EP1303001B1 - A broadband microstrip directional coupler - Google Patents

Abstract

A directional coupler has a substrate and two first terminals (1,2) arranged on the substrate and connected by a first line (11) and two second terminals (3,4) connected by a second line (12) in which the lines (11,12) run through a coupling zone. The lines (11,12) are spaced in the coupling zone by a conductor surface (20) un-connected with the lines.

Description

The present invention relates to a broadband Directional coupler in microstrip technology and the Use of such a directional coupler.

Such directional couplers come in high and ultra high frequency applications used to get from one up a first line led signal a defined, in general small share on one überzukoppeln second line and so in particular For control or monitoring purposes.

Such a directional coupler generally includes a Substrate on which the two wires are galvanically isolated are guided through a coupling zone, in they are capacitive and magnetic to each other influence.

On the first line, signals in general the coupler in opposite directions run through.

It is important for many applications, selective only to be able to pick up those signals that are in one of the two opposite directions of the first Spread out line, or in opposite direction Directions propagating signals from each other to be able to distinguish, for example, with the help of a between a transmitter output stage and an antenna arranged Richtkopplers the output signal of Amplifier from a possibly reflected from the antenna Signal to distinguish. Therefor it is necessary that the directional coupler a high Has degree of directionality, i. if an input signal on the first line the directional coupler goes through in one direction, so should that on the second line evoked signal itself in this with very predominant intensity too only spread in one direction.

The directionality is achieved by the combined Exploitation of capacitive and magnetic Coupling. If a point of the second line of a signal carried on the first line capacitive is influenced by it, so signals from him same phase in both directions of the second line out. With magnetic coupling of a point differ from him in different Directions outgoing signals by 180 ° in phase. This feature is used with directional couplers, by capacitive and magnetic coupling so be combined with each other, that both are equal strong contributions to the second line generated Signal deliver, but with the contributions for in a first direction of the second line structurally overlay the propagating signal and for a propagating in the opposite direction Overlay signal destructively.

Such an effect is by simple parallel guidance the first and second lines in the coupling zone impossible to achieve, because in such a Case the coupling is predominantly magnetic nature is.

It is therefore necessary to have a geometry for the different ones To find lines of the directional coupler the capacitive coupling compared to the magnetic favored. A well-known and already in US-A-5,159,298 described as prior art Solution to this problem is shown in Fig. 1. The two lines between input / output ports 1, 2, 3, 4 of the directional coupler two coupling lines 5, 6, located in a extend predetermined distance parallel to each other and each other in a distance dependent one Predominantly influence magnetically. Each at the ends of the parallel coupling lines 5, 6 There are areas of strong capacitive coupling in the form of to the other coupling line towards projecting conductor sections 7, the local provide a predominantly capacitive coupling.

A similar construction is known from US-5 767 763 A1 known. Here are the coupling lines respectively from two mutually perpendicular oriented Sections whose ends face each other and the areas of strong capacitive coupling.

With a constructed according to the known scheme of Fig. 1 coupler good directionality for frequencies can be achieved, whose wavelength in the lines of four times the length of the coupling lines 5 and 6 corresponds. If deviations from this frequency occur, then the relative phase position of the capacitive contributions of the projecting conductor sections 7 changes; a satisfactory directionality can therefore only be achieved within a narrow band around this one frequency due to the design principle. US-A-5,159,298 investigates ways to optimize the directionality of a directional coupler having an electrical length l _e = π / 2 by a single localized capacitor.

In order to build a broadband directional coupler, it would be desirable per se to reduce the length of the coupling zone. However, this encounters difficulties in the conventional design principle, because the realization of a coupling capacity between the first and second lines always implies the occurrence of a parasitic capacitance between the lines and a ground plane, which is applied to a side of the substrate opposite the lines. The presence of the parasitic capacitance causes disturbances in the behavior of the coupling zone. Conventionally, these disturbances are compensated for by arranging the coupling capacitances in pairs at a distance of λ / 4, where λ is the wavelength corresponding to the center frequency of the frequency band in which the coupler is effective. This distance λ / 4 therefore defines a minimum size; which must have the coupling zone. If you wanted to opplungszone the _K decrease below this level, so you would have to compensate the caused by the presence of the coupling capacitance disorders using inductive or capacitive auxiliary structures.

In US-4,376,921 a directional coupler is proposed in which the length of the coupling area clearly less than λ / 4 is made. To get one out of the Shortening of the coupling area resulting deficit to fix capacitive coupling is between the lines an additional capacitive Coupling element in the form of one or more track fingers attached, each of a Lead out to the other, without to reach her.

While in US-A-4,376,921 the conductor fingers each a straight piece of the other line opposite or between strip finger of the to intervene with another line, US 3,496,492 a trace geometry, in the opposite one another Trace protrusions of the two lines to compensate for an otherwise predominantly inductive Serve coupling.

US-A-4,999,593 also discloses in Fig. 2 a Directional coupler whose coupling range is shorter than that of a conventional λ / 4-directional coupler. Between two sections of one of the lines of the coupling region is a meandering phase shift path inserted. From not explained in more detail Reasons are at both ends of the coupling area Condenser networks between the both lines and ground needed.

US 5,424,694 discloses a double in FIG Directional coupler, in which in a coupling region three ladders, one middle and two in addition parallel outer. The middle ladder is at one Signal input or output connected; a coupling between the two outer conductors over the middle away is not provided.

Another disadvantage of the known design principle is that the coupling lines 5, 6 respectively one at the operating frequency of the directional coupler form a resonant system. The resonant elevation the currents on the coupling lines leads to one compared to non-resonant line sections increased radiation and thus on the one hand to losses and on the other hand to a strong influence on the currents in the directional coupler through at the metallization of the opposite Substrate side reflected and phase-delayed the Coupling zone reaching fields. Since it was up to now Techniques to prevent or reduce radiation Missing, one tries, their disturbing influence to minimize by using the thinnest possible substrates, the only a relatively small phase shift between the streams in the coupling zone and bring about the fields reflected back into these fields. The mechanical sensitivity of these thin Substrates affect the durability of the they made couplers and the yield at their Production.

An object of the present invention is a Directional coupler with a novel design principle indicate the low consumption Substrate surface has a very large bandwidth or specify a use for a directional coupler, which allows with a directional coupler of small dimensions to achieve a large bandwidth.

Another object of the invention is a Directional coupler with reduced radiation to create.

These tasks are solved by a directional coupler with the features of claim 1. In directional coupler according to claim 1 has the in the coupling zone between the lines arranged, unconnected Conductor surface simply said the function a series connection of two capacitors, wherein a first capacitor through the first line and one of these facing edge of the unconnected Conductor surface and the second through the second line and one of these facing edge of the conductor surface is formed. This construction allows by varying the shape of the conductor surface the Coupling capacity between first and second line to vary widely, without this Changes in parasitic capacities in corresponding Scope are connected. That is, if the geometry of the first and second line and so that their magnetic coupling has been fixed is, it is possible by appropriate selection of the Shape of unconnected conductor surface the effective Coupling capacity between the first and second To vary the line to a large extent without whose shape or arrangement is changed for this purpose got to. This greatly simplifies the optimization the conductor geometry of the directional coupler.

Furthermore, in the directional coupler according to claim 1 each line consists of two rectilinear sections, the in the coupling zone forming an angle immediately meet, with the so spanned Angle a common bisector to have. Parallel coupling lines between input and output lines as shown in FIG. 1, be in such an inventive Directional coupler avoided. This is how the expansion of the Coupling zone and thus the dependence of the Behavior of the directional coupler from the input frequency minimized.

Preferably, the two lines of the Directional coupler outside the coupling zone in two mutually perpendicular directions. This will be legs mutual magnetic influence of the lines as far as possible outside the coupling zone locked out.

The sections of the lines of the directional coupler are in each case preferably in strip form with one the edges of the strip vertical end edge. This allows an arrangement in which the two sections of each line each with a Ekke overlap their end edge. By suitable Choice of the width of this overlap area can be a weakly inductive behavior of the first or second line can be achieved. Such Behavior is desirable to the capacitive Influence of unconnected conductor surface on the reflection behavior to balance the lines.

The unconnected conductor surface preferably has one square outline, especially with the end edges the strip-shaped line sections facing Edge.

It is known per se, a directional coupler symmetrical with respect to a first axis of symmetry, a reflection at the first axis of symmetry convicting each of the two lines, such a symmetrical, from the direction of propagation a signal on the first or second line independent behavior of the directional coupler to achieve. According to the invention, it is preferable that the conductor surface of two in each case the first or second lines facing, through a extending along the first axis of symmetry web-shaped conductor piece connected sections is constructed. This web-shaped conductor piece ensures that the presence of unconnected Conductor surface only the capacitive coupling between first and second lines, not but the inductive coupling affects. It runs preferably along the axis of symmetry.

The sections facing the first and second line, respectively are preferably L-shaped, in particular each having one of an end edge of a rectilinear one Line section opposite leg.

Fig. 1,

bereits diskutiert, eine Draufsicht auf einen herkömmlichen Richtkoppler;

Figs. 2 bis 4

jeweils Draufsichten auf Richtkoppler nach einem ersten bis dritten Ausführungsbeispiel der vorliegenden Erfindung;

Fig. 5

ein Smith-Diagramm der Reflexion einer einzelnen Leitung des Richtkopplers aus Fig. 4;

Fig. 6

Signalstärken an der zweiten Ausgangsleitung und der zweiten Eingangsleitung des Richtkopplers aus Fig. 4 bei Anregung über die erste Eingangsleitung für verschiedene Frequenzen des Anregungssignals; und

Fig. 7

ein Smith-Diagramm der erwünschten und der unerwünschten Kopplung des Richtkopplers aus Fig. 4.

Further features and advantages of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying figures. Show it:

Fig. 1,

already discussed, a plan view of a conventional directional coupler;

Figs. 2 to 4

respective plan views of directional coupler according to a first to third embodiment of the present invention;

Fig. 5

a Smith chart of the reflection of a single line of the directional coupler of Fig. 4;

Fig. 6

Signal strengths at the second output line and the second input line of the directional coupler of Figure 4 when excited via the first input line for different frequencies of the excitation signal. and

Fig. 7

a Smith chart of the desired and the unwanted coupling of the directional coupler of FIG. 4.

Fig. 2 illustrates the basic principle of the present invention with reference to a plan view of a first example of a directional coupler according to the invention. The directional coupler is composed of a substrate 10, for example of Al ₂ O ₃ , which has a metallization on its underside not shown in the figure and on its upper side two microstrip-generated lines 11, 12 and between them one with two lines 11, 12 unconnected conductor surface 20 carries. Parallel to each other, on both sides of the unconnected conductor surface 20 extending portions of the first and second lines 11, 12 are referred to as first and second coupling line 15 and 16; Together with the conductor surface 20, they form the coupling zone of the directional coupler.

The lines 11, 12 and the unconnected conductor surface 20 are in a same operation, through local application of metal or local removal a continuous metallization, formed and therefore have the same composition and Schichtdikke.

Straight line sections 13-1, 13-2, 13-3, 13-4 each extend from points 1, 2, 3, 4 the lines 11, 12 to one end of the coupling line 15 or 16.

Points 1 to 4 will be the next in the series after as first input terminal, first output terminal, second output terminal or second Input terminal, the distinction in between input and output connections Terminological nature is and no technical Differences implied. The names are up a randomly chosen propagation direction of a Signals related to the first line: when this via the first input terminal 1 in the Coupler enters and over the first output terminal 2 exit, so the decoupled Signal component appear at the second output terminal 3; possibly at the second input connection 4 appearing signal component is undesirable.

The connections 1 to 4 can, if the directional coupler formed on its own on the substrate 10 is, actual ends of the lines 11, 12 on be the substrate; if he works with other components integrated together on a substrate, it can around any points of a trace between the directional coupler and another component act.

The line section 13-1 is perpendicular to the Sections 13-2 and 13-3 as well as parallel to the section 13-4 oriented to a magnetic coupling of section 13-1 at 13-2 and 13-3. The lines 11, 12 go through reflection at a first line of symmetry 18 in itself itself over.

The second line 12 is relative to a second one Symmetry line 19, which is perpendicular to the first line of symmetry 18 runs in mirror image to the first Line 11 is formed.

Between facing, parallel edges the coupling lines 15, 16 extends, with this unconnected, the conductor surface 20. This couples Capacitive both to the first and the second line, with the strength of the capacitive Coupling significantly through the width of the column 21st between the conductor surface 20 and the coupling lines 15, 16 is determined. This construction allows for given geometry of the first and second coupling lines 15, 16 and thus given magnetic coupling the capacitive coupling between the lines by varying the Width of column 21 to a large extent to change without this with a change of shape and Position of the first and second lines 11 to 16 must be connected, and consequently without an essential one Change of the parasitics acting on this line Capacities.

To prevent in the unconnected conductor surface 20 in the longitudinal direction or along the second line of symmetry 19 induced currents as well the magnetic coupling between coupling lines 15, 16, according to a not in a further development shown useful be, the conductor surface 20 in a plurality of each other unconnected, in the longitudinal direction subdivide successive individual surfaces.

The capacitive coupling is in the construction of Fig. 2 over the entire length of each other parallel coupling conductor 15, 16 evenly distributed and as strong as the magnetic coupling. To be efficient with such an arrangement to achieve capacitive coupling in which not the contributions of different sections of the It is mutually canceling coupling lines desirable, the length of the coupling lines so to reduce as much as possible. The length of the coupling lines 15, 16 is therefore in any case significantly smaller than λ1 / 4, when λ1 is the shorter of two wavelengths λ1, λ2, each of the upper and lower limit frequency of a frequency band correspond, in which the coupler is effective.

On the one hand the brevity of the coupling zone and on the other hand the same strength of the magnetic and the capacitive coupling make sure that within the frequency band in which the coupler is effective is to build up no resonances in the coupling zone can. There is therefore no resonant current increase in the coupling zone, and consequently the radiation is low. The behavior of the Directional coupler is therefore only slightly radiated by and at the metallization on the opposite Substrate side influenced fields. Therefore, a larger phase shift can occur between the in the coupling zone on one the lines 11 or 12 fed signal and these reflected fields in the coupling zone be accepted, as in the above-described conventional design principle.

This allows the use of the invention Directional coupler on comparatively thick, stable Substrates made easily and in good yield can be, or at a given substrate thickness an operation of the directional coupler at comparatively high frequencies.

An evolved design that has the advantages the embodiment shown above and others is shown in Fig. 3. Here is the Length of the coupling lines reduced to zero. The rectilinear sections 13-1 and 13-2 of the first Line 11 and 13-3, 13-4 of the second line 12 each meet directly at right angles at the first line of symmetry 18 on each other. The Lines 13-1 to 13-4 each have the form of Strips with parallel longitudinal edges and one to the longitudinal edges vertical end edge 14, and they overlap each other in the area of a Ekke the end edge, as the example of the first line 11 shown as a dashed square 22. The Unconnected conductor surface 20 'has the shape here a square, each parallel to the end edges 14 Edge.

As in this embodiment, the length of the coupling zone is minimized, here is a breakdown the conductor surface 20 'in several sub-areas along the line of symmetry 19 no additional suppression of magnetic coupling across the conductor surface 20 'to be expected; rather, it is to be assumed that such a division here is the magnetic Coupling promotes.

Another improvement is on the top view of Fig. 4 shown. Here is the square conductor surface 20 'replaced by a conductor surface 20 ", which has a substantially square outline, but made up of three sections 23 ", 24", 25 " composed. The sections 23 ", 24" are respectively essentially L-shaped, with legs of equal length, the end edges 14 of the straight line sections 13-1, 13-2, 13-3, 13-4 facing are. The section 25 "has the shape of an elongated Bridge and connect the vertices the L-shaped sections 23 ", 24" along the first Line of symmetry 18. By one on the first Line 11 propagating signal in the facing L-shaped section 23 "induced charges broad so over the bridge 25 "along the line of symmetry 18 to the second L-shaped section 24 " and thus capacitively couple to the second line 12. Any current flows on the conductor surface 20 " transverse to the line of symmetry 18, which is a magnetic Coupling between the first and second lines 11, 12 could correspond across the conductor surface 20 ", are suppressed by their shape.

• Substratmaterial und Dicke.
  Diese Parameter sind im wesentlichen für die maximale Arbeitsfrequenz relevant, bei der der Koppler eingesetzt werden soll. Generell sind zur Verringerung von Abstrahlung geringe Substratdicken bevorzugt. Bei Arbeitsfrequenzen bis zu 30 GHz ist ein Aluminiumoxidsubstrat mit einer Dicke von 381 µm geeignet. Bei Frequenzen oberhalb 30 GHz ist eine Dicke von 254 µm bevorzugt.
• Breite der Leitungen.
  Die Breite a der Leitungen 11 bis 14 ist im wesentlichen relevant für die Leitungsimpedanz des Systems. Für eine Impedanz der Leitungen 11 bis 14 von 50 Ω ist eine Breite a von 340 µm optimal.
• Breite b der Überschneidungszone 22.
  Dieser Parameter beeinflußt das Reflexionsverhalten der Leitungen. Je kleiner b ist, um so stärker induktiv ist das Reflexionsverhalten. Es ist wünschenswert, wenn die zwei Leitungen 11, 12, betrachtet ohne die Leiterfläche 20 und die jeweils andere Leitung 12 bzw. 11, schwach induktives Verhalten aufweisen, wie im Smith-Diagramm von Fig. 5 für die erste Eingangsleitung dargestellt. Die Reflexion S(1,1) am Eingang der ersten Leitung ist im betrachteten Frequenzbereich von 19 bis 27 GHz praktisch unveränderlich. Das schwach induktive Verhalten der Reflexion S(1,1) wird beim vollständigen Richtkoppler durch den kapazitiven Beitrag der Leiterfläche 20 im wesentlichen kompensiert, so daß insgesamt minimale Reflexion erreicht wird.
• minimaler Abstand zwischen ersten und zweiten Leitungen.
  Der Abstand c zwischen einander zugewandten Ecken der Endkanten 22 der ersten und zweiten Leitungen 11, 12 hat offensichtlich Einfluß auf die Stärke der Kopplung zwischen diesen Leitungen. Er wird vorzugsweise so gewählt, daß die rechnerische Simulation eines Richtkopplers, der nur aus erster und zweiter Leitung 11, 12, ohne die unverbundene Leiterfläche 20, besteht, eine Kopplung zwischen der ersten und zweiten Leitung ergibt, die um ca. 5 dB geringer als die gewünschte Kopplung ist. Fügt man die unverbundene Leiterfläche 20" ein, um gleich starke magnetische und kapazitive Kopplungen zu erhalten, so erhöht sich die Kopplung insgesamt um etwa 5dB.

For example, to construct a directional coupler having the geometry shown in FIG. 4 for a given frequency band, the following parameters can be optimized:

• Substrate material and thickness.
  These parameters are essentially relevant to the maximum operating frequency at which the coupler is to be used. In general, low substrate thicknesses are preferred for reducing radiation. At working frequencies up to 30 GHz, an aluminum oxide substrate with a thickness of 381 μm is suitable. At frequencies above 30 GHz, a thickness of 254 μm is preferred.
• Width of the lines.
  The width a of the lines 11 to 14 is substantially relevant to the line impedance of the system. For an impedance of the lines 11 to 14 of 50 Ω a width a of 340 microns is optimal.
• Width b of the intersection zone 22.
  This parameter influences the reflection behavior of the lines. The smaller b is, the more inductive is the reflection behavior. It is desirable if the two lines 11, 12, viewed without the conductor surface 20 and the respective other line 12 or 11, have weakly inductive behavior, as shown in the Smith diagram of Fig. 5 for the first input line. The reflection S (1,1) at the input of the first line is practically invariable in the considered frequency range from 19 to 27 GHz. The weakly inductive behavior of the reflection S (1,1) is substantially compensated by the capacitive contribution of the conductor surface 20 in the case of the complete directional coupler, so that overall minimal reflection is achieved.
• minimum distance between first and second lines.
  The distance c between facing corners of the end edges 22 of the first and second lines 11, 12 obviously affects the strength of the coupling between these lines. It is preferably chosen so that the computational simulation of a directional coupler, consisting only of first and second line 11, 12, without the unconnected conductor surface 20, results in a coupling between the first and second line, which by about 5 dB less than the desired coupling is. Inserting the unconnected conductor surface 20 "in order to obtain equal magnetic and capacitive couplings, the total coupling increases by about 5 dB.

A fine adjustment of the capacitive coupling can by optimizing the width e of the legs of the L-shaped Sections as well as the width d of the column between the L-shaped sections 23 ", 24" and the end edges 22 of the lines can be achieved.

a = 340 µm

b = 31 µm

c = 116 µm

d = 30 µm

e = 30 µm

An example of a favorable set of the various geometric parameters is:

a = 340 μm

b = 31 μm

c = 116 μm

d = 30 μm

e = 30 μm

Figs. Figures 6 and 7 show each for different signal frequencies the strength S (1,3) of the desired, from the first input terminal 1 to the second output terminal 3 transmitted signal and S (1,4) of the unwanted, at the second input terminal 4 appearing signal for a directional coupler with the specified values of the parameters a to e. you recognizes an excellent directionality with a Level difference of over 20 dB between the two Signals S (1,3) and S (1,4) throughout the examined Frequency range from 19 to 27 GHz. The phase drift of the signal at the second output terminal 3 in FIG Dependence on the frequency is low, like that Smith chart of Fig. 7 shows.

In summary, the present invention provides an extremely compact directional coupler with large Bandwidth and excellent directionality. While with conventional directional couplers extremely thin Substrates must be used even at high Operating frequencies satisfactory directionality can be achieved in the context of the present invention relatively thick substrates are used what the durability of the coupler and also the yield Improved in mass production and thereby Cost reduced.

Claims (8)

1. A directional coupler having a substrate and, arranged on said substrate, two first ports (1, 2) connected by a first line (11) and two second ports (3, 4) connected by a second line (12), wherein the lines (11, 12) extend through a coupling zone and are separated in the coupling zone by an unconnected conductor area (20, 20', 20"), characterized in that an out-coupled portion of a signal supplied to one of the first ports (1, 2) appears at one of the second ports (3, 4).
2. A directional coupler according to claim 1, characterized in that the lines (11, 12) extend in mutually perpendicular directions outside the coupling zone.
3. A directional coupler according to claim 1 or 2, characterized in that each line (11; 12) comprises two straight sections (13-1, 13-2; 13-3, 13-4) meeting each other in the coupling zone at an angle, the bisectrix (18) being the same for the angles of both lines (11, 12).
4. A directional coupler according to claim 3, characterized in that the sections (13-1, 13-2, 13-3, 13-4) are in the form of strips having an end edge (14) perpendicular to the borders of the strips, and that the two sections (13-1, 13-2; 13-3, 13-4) of each line (11, 12) intersect at a corner of their end edge (14).
5. A directional coupler according to one of the preceding claims, characterized in that the conductor area (20', 20") has a square outline.
6. A directional coupler according to one of the preceding claims, characterized in that the conductor area (20") is formed of two sections (23", 24") facing the first and second lines, respectively and connected by a land-shaped conductor section (25'').
7. A directional coupler according to claim 6, characterized in that it has a first symmetry axis (18), wherein a specular reflection at the first symmetry axis (18) transforms each line (11, 12) into itself, and that the land-shaped conductor section (25") extends along the symmetry axis.
8. A directional coupler according to claim 7 or claim 8, characterized in that the sections (23", 24") are L-shaped.

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