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EP0108003A1 - Double strip line resonators and filter using such resonators - Google Patents

Double strip line resonators and filter using such resonators Download PDF

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Publication number
EP0108003A1
EP0108003A1 EP83402026A EP83402026A EP0108003A1 EP 0108003 A1 EP0108003 A1 EP 0108003A1 EP 83402026 A EP83402026 A EP 83402026A EP 83402026 A EP83402026 A EP 83402026A EP 0108003 A1 EP0108003 A1 EP 0108003A1
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Prior art keywords
resonators
resonator
filter
dielectric
faces
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EP83402026A
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German (de)
French (fr)
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EP0108003B1 (en
Inventor
Jean-Claude Mage
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Thales SA
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Thomson CSF SA
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/201Filters for transverse electromagnetic waves
    • H01P1/203Strip line filters
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P1/00Auxiliary devices
    • H01P1/20Frequency-selective devices, e.g. filters
    • H01P1/207Hollow waveguide filters
    • H01P1/208Cascaded cavities; Cascaded resonators inside a hollow waveguide structure
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P7/00Resonators of the waveguide type
    • H01P7/08Strip line resonators
    • H01P7/082Microstripline resonators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P7/00Resonators of the waveguide type
    • H01P7/08Strip line resonators
    • H01P7/084Triplate line resonators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01PWAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
    • H01P7/00Resonators of the waveguide type
    • H01P7/10Dielectric resonators

Definitions

  • the present invention relates to a type of electromagnetic resonator, which can be called a "two-band resonator", as well as the high frequency filters produced from these resonators.
  • the resonators and filters produced from these elements often consist of line sections.
  • These can be air coaxial lines or coaxial lines loaded with dielectric as mentioned in the article: "Bandpass filter with dielectric materials used for broadcasting channel filter” by K. WAKINO and Y. KONISHI published in the review I.E.E.E. Transactions on Broadcasting, vol. BC-26, N ° 1, March 1980. It is also known to manufacture resonators and filters from microstrip lines as the article indicates: "750 MHz microstrip bandpass filter on barium tetratitanate substrate" by G. OHM and G. SCHMOLLER published in the review Electronics Letters, vol. 18, No. 15 of July 22, 1982.
  • the coaxial line technique allows the manufacture of independent resonators whose natural frequencies can be adjusted before their assembly to form filters.
  • This assembly can be carried out in the case of a bandpass filter by placing the various resonators end to end, the couplings between two sections of consecutive lines being determined by the distances which separate their faces placed opposite.
  • overvoltage coefficients greater than 500
  • a silver-plated 20 mm diameter resonator can have an overvoltage coefficient Q greater than 1000 for a frequency of 1 GHz.
  • the coupling of quarter-wave resonators remains delicate and the very realization of the coaxial structure is quite complex because of the different operations of machining and metallization of elements with circular section.
  • Resonators can be designed using the microstrip line technique. They are generally produced from a relatively large dielectric substrate, one face of which is entirely metallized and of which the other receives a metallic conductor in the form of a thin ribbon. This technique has two drawbacks. On the one hand, the inherent overvoltage coefficients Q of the resonators are always low (less than 500) and consequently the performance of filters formed from these resonators is always modest (high insertion losses, greater than 3 dB towards 1 GHz). On the other hand, once the filter has been produced, by depositing ribbons on the same substrate, it is practically impossible to adjust the natural frequencies of the resonators as well as their mutual couplings. This prohibits the industrial production of filters comprising a high number of poles due to the inevitable dispersions of the characteristics: in particular, the dielectric constant of the substrate.
  • the invention proposes to produce resonators from a parallelepiped made of dielectric material.
  • a line is produced by metallizing two opposite faces of the parallelepiped and a resonator or along the length and termination of the line.
  • the subject of the invention is therefore a resonator comprising a section of line with distributed constants along which a steady state of transverse electromagnetic waves is established, said section comprising two conductive elements separated by a dielectric medium; characterized in that said medium is formed by a dielectric solid with six faces, at most four of said faces being entirely covered by a metallization and two other non-covered faces being opposite to each other.
  • the invention also relates to a high-frequency filter comprising at least one resonator according to the invention.
  • FIG. 1 shows a waveguide called microstrip line (microstrip line in English).
  • This line is formed by a flat dielectric substrate 1 covered on its underside with a metallization 2.
  • the opposite face of the substrate receives a conductive tape 3.
  • This solid can be a parallelepiped.
  • Metallizations 5 and 6 cover two opposite faces of the dielectric.
  • the bi-ribbon line has two similar electrodes.
  • a resonator is shown in Figure 4. It is formed by a bi-ribbon line defined by a dielectric bar 12, metallizations 13 and 14 and a short circuit 15 caused by the metallization of one of the ends of the bar. Its length L is equal to .
  • an appropriate dielectric In order to have temperature stable resonators, it is advantageous to choose an appropriate dielectric.
  • a material such as those which were the subject of the patent of the Applicant n ° 80.04 601 filed on February 29, 1980. These materials have relative molar proportions t Ti 0 2 , x Sn 0 2 , y Zr 0 2 , a Ni 0, b La 2 0 3 and c Fe where the parameters t, x, y, a, b and c satisfy the following inequalities:
  • resonators are typically intended for the production of band-pass and band-cut filters in the UHF range. They can also be used to stabilize oscillators. Examples of filters in the vicinity of 1 GHz are presented below. They can be easily transposed to other frequencies and can be made indifferently using resonators or .
  • Figure 5 is a top view of the housing from which the cover has been removed. A cut was made at the holes 25 and 26 for input and output of the signal. The hole 25 allows the passage of a conductor 27 which forms a coupling loop 29, serving as excitation means, with the resonator 20. The end of the conductor 27 is then connected to the housing.
  • the device allowing the output of the signal is similarly constituted by a conductor 28 which forms a loop 30, which serves as collecting means, at the level of the resonator 23 and the end of which is connected to ground.
  • the bottom of the housing is covered with an insulating substrate 31 which has, for example, a very low dielectric constant.
  • the resonators are fixed to the substrate 31, for example by gluing.
  • the metallizations of the quarter wave resonators are respectively mutually parallel and perpendicular to the substrate as shown in FIG. 5.
  • the coupling between resonators is made by mutual inductance.
  • the natural frequencies of each resonator have been previously adjusted either by manufacturing or by running in. The development of the filter is then greatly facilitated.
  • We can also separate the resonators by spacers made of dielectric material of low dielectric constant. The distances between each resonator can be of the order of edge a.
  • FIG. 6 is a sectional view of the filter shown in Figure 5, the section being taken along AA.
  • a metal cover 32 closes the housing and helps to shield the filter from external influences. It can be fixed to the housing by screws not shown. In order to make fine adjustments to the couplings between resonators, it is possible to place adjustment screws along axes 33, 34 and 35. These screws, located between the resonators, modify the electromagnetic field, depending on the state of their depression. reigns between the resonators.
  • FIG. 8 shows such a filter.
  • the housing was cut as in FIG. 5.
  • the housing 50 is recognized on which a cover, not shown, is fixed.
  • the bottom of the housing is covered with a substrate 51 of dielectric material of low dielectric constant.
  • the filter includes 3 quarter-wave resonators 52, 53 and 54, holes 55 and 56 which allow the passage of a signal input conductor 57 and an output conductor 58, a line 59 which can be l soul of a coaxial line.
  • the housing and its cover are connected to the ground.
  • the distances separating the resonators from each other and between the line 59 are of the order of magnitude of the edge a. It is also possible to obtain with this kind of filters an adjustment of the couplings by the presence of screws modifying the electromagnetic field between the resonators.
  • the band-cut and band-pass filters produced using quarter-wave resonators exhibit a first spurious response at a frequency substantially triple their operating frequency.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Control Of Motors That Do Not Use Commutators (AREA)
  • Waveguides (AREA)

Abstract

L'invention se rapport aux résonateurs électromagnétiques et aux filtres hautes fréquences réalisés à partir de ces résonateurs. L'invention a pour objet de recouvrir un parallélépipède en matériau diélectrique (4) d'au moins deux métallisations (5 et 6) disposées parallèlement à la direction de déplacement d'une onde électromagnétique. L'invention s'applique à la réalisation de résonateurs quart d'onde ou demi-onde ainsi qu'aux filtres passe-band ou coupe-bande.The invention relates to electromagnetic resonators and to high frequency filters produced from these resonators. The object of the invention is to cover a parallelepiped of dielectric material (4) with at least two metallizations (5 and 6) arranged parallel to the direction of movement of an electromagnetic wave. The invention applies to the production of quarter-wave or half-wave resonators as well as to band-pass or band-cut filters.

Description

La présente invention concerne un type de résonateur électromagnétique, que l'on peut appeler "résonateur bi-ruban", ainsi que les filtres hautes fréquences réalisés à partir de ces résonateurs.The present invention relates to a type of electromagnetic resonator, which can be called a "two-band resonator", as well as the high frequency filters produced from these resonators.

Dans la gamme des fréquences élevées appelée UHF (pratiquement de 300 MHz à 3 Ghz), les résonateurs et les filtres réalisés à partir de ces éléments sont souvent constitués de tronçons de lignes. Il peut s'agir de lignes coaxiales à air ou de lignes coaxiales chargées de diélectrique telles que mentionnées dans l'article : "Bandpass filter with dielectric materials used for broadcasting channel filter" de K. WAKINO et Y. KONISHI paru dans la revue I.E.E.E. Transactions on Broadcasting, vol. BC-26, N° 1, Mars 1980. Il est connu aussi de fabriquer des résonateurs et des filtres à partir de lignes microrubans comme l'indique l'article : "750 MHz microstrip bandpass filter on barium tetratitanate substrate " de G. OHM et G. SCHMOLLER paru dans la revue Electronics Letters, vol. 18, N° 15 du 22 Juillet 1982.In the high frequency range called UHF (practically from 300 MHz to 3 Ghz), the resonators and filters produced from these elements often consist of line sections. These can be air coaxial lines or coaxial lines loaded with dielectric as mentioned in the article: "Bandpass filter with dielectric materials used for broadcasting channel filter" by K. WAKINO and Y. KONISHI published in the review I.E.E.E. Transactions on Broadcasting, vol. BC-26, N ° 1, March 1980. It is also known to manufacture resonators and filters from microstrip lines as the article indicates: "750 MHz microstrip bandpass filter on barium tetratitanate substrate" by G. OHM and G. SCHMOLLER published in the review Electronics Letters, vol. 18, No. 15 of July 22, 1982.

La technique des lignes coaxiales autorise la fabrication de résonateurs indépendants dont les fréquences propres peuvent être ajustées avant leur assemblage pour former des filtres. Cet assemblage peut être réalisé dans le cas d'un filtre passe-bande en plaçant les différents résonateurs bout à bout, les couplages entre deux tronçons de lignes consécutifs étant déterminés par les distances qui séparent leurs faces placées en vis-à-vis. Cependant, pour obtenir des coefficients de surtension intéressants (supérieurs à 500) il faut disposer de tronçons ayant une section assez importante. Typiquement un résonateur de diamètre de 20 mm métallisé à l'argent peut avoir un coefficient de surtension Q supérieur à 1000 pour une fréquence de 1 GHz. En outre, le couplage des résonateurs quart d'onde demeure délicat et la réalisation même de la structure coaxiale est assez complexe à cause des différentes opérations d'usinage et de métallisation d'éléments à section circulaire.The coaxial line technique allows the manufacture of independent resonators whose natural frequencies can be adjusted before their assembly to form filters. This assembly can be carried out in the case of a bandpass filter by placing the various resonators end to end, the couplings between two sections of consecutive lines being determined by the distances which separate their faces placed opposite. However, to obtain interesting overvoltage coefficients (greater than 500) it is necessary to have sections having a fairly large section. Typically, a silver-plated 20 mm diameter resonator can have an overvoltage coefficient Q greater than 1000 for a frequency of 1 GHz. In addition, the coupling of quarter-wave resonators remains delicate and the very realization of the coaxial structure is quite complex because of the different operations of machining and metallization of elements with circular section.

Des résonateurs peuvent être conçus selon la technique des lignes microrubans. Ils sont généralement réalisés à partir d'un substrat diélectrique relativement large dont une face est entièrement métallisée et dont l'autre reçoit un conducteur métallique sous la forme d'un mince ruban. Cette technique présente deux inconvénients. D'une part, les coefficients de surtension propres Q des résonateurs sont toujours faibles (inférieur à 500) et par conséquent les performances de filtres formés à partir de ces résonateurs sont toujours modestes (pertes d'insertion élevées, supérieures à 3 dB vers 1 GHz). D'autre part, une fois le filtre réalisé, par dépôt de rubans sur un même substrat, il est pratiquement impossible d'ajuster les fréquences propres des résonateurs ainsi que leurs couplages mutuels. Ceci interdit la réalisation industrielle de filtres comportant un nombre de pôles élevé en raison des inévitables dispersions des caractéristiques : en particulier, de la constante diélectrique du substrat.Resonators can be designed using the microstrip line technique. They are generally produced from a relatively large dielectric substrate, one face of which is entirely metallized and of which the other receives a metallic conductor in the form of a thin ribbon. This technique has two drawbacks. On the one hand, the inherent overvoltage coefficients Q of the resonators are always low (less than 500) and consequently the performance of filters formed from these resonators is always modest (high insertion losses, greater than 3 dB towards 1 GHz). On the other hand, once the filter has been produced, by depositing ribbons on the same substrate, it is practically impossible to adjust the natural frequencies of the resonators as well as their mutual couplings. This prohibits the industrial production of filters comprising a high number of poles due to the inevitable dispersions of the characteristics: in particular, the dielectric constant of the substrate.

Afin de pallier ces inconvénients, l'invention propose de réaliser des résonateurs à partir d'un parallélépipède constitué de matériau diélectrique. On réalise une ligne en métallisant deux faces opposées du parallélépipède et un résonateur

Figure imgb0001
ou
Figure imgb0002
suivant la longueur et la terminaison de la ligne.In order to overcome these drawbacks, the invention proposes to produce resonators from a parallelepiped made of dielectric material. A line is produced by metallizing two opposite faces of the parallelepiped and a resonator
Figure imgb0001
 or
Figure imgb0002
 along the length and termination of the line.

L'invention a donc pour objet un résonateur comportant un tronçon de ligne à constantes réparties le long duquel s'établit un régime stationnaire d'ondes transverses électromagnétiques, ledit tronçon comportant deux éléments conducteurs séparés par un milieu diélectrique ; caractérisé en ce que ledit milieu est formé par un solide diélectrique à six faces, quatre au plus desdites faces étant entièrement recouvertes par une métallisation et deux autres faces non recouvertes étant opposées l'une à l'autre.The subject of the invention is therefore a resonator comprising a section of line with distributed constants along which a steady state of transverse electromagnetic waves is established, said section comprising two conductive elements separated by a dielectric medium; characterized in that said medium is formed by a dielectric solid with six faces, at most four of said faces being entirely covered by a metallization and two other non-covered faces being opposite to each other.

L'invention a aussi pour objet un filtre haute-fréquence comprenant au moins un résonateur selon l'invention.The invention also relates to a high-frequency filter comprising at least one resonator according to the invention.

L'invention sera mieux comprise et d'autres avantages apparaîtront au cours de la description qui va suivre et des figures annexées parmi lesquelles :

  • - la figure 1 représente une ligne microruban ;
  • - les figures 2 et 3 représentent des résonateurs demi-onde selon l'invention ;
  • - la figure 4 représente un résonateur quart d'onde selon l'invention ;
  • - les figures 5 et 6 représentent un filtre passe-bande selon l'invention ;
  • - la figure 7 est un diagramme donnant la réponse d'un filtre passe-bande ;
  • - la figure 8 représente un filtre coupe-bande selon l'invention.
The invention will be better understood and other advantages will appear during the description which follows and from the appended figures among which:
  • - Figure 1 shows a microstrip line;
  • - Figures 2 and 3 show half-wave resonators according to the invention;
  • - Figure 4 shows a quarter wave resonator according to the invention;
  • - Figures 5 and 6 show a bandpass filter according to the invention;
  • - Figure 7 is a diagram giving the response of a bandpass filter;
  • - Figure 8 shows a notch filter according to the invention.

La figure 1 représente un guide d'onde que l'on appelle ligne microruban (microstrip line en anglais). Cette ligne est constituée par un substrat diélectrique plan 1 recouvert sur sa face inférieure d'une métallisation 2. La face opposée du substrat reçoit un ruban conducteur 3. C'est une technique de réalisation de guide d'onde assez connue. On peut envisager des guides d'onde réalisés par la métallisation de deux faces d'un solide diélectrique à six faces et se présentant différemment. C'est l'objet de la figure 2. Ce solide peut être un parallélépipède. Sur cette figure, on remarque un parallélépipède 4 en matériau diélectrique ayant une section rectangulaire de côtés a et b. Des métallisations 5 et 6 recouvrent deux faces opposées du diélectrique. A l'inverse de la ligne microruban, la ligne bi-ruban présente deux électrodes semblables. Le côté a est la distance qui sépare les deux électrodes 5 et 6. Une telle ligne propage des ondes électromagnétiques avec un indice efficace n =

Figure imgb0003
. λ o représente la longueur d'onde dans le vide et À g la longueur d'onde dans le guide bi-ruban. Cet indice dépend de la constante diélectrique du matériau et de la géométrie de la ligne. Ainsi, en utilisant un barreau de diélectrique en tétratitanate de baryum Ba Ti4 09 de constante diélectrique 37, et de dimensions a et b comprises entre 5 et 10 mm, on obtient, pour 1 GHz, n = 4,7.Figure 1 shows a waveguide called microstrip line (microstrip line in English). This line is formed by a flat dielectric substrate 1 covered on its underside with a metallization 2. The opposite face of the substrate receives a conductive tape 3. This is a fairly well-known technique for producing a waveguide. One can envisage waveguides produced by the metallization of two faces of a dielectric solid with six faces and having a different appearance. This is the object of FIG. 2. This solid can be a parallelepiped. In this figure, there is a parallelepiped 4 of dielectric material having a rectangular section with sides a and b. Metallizations 5 and 6 cover two opposite faces of the dielectric. Unlike the microstrip line, the bi-ribbon line has two similar electrodes. Side a is the distance between the two electrodes 5 and 6. Such a line propagates electromagnetic waves with an effective index n =
Figure imgb0003
 . λ o represents the wavelength in vacuum and À g the wavelength in the twin-ribbon guide. This index depends on the dielectric constant of the material and the geometry of the line. Thus, using a barium tetratitanate barium dielectric bar Ba Ti 4 0 9 of dielectric constant 37, and of dimensions a and b between 5 and 10 mm, we obtain, for 1 GHz, n = 4.7.

Une telle ligne peut présenter des fréquences de résonance propres suivant que la valeur de sa longueur L est un multiple pair ou impair de

Figure imgb0004
et selon les conditions aux limites. Dans la pratique, on s'intéressera au deux cas suivants :

  • - résonateur demi-onde :
    Figure imgb0005
  • - résonateur quart d'onde :
    Figure imgb0006
Such a line can have natural resonant frequencies depending on whether the value of its length L is an even or odd multiple of
Figure imgb0004
 and according to the boundary conditions. In practice, we will focus on the following two cases:
  • - half-wave resonator:
    Figure imgb0005
  • - quarter wave resonator:
    Figure imgb0006

Des résonateurs demi-onde peuvent se présenter comme le montre la figure 2, c'est-à-dire en circuit ouvert, avec L =

Figure imgb0007
. Ils peuvent aussi être du type représenté à la figure 3. On voit sur cette figure un guide d'onde bi-ruban formé par un barreau diélectrique 7 recouvert sur deux de ses faces de dépôts métalliques 8 et 9. Les conditions aux limites : métallisations des extrémités 10 et 11 en font un résonateur
Figure imgb0008
pour
Figure imgb0009
 Half-wave resonators can be present as shown in FIG. 2, that is to say in open circuit, with L =
Figure imgb0007
 . They can also be of the type shown in Figure 3. We see in this figure a guide bi-ribbon wave formed by a dielectric bar 7 covered on two of its faces with metal deposits 8 and 9. The boundary conditions: metallizations of the ends 10 and 11 make it a resonator
Figure imgb0008
 for
Figure imgb0009

Un résonateur

Figure imgb0010
est représenté à la figure 4. Il est formé par une ligne bi-ruban définie par un barreau diélectrique 12, des métallisations 13 et 14 et un court-circuit 15 provoqué par la métallisation de l'un des bouts du barreau. Sa longueur L est égale à
Figure imgb0011
.A resonator
Figure imgb0010
 is shown in Figure 4. It is formed by a bi-ribbon line defined by a dielectric bar 12, metallizations 13 and 14 and a short circuit 15 caused by the metallization of one of the ends of the bar. Its length L is equal to
Figure imgb0011
 .

En utilisant un matériau de constante diélectrique 37 et des métallisations réalisées en argent sérigraphié, on obtient les résultats résumés dans le tableau 1. Les mesures ont été effectuées sur des résonateurs à section carrée (a = b) de type

Figure imgb0012
et
Figure imgb0013
. Le tableau 1 donne également les valeurs de la fréquence de résonance fo, du coefficient de surtension Q à la résonance, du volume V pour chaque résonateur. En fait, ce qui est surtout important pour la section du barreau c'est la distance a qui sépare les métallisations.
Figure imgb0014
 Using a material of dielectric constant 37 and metallizations made of screen-printed silver, the results summarized in Table 1 are obtained. The measurements were carried out on square section resonators (a = b) of the type
Figure imgb0012
 and
Figure imgb0013
 . Table 1 also gives the values of the resonant frequency fo, of the overvoltage coefficient Q at the resonance, of the volume V for each resonator. In fact, what is especially important for the cross-section of the bar is the distance a which separates the metallizations.
Figure imgb0014

TABLEAU 1TABLE 1

On constate, à la lecture du tableau 1, que la surtension Q est proportionnelle à l'arête a et que à section constante, la surtension varie comme la racine carrée de la fréquence. On peut écrire Q = Ka√f, K étant un coefficient de proportionnalité. Si on considère le rapport surtension/volume du diélectrique, on constate que la structure bi-ruban permet d'obtenir des résonateurs ayant d'excellentes performances par rapport à leur encombrement. Pour une surtension et un volume donnés on peut choisir entre les deux types de résonateurs. Par exemple, les résonateurs 4 et 5 sont équivalents à ce point de vue.It can be seen from reading Table 1 that the overvoltage Q is proportional to the edge a and that, at constant section, the overvoltage varies as the square root of the frequency. We can write Q = Ka√f, K being a coefficient of proportionality. If we consider the overvoltage / volume ratio of the dielectric, we see that the dual-ribbon structure makes it possible to obtain resonators having excellent performance compared to their size. For a given overvoltage and volume, one can choose between the two types of resonators. For example, resonators 4 and 5 are equivalent from this point of view.

Afin de disposer de résonateurs stables en température, il est avantageux de choisir un diélectrique approprié. On peut par exemple utiliser un matériau tels que ceux qui ont fait l'objet du brevet de la Demanderesse n° 80.04 601 déposé le 29 Février 1980. Ces matériaux ont des proportions molaires relatives t Ti 02, x Sn 02, y Zr 02, a Ni 0, b La2 03 et c Fe où les paramètres t, x, y, a, b et c satisfont aux inégalités suivantes :

Figure imgb0015
Figure imgb0016
Figure imgb0017
 In order to have temperature stable resonators, it is advantageous to choose an appropriate dielectric. One can for example use a material such as those which were the subject of the patent of the Applicant n ° 80.04 601 filed on February 29, 1980. These materials have relative molar proportions t Ti 0 2 , x Sn 0 2 , y Zr 0 2 , a Ni 0, b La 2 0 3 and c Fe where the parameters t, x, y, a, b and c satisfy the following inequalities:
Figure imgb0015
Figure imgb0016
Figure imgb0017

Pour x voisin de 0,35 le coefficient de variation thermique s'annule. La constante diélectrique élevée (environ 37) de tels matériaux autorise une réduction de volume des résonateurs pour une longueur d'onde donnée.For x close to 0.35 the coefficient of thermal variation is zero. The high dielectric constant (around 37) of such materials allows a reduction in volume of the resonators for a given wavelength.

Ces résonateurs sont typiquement destinés à la réalisation de filtres passe-bande et coupe-bande dans la gamme UHF. Ils peuvent aussi servir à stabiliser des oscillateurs. Des exemples de réalisation de filtres au voisinage de 1 GHz sont présentés ci-dessous. Ils peuvent être aisément transposés à d'autres fréquences et peuvent être réalisés indifféremment à l'aide de résonateurs

Figure imgb0018
ou
Figure imgb0019
.These resonators are typically intended for the production of band-pass and band-cut filters in the UHF range. They can also be used to stabilize oscillators. Examples of filters in the vicinity of 1 GHz are presented below. They can be easily transposed to other frequencies and can be made indifferently using resonators
Figure imgb0018
 or
Figure imgb0019
 .

Pour la réalisation de filtres, le type de résonateurs, leur longueur et leur section doivent être choisis en fonction des performances requises.For the production of filters, the type of resonators, their length and their section must be chosen according to the required performance.

La figure 5 représente une réalisation d'un filtre passe-bande à quatre résonateurs 20, 21, 22 et 23. Ceux-ci correspondent par exemple au numéro 3 du tableau 1, soit a = b = 7 mm et de type

Figure imgb0020
. Ils sont disposés dans un boîtier 24 relié à la masse. La figure 5 est une vue de dessus du boîtier dont le couvercle a été ôté. Une coupe a été réalisée au niveau des trous 25 et 26 d'entrée et de sortie du signal. Le trou 25 permet le passage d'un conducteur 27 qui forme une boucle 29 de couplage, servant de moyens excitateurs, avec le résonateur 20. L'extrémité du conducteur 27 est ensuite reliée au boîtier. Le dispositif permettant la sortie du signal est constitué de façon similaire par un conducteur 28 qui forme une boucle 30, qui sert de moyens collecteurs, au niveau du résonateur 23 et dont l'extrémité est reliée à la masse. Le fond du boîtier est recouvert d'un substrat isolant 31 qui possède par exemple une très faible constante diélectrique. Les résonateurs sont fixés sur le substrat 31, par exemple par collage. Les métallisations des résonateurs quart d'onde sont respectivement parallèles entre elles et perpendiculaires au substrat comme l'indique la figure 5. Le couplage entre résonateurs se fait par inductance mutuelle. Les fréquences propres de chaque résonateur ont été au préalable ajustées soit par fabrication, soit par rodage. La mise au point du filtre est alors largement facilitée. On peut également séparer les résonateurs par des entretoises en matériau diélectrique de faible constante diélectrique. Les distances entre chaque résonateur peuvent être de l'ordre de l'arête a.FIG. 5 represents an embodiment of a bandpass filter with four resonators 20, 21, 22 and 23. These correspond for example to number 3 in Table 1, ie a = b = 7 mm and of type
Figure imgb0020
 . They are arranged in a housing 24 connected to ground. Figure 5 is a top view of the housing from which the cover has been removed. A cut was made at the holes 25 and 26 for input and output of the signal. The hole 25 allows the passage of a conductor 27 which forms a coupling loop 29, serving as excitation means, with the resonator 20. The end of the conductor 27 is then connected to the housing. The device allowing the output of the signal is similarly constituted by a conductor 28 which forms a loop 30, which serves as collecting means, at the level of the resonator 23 and the end of which is connected to ground. The bottom of the housing is covered with an insulating substrate 31 which has, for example, a very low dielectric constant. The resonators are fixed to the substrate 31, for example by gluing. The metallizations of the quarter wave resonators are respectively mutually parallel and perpendicular to the substrate as shown in FIG. 5. The coupling between resonators is made by mutual inductance. The natural frequencies of each resonator have been previously adjusted either by manufacturing or by running in. The development of the filter is then greatly facilitated. We can also separate the resonators by spacers made of dielectric material of low dielectric constant. The distances between each resonator can be of the order of edge a.

La figure 6 est une vue en coupe du filtre représenté à la figure 5, la coupe étant effectuée selon AA. Sur ces 2 figures, les mêmes références représentent les mêmes objets. Un couvercle métallique 32 ferme le boîtier et contribue à soustraire le filtre aux influences extérieures. Il peut être fixé au boîtier par des vis non représentées. Afin de procéder à des ajustements fins des couplages entre résonateurs, il est possible de placer des vis de réglage selon les axes 33, 34 et 35. Ces vis, situées entre les résonateurs, modifient suivant l'état de leur enfoncement le champ électromagnétique qui règne entre les résonateurs.Figure 6 is a sectional view of the filter shown in Figure 5, the section being taken along AA. In these 2 figures, the same references represent the same objects. A metal cover 32 closes the housing and helps to shield the filter from external influences. It can be fixed to the housing by screws not shown. In order to make fine adjustments to the couplings between resonators, it is possible to place adjustment screws along axes 33, 34 and 35. These screws, located between the resonators, modify the electromagnetic field, depending on the state of their depression. reigns between the resonators.

A titre d'exemple, on a relevé la courbe du coefficient |s21| de la matrice de diffusion en fonction de la fréquence f, c'est-à-dire l'allure de la réponse en fréquence du filtre passe-bande à quatre pôles décrit précédemment. C'est l'objet de la figure 7. La réponse en fréquence du filtre est représentée par la courbe 40. L'axe des ordonnées est gradué en décibels. La courbe présente un maximum et deux flancs assez raides qui définissent un filtre passe-bande. Le filtre est caractérisé par une fréquence centrale f , une bande passante B à x dB, l'ondulation que présente le maximum qui détermine une bande passante B , des pertes d'insertion. Les fréquences propres des résonateurs 20, 21, 22 et 23 sont respectivement 1060, 1080, 1080 et 1060 MHz. D'après le diagramme de la figure 7, on relève :

  • - des pertes d'insertion dans la gamme Bo inférieures ou égales à 2,5 dB,
  • - une fréquence centrale f = 1070 MHz,
  • - une ondulation dans la bande Bo ≤ 0,5 dB,
  • - la bande passante B = 24 MHz,
  • - les bandes passantes à 20 dB et 40 dB, B20 = 50 MHz et B40 = 90 MHz.
For example, the curve of the coefficient | s 21 | of the diffusion matrix as a function of the frequency f, that is to say the shape of the frequency response of the four-pole bandpass filter described above. This is the object of FIG. 7. The frequency response of the filter is represented by curve 40. The ordinate axis is graduated in decibels. The curve has a maximum and two fairly steep sides which define a bandpass filter. The filter is characterized by a central frequency f, a bandwidth B at x dB, the ripple presented by the maximum which determines a bandwidth B, insertion losses. The natural frequencies of the resonators 20, 21, 22 and 23 are respectively 1060, 1080, 1080 and 1060 MHz. From the diagram in Figure 7, we note:
  • - insertion losses in the B o range less than or equal to 2.5 dB,
  • - a central frequency f = 1070 MHz,
  • - ripple in the band B o ≤ 0.5 dB,
  • - bandwidth B = 24 MHz,
  • - the bandwidths at 20 dB and 40 dB, B 20 = 50 MHz and B 40 = 90 MHz.

Les mesures effectuées sur ce filtre donnent également |S11| dans Bo < 0,1.The measurements made on this filter also give | S 11 | in B o < 0 , 1 .

A titre comparatif, d'autres mesures ont été effectuées sur un filtre passe-bande comportant 3 résonateurs de configurations identiques aux précédents (a = b = 6 mm, h = 15 mm, e = 37) et de fréquences propres 1060 MHz pour le résonateur d'entrée, 1080 MHz pour celui du milieu et 1060 MHz pour celui de sortie. Les caractéristiques de ce filtre à 3 pôles sont alors : fo = 1070 MHz, Bo = 20 MHz, B20 = 50 MHz et B40 = 110 MHz. Le coefficient S11 de la matrice de diffusion est inférieur à 0,1.For comparison, other measurements were made on a bandpass filter comprising 3 resonators with configurations identical to previous (a = b = 6 mm, h = 15 mm, e = 37) and natural frequencies 1060 MHz for the input resonator, 1080 MHz for that of the medium and 1060 MHz for that of output. The characteristics of this 3-pole filter are then: f o = 1070 MHz, B o = 20 MHz, B 20 = 50 MHz and B 40 = 110 MHz. The coefficient S 11 of the diffusion matrix is less than 0.1.

Les résonateurs selon l'invention se prêtent également très bien à la réalisation de filtres coupe-bande. La figure 8 représente un tel filtre. La coupe du boîtier a été effectuée comme pour la figure 5. On reconnaît le boîtier 50 sur lequel se fixe un couvercle non représenté. Le fond du boîtier est recouvert d'un substrat 51 en matériau diélectrique de faible constante diélectrique. Le filtre comprend 3 résonateurs quart d'onde 52, 53 et 54, des trous 55 et 56 qui permettent le passage d'un conducteur 57 d'entrée du signal et d'un conducteur de sortie 58, une ligne 59 qui peut être l'âme d'une ligne coaxiale. Le boîtier ainsi que son couvercle sont réunis à la masse. Les distances séparant les résonateurs entre eux et entre la ligne 59 sont de l'ordre de grandeur de l'arête a. Il est également possible d'obtenir avec ce genre de filtres un réglage des couplages par la présence de vis modifiant le champ électromagnétique entre les résonateurs.The resonators according to the invention also lend themselves very well to the production of notch filters. Figure 8 shows such a filter. The housing was cut as in FIG. 5. The housing 50 is recognized on which a cover, not shown, is fixed. The bottom of the housing is covered with a substrate 51 of dielectric material of low dielectric constant. The filter includes 3 quarter-wave resonators 52, 53 and 54, holes 55 and 56 which allow the passage of a signal input conductor 57 and an output conductor 58, a line 59 which can be l soul of a coaxial line. The housing and its cover are connected to the ground. The distances separating the resonators from each other and between the line 59 are of the order of magnitude of the edge a. It is also possible to obtain with this kind of filters an adjustment of the couplings by the presence of screws modifying the electromagnetic field between the resonators.

Les filtres coupe-bandes et passe-bandes réalisés à l'aide de résonateurs quart d'onde présentent une première réponse parasite à une fréquence sensiblement triple de leur fréquence de fonctionnement.The band-cut and band-pass filters produced using quarter-wave resonators exhibit a first spurious response at a frequency substantially triple their operating frequency.

Claims (8)

1. Résonateur comportant un tronçon de ligne à constantes réparties le long duquel s'établit un régime stationnaire d'ondes transverses électromagnétiques, ledit tronçon comportant deux éléments conducteurs séparés par un milieu diélectrique (4) ; caractérisé en ce que ledit milieu est formé par un solide diélectrique à six faces, quatre au plus desdites faces étant entièrement recouvertes par une métallisation (8, 9, 10 et 11) et deux autres faces non recouvertes étant opposées l'une à l'autre.1. Resonator comprising a section of line with distributed constants along which a steady state of transverse electromagnetic waves is established, said section comprising two conductive elements separated by a dielectric medium (4); characterized in that said medium is formed by a dielectric solid with six faces, at most four of said faces being completely covered by a metallization (8, 9, 10 and 11) and two other non-covered faces being opposite one to the other other. 2. Résonateur selon la revendication 1, caractérisé en ce que ledit solide est un parallélépipède.2. Resonator according to claim 1, characterized in that said solid is a parallelepiped. 3. Résonateur selon la revendication 2, caractérisé en ce que ledit parallélépipède est un parallélépipède rectangle.3. Resonator according to claim 2, characterized in that said parallelepiped is a rectangular parallelepiped. 4. Résonateur selon l'une quelconque des revendications 1 à 3, caractérisé en ce que ledit résonateur est du type demi-onde.4. Resonator according to any one of claims 1 to 3, characterized in that said resonator is of the half-wave type. 5. Résonateur selon l'une quelconque des revendications 1 à 3, caractérisé en ce que ledit résonateur est du type quart d'onde.5. Resonator according to any one of claims 1 to 3, characterized in that said resonator is of the quarter wave type. 6. Filtre haute-fréquence, caractérisé en ce qu'il comprend au moins un résonateur électromagnétique selon l'une des revendications 1 à 5.6. High-frequency filter, characterized in that it comprises at least one electromagnetic resonator according to one of claims 1 to 5. 7. Filtre haute-fréquence selon la revendication 6, caractérisé en ce que lesdits résonateurs (20, 21, 22 et 23) sont agencés entre des moyens excitateurs (29) et collecteurs (30) constituant les bornes d'entrée et de sortie dudit filtre afin que l'énergie électromagnétique incidente soit filtrée successivement par lesdits résonateurs ; la présence desdits résonateurs produisant un filtre passe-bande.7. High frequency filter according to claim 6, characterized in that said resonators (20, 21, 22 and 23) are arranged between exciter means (29) and collectors (30) constituting the input and output terminals of said filters so that the incident electromagnetic energy is successively filtered by said resonators; the presence of said resonators producing a bandpass filter. 8. Filtre haute-fréquence selon la revendication 6, caractérisé en ce que lesdits résonateurs (52, 53 et 54) sont agencés pour prélever de l'énergie électromagnétique véhiculée par une ligne de propagation (59) reliant les bornes d'entrée et de sortie dudit filtre ; la présence desdits résonateurs produisant un filtre coupe-bande.8. High-frequency filter according to claim 6, characterized in that said resonators (52, 53 and 54) are arranged to take electromagnetic energy conveyed by a propagation line (59) connecting the input and output of said filter; the presence of said resonators producing a notch filter.
EP83402026A 1982-10-29 1983-10-18 Double strip line resonators and filter using such resonators Expired EP0108003B1 (en)

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FR8218236A FR2535547B1 (en) 1982-10-29 1982-10-29 BI-RIBBON RESONATORS AND FILTERS MADE FROM THESE RESONATORS
FR8218236 1982-10-29

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FR2565438A1 (en) * 1984-05-30 1985-12-06 Cepe DIELECTRIC FILTER WITH VARIABLE CENTRAL FREQUENCY.
FR2568414A1 (en) * 1984-05-25 1986-01-31 Thomson Csf ELECTROMAGNETIC RESONATORS AND FILTERS MADE THEREFROM THESE RESONATORS.
EP0187579A1 (en) * 1984-12-06 1986-07-16 Thomson-Csf Electromagnetic resonators and filters comprising such resonators
EP0547968A1 (en) * 1991-12-19 1993-06-23 Commissariat A L'energie Atomique Measuring system for dielectric and magnetic properties of materials
RU2784658C1 (en) * 2022-04-11 2022-11-29 Федеральное государственное бюджетное научное учреждение "Федеральный исследовательский центр "Красноярский научный центр Сибирского отделения Российской академии наук" (ФИЦ КНЦ СО РАН, КНЦ СО РАН) Strip frequency doubler

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US4751481A (en) * 1986-12-29 1988-06-14 Motorola, Inc. Molded resonator
US4908589A (en) * 1987-09-21 1990-03-13 Hughes Aircraft Company Dielectrically loaded waveguide switch
DE69122748T2 (en) * 1990-12-26 1997-05-07 Tdk Corp HIGH FREQUENCY DEVICE
FI88440C (en) * 1991-06-25 1993-05-10 Lk Products Oy Ceramic filter
US5290740A (en) * 1991-11-06 1994-03-01 Ngk Insulators, Ltd. Dielectric ceramic composition used for producing dielectric resonator or filter for microwave application
FI95515C (en) * 1993-11-01 1996-02-12 Solitra Oy Resonator construction with point-distributed circuit constant and a method for controlling a resonator construction with point-distributed circuit constant
KR100323895B1 (en) * 1994-03-31 2002-06-24 이또시로 Resonator and filter with this resonator
AU2868899A (en) * 1998-02-17 1999-08-30 Itron Inc. Laser tunable thick film microwave resonator for printed circuit boards
FR2847747B1 (en) * 2002-11-22 2005-02-18 Thales Sa ANALOGUE / DIGITAL CONVERTER FOR HYPERFREQUENCIES
CN104037484A (en) * 2013-03-08 2014-09-10 中兴通讯股份有限公司 Dielectric resonator and dielectric filter
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FR2565438A1 (en) * 1984-05-30 1985-12-06 Cepe DIELECTRIC FILTER WITH VARIABLE CENTRAL FREQUENCY.
EP0165158A1 (en) * 1984-05-30 1985-12-18 Compagnie D'electronique Et De Piezo-Electricite - C.E.P.E. Dielectric filter with a variable centre frequency
EP0187579A1 (en) * 1984-12-06 1986-07-16 Thomson-Csf Electromagnetic resonators and filters comprising such resonators
EP0547968A1 (en) * 1991-12-19 1993-06-23 Commissariat A L'energie Atomique Measuring system for dielectric and magnetic properties of materials
FR2685490A1 (en) * 1991-12-19 1993-06-25 Commissariat Energie Atomique DEVICE FOR MEASURING DIELECTRIC AND MAGNETIC PARAMETERS OF MATERIALS AND MEASUREMENT SYSTEM FOR SAID PARAMETERS USING THE SAME.
RU2784658C1 (en) * 2022-04-11 2022-11-29 Федеральное государственное бюджетное научное учреждение "Федеральный исследовательский центр "Красноярский научный центр Сибирского отделения Российской академии наук" (ФИЦ КНЦ СО РАН, КНЦ СО РАН) Strip frequency doubler

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FR2535547A1 (en) 1984-05-04
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EP0108003B1 (en) 1988-05-11
US4603311A (en) 1986-07-29
FR2535547B1 (en) 1988-09-16

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