimized, and parallelism formed by the top surface metal pattern and the back surface metal pattern To minimize signal loss by removing the plate mode. The method according to claim 1,
In a transition for a millimeter wave signal transition between a microstrip line and a waveguide,
And a dielectric substrate on the opposite side connected to the microstrip line formed on one side by a via connection and coupled to the waveguide so as to enclose all of the metal patches in one end region of the waveguide,
Wherein the microstrip line extends from one end of the dielectric substrate and extends for a predetermined length, and the metal patch and the via connection are formed at an end thereof,
Wherein the transition is for signal transition between the microstrip line and the waveguide through the metal patch formed on the opposite plane in the microstrip line and the dielectric substrate. The method according to claim 6,
Wherein the waveguide comprises a spherical waveguide or an oval waveguide. The method according to claim 6,

Characterized in that the metal patch comprises a square patch or an oblique patch. The method according to claim 6,
Wherein the dielectric substrate comprises:
A first metal pattern formed on one side of the microstrip line and spaced apart from the end of the microstrip line by a predetermined distance,
And a second metal pattern on the opposite surface for a ground surrounding the metal patch at a predetermined distance around the metal patch,
Wherein the first metal pattern and the second metal pattern are electrically connected by a via connection for ground. 10. The method of claim 9,
And via holes formed along the periphery of the metal patch for the via connection. 11. The method of claim 10,
Wherein a via hole for connection of the first metal pattern and the second metal pattern is minimized, and a parallel plate mode formed by the first metal pattern and the second metal pattern is minimized To minimize signal loss. ≪ RTI ID = 0.0 > A < / RTI > The method according to claim 6,
Wherein the metal patch comprises a left-right symmetrical slit in which a metal is removed by a predetermined width and length at symmetrical positions at the center of the metal patch. 13. The method of claim 12,
Wherein the width and the length of the left-right symmetrical slit are determined according to the shape of the waveguide for tuning the frequency of the signal. 7. The method according to claim 1 or 6,
Wherein the microstrip line is connected to a front end of an RF board in a radio frequency (RF) communication system to transmit / receive signals to / from each other. 7. The method according to claim 1 or 6,
Wherein the microstrip line is connected to a transmission / reception antenna in a radio frequency (RF) communication system to transmit / receive signals to / from each other. delete

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