Radiofrequency filter with dielectric element

Abstract

A radiofrequency filter exhibiting at least one resonant mode comprises: at least one cavity at least partially closed using conductive walls, having a cylindrical outer surface defined by a directing curve described by a generatrix and having a point of symmetry, an axis passing through a point of symmetry and parallel to the generatrix being a longitudinal axis of the cavity. At least one dielectric element is arranged in the cavity and comprises: a first portion having a thickness according to the longitudinal axis and a section according to a plane perpendicular to the longitudinal axis whose vertices are distributed according to a polygon, at least two vertices being short-circuited between them by the conductive walls of the cavity, via an electrical or radiofrequency contact between the vertices and walls, at least one pyramidal portion comprising an apex and a base coinciding with an extreme section of the first portion.

Claims

1. A radiofrequency filter exhibiting at least one resonant mode, the radiofrequency filter comprising: conductive walls that define at least one cavity that is at least partially closed and includes: a cylindrical outer surface defined by a directing curve that is symmetrical about a point of symmetry, and a longitudinal axis that passes through said point of symmetry; and at least one dielectric element arranged in said cavity and including: a first portion that has a thickness along said longitudinal axis and extends along a plane perpendicular to said longitudinal axis between vertices of the first portion that are arranged according to a shape of a polygon, a top pyramidal portion that includes a top base that coincides with a top extreme section of said first portion, and a bottom pyramidal portion including a bottom base that coincides with a bottom extreme section of said first portion, wherein at least two vertices of said vertices are short-circuited together by said conductive walls via an electrical or radiofrequency contact between said vertices and said conductive walls, and wherein said top pyramidal portion and said bottom pyramidal portion are identical.

2. The filter according to claim 1, wherein said directing curve is is one of a square, a rectangle, a hexagon, a circle, and an ellipse.

3. The filter according to claim 1, wherein at least one of said top base and said bottom base comprises vertices arranged according to a regular polygon.

4. The filter according to claim 1, wherein all of said vertices are short-circuited together by said conductive walls of said cavity via the electrical or radiofrequency contact between said vertices and said conductive walls.

5. The filter according to claim 1, wherein an apex of at least one of said top pyramidal portion and said bottom pyramidal portion is arranged on said longitudinal axis.

6. The filter according to claim 1, wherein a barycentre of said shape of said polygon corresponding to the first portion is arranged on said longitudinal axis.

7. The filter according to claim 1, wherein at least one of an angle between said top base and a face of said top pyramidal portion and an angle between said bottom base and a face of said bottom pyramidal portion is less than or equal to 45 .

8. The filter according to claim 1, wherein at least one of said top pyramidal portion and said bottom pyramidal portion is truncated along a plane at right-angles to said longitudinal axis.

9. The filter according to claim 1, wherein at least one of said top pyramidal portion and said bottom pyramidal portion is a truncated pyramidal portion that defines a recess on a top face of said truncated pyramidal portion.

10. The filter according to claim 1, wherein at least one recess is is defined by said at least one dielectric element on a perimeter of said at least one dielectric element.

11. The filter according to claim 1, dimensioned such that a resonance frequency of the at least one resonant mode is between 3 GHz and 30 GHz.

12. The filter according to claim 1, wherein an electromagnetic field corresponding to the at least one resonant mode comprises an even number 2n of zones for which said electromagnetic field exhibits a maximum, said zones being arranged in equal numbers n on either side of said first portion of said at least one dielectric element, n being chosen from 1, 2, 3 and 4.

13. The filter according to claim 12, wherein each of said zones is distributed partially inside and partially outside at least one of said top pyramidal portion and said bottom pyramidal portion positioned on a same side of the at least one dielectric element as a respective zone.

14. The filter according to claim 1, further comprising at least one input cavity and one output cavity; input coupling means for a radiofrequency wave originating from an external source with said at least one input cavity; output coupling means between said one output cavity and an external waveguide; and intermediate coupling means for coupling said at least one input cavity and one output cavity together.

15. A radiofrequency filter exhibiting at least one resonant mode, the radiofrequency filter comprising: conductive walls that define at least one cavity that is at least partially closed and includes: a cylindrical outer surface defined by a directing curve that is symmetrical about a point of symmetry, and a longitudinal axis that passes through said point of symmetry; and at least one dielectric element arranged in said cavity and including: a first portion that has a thickness along said longitudinal axis and extends along a plane perpendicular to said longitudinal axis between vertices of the first portion that are arranged according to a shape of a polygon, at least one pyramidal portion including an apex and a base coinciding with an extreme section of said first portion, wherein at least two vertices of said vertices are short-circuited together by said conductive walls via an electrical or radiofrequency contact between said vertices and said conductive walls, wherein said at least one pyramidal portion is a truncated pyramidal portion that defines at least one recess on a top face of said truncated pyramidal portion, and wherein said at least one recess is defined by said truncated pyramidal portion on a perimeter of the dielectric element.

16. A radiofrequency filter exhibiting at least one resonant mode, the radiofrequency filter comprising: conductive walls that define at least one cavity that is at least partially closed and includes: a cylindrical outer surface defined by a directing curve that is symmetrical about a point of symmetry, and a longitudinal axis that passes through said point of symmetry; and at least one dielectric element arranged in said cavity and including: a first portion that has a thickness along said longitudinal axis and extends along a plane perpendicular to said longitudinal axis between vertices of the first portion that are arranged according to a shape of a polygon, at least one pyramidal portion including an apex and a base coinciding with an extreme section of said first portion, wherein at least two vertices of said vertices are short-circuited together by said conductive walls via an electrical or radiofrequency contact between said vertices and said conductive walls, and wherein said radiofrequency filter operates in a transverse electrical mode.

17. The filter according claim 16, wherein an electromagnetic field corresponding to the at least one resonant mode comprises an even number 2n of zones for which said electromagnetic field exhibits a maximum, said zones being arranged in equal numbers n on either side of said first portion of said at least one dielectric element, n being chosen from 1, 2, 3 and 4.

18. A radiofrequency filter exhibiting at least one resonant mode, comprising: conductive walls that define at least one cavity that is at least partially closed and includes: a cylindrical outer surface defined by a directing curve that is symmetrical about a point of symmetry, and a longitudinal axis that passes through said point of symmetry; and at least one dielectric element arranged in said cavity and including: a first portion that has a thickness along said longitudinal axis and extends along a plane perpendicular to said longitudinal axis between vertices of the first portion that are arranged according to a shape of a polygon, at least one pyramidal portion including an apex and a base coinciding with an extreme section of said first portion, wherein at least two vertices of said vertices are short-circuited together by said conductive walls via an electrical or radiofrequency contact between said vertices and said conductive walls, wherein an electromagnetic field corresponding to the at least one resonant mode comprises an even number 2n of zones for which said electromagnetic field exhibits a maximum, said zones being arranged in equal numbers n on either side of said first portion of said at least one dielectric element, n being chosen from 1, 2, 3 and 4, and wherein each of said zones is distributed partially inside and partially outside said at least one pyramidal portion positioned on a same side of the dielectric element as a respective zone.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) Other features, aims and advantages of the present invention will become apparent on reading the following detailed description and in light of the attached drawings given by way of nonlimiting examples and wherein:

(2) FIGS. 1a-1c schematically illustrate a filter according to the invention.

(3) FIG. 2 describes an exemplary pyramidal structure of the dielectric element.

(4) FIGS. 3a-3b illustrate a preferred embodiment of a pyramidal portion.

(5) FIG. 4a-4b illustrate a variant dielectric element comprising a truncated pyramidal portion.

(6) FIG. 5a-5c illustrate a variant dielectric element comprising recesses.

(7) FIGS. 6a-6b illustrate the distribution of the field lines for an embodiment of the filter according to the invention.

(8) FIGS. 7a-7b illustrate the distribution of the field lines for another embodiment of the filter according to the invention.

(9) FIGS. 8a-8b schematically illustrate a variant embodiment of the dielectric element of the filter according to the invention.

(10) FIG. 9 illustrates the distribution of the field lines for a filter according to the invention having a dielectric element as described in FIG. 8.

(11) FIG. 10 illustrates a first exemplary embodiment of a filter according to the invention.

(12) FIG. 11 illustrates a second exemplary embodiment of a filter according to the invention.

(13) FIG. 12 illustrates a third exemplary embodiment of a filter according to the invention.

(14) FIG. 13 illustrates an exemplary frequency response over a wide band of a filter according to the invention.

(15) FIG. 14 illustrates an exemplary frequency response in the vicinity of the resonance frequency of a filter according to the invention.

DETAILED DESCRIPTION

(16) One aim of the invention is to produce a filter for radiofrequency waves exhibiting very good performance levels both in terms of quality factor Q and insulation.

(17) Insulation should be understood to mean the capacity of the filter not to transmit undesirable modes other than the selected resonance modes of the filter. The frequency range around the resonance frequency for which no spurious mode is transmitted is, according to the terminology, called spurious free range. The aim will of course be to obtain the widest possible range.

(18) For example, for an OMUX application in band Ku (10 to 13 GHz), the aim is typically to have a range of the order of 500 MHz on either side of the resonance frequency, a non-loaded quality factor at least equal to 18 000 and a power withstand strength of at least 300 W per channel.

(19) Figure 1a describes a perspective view of a radiofrequency filter (RF) 10 according to the invention. This filter exhibits at least one resonance mode and comprises a cavity 11 at least partially closed using conductive walls 12, typically metallic. The cavity 11 has a cylindrical outer surface defined by a directing curve C described by a straight line called generatrix 200 of the cylinder. The directing curve of the cavity of the filter according to the invention has a point of symmetry Sy, which simplifies production and simulation.

(20) According to a preferred embodiment, for ease of production, the directing curve C is a square, a rectangle, a hexagon, a circle or an ellipse. The longitudinal axis z of the hollow cylindrical cavity is defined as the axis parallel to a generatrix 200 straight line and passing through the points of symmetry.

(21) The filer 10 according to the invention also comprises at least one dielectric element 13 arranged in the cavity 11. The dielectric element 13 comprises a first portion 131 having a thickness e according to the axis z and a section according to a plane perpendicular to z wherein the p vertices S1, S2, . . . Sp are distributed according to a polygon P. To simplify understanding and, in a nonlimiting manner, the polygon represented in FIG. 1 is a square, but any polygon P is compatible with the invention.

(22) According to a preferred variant, the polygon is regular (triangle, square, pentagon, hexagon, etc.) or rectangular, to allow for a low cost industrial production of the filter and an easier optimization because of the presence of axes of symmetry.

(23) According to a preferred embodiment, the polygon is a square so as to limit the contacts between the dielectric element 13 and the cavity 11, which makes it possible to prioritize certain modes and ensure the quality of the contacts.

(24) Similarly in FIG. 1 and in a nonlimiting manner, the sides which join the vertices together are straight-line segments, but any other form is compatible with the filter 10 according to the invention, variants of which are described later. The contact of the dielectric element 13 with the conductive wall is made through the first portion 131, according to the same principle as that described in U.S. Pat. No. 5,880,650, that is to say at least two vertices of the polygon are short-circuited between them by the walls 12, via an electrical or radiofrequency contact between these vertices and the wall.

(25) The method for fixing the dielectric element 13 to the walls 12 thus offers the same advantages as those described in U.S. Pat. No. 5,880,650, such as: assembly of the filter simplified by an exact and absolute positioning of the dielectric element without having to use securing elements. heat transfer between the element and the walls significantly enhanced.

(26) The method for fastening the dielectric element to the walls is also compatible with the same variants, for example: truncated or rounded vertices, as described in FIG. 1, to closely follow the form of the side walls, planar or rounded depending on the form of the directing curve C of the cylindrical cavity, truncation of the vertices according to dimensions slightly less than the transversal dimensions of the cavity so as to leave a small space, which may be empty or filled with dielectric or conductive and/or elastic material, use of securing pillars, truncation of the vertices according to dimensions slightly greater than the transversal dimensions of the cavity and production of notches, etc.

(27) It is not necessary for all the vertices of the polygon P to be short-circuited between them, it is sufficient for the vertices short-circuited by the walls 12 to be in sufficient numbers to ensure a correct positioning of the dielectric element in the cavity.

(28) According to a preferred variant, for a better positioning accuracy, all the vertices S1 . . . Sp of the polygon P are short-circuited between them by the conductive walls.

(29) The dielectric element 13 also comprises at least one pyramidal portion 132, 133 as illustrated in FIGS. 1a (perspective view), 1b (profile view) and 1c (plan view). The pyramidal portion comprises an apex Asup, Ainf, vertex of the pyramid, and a base Bsup, Binf, which coincides with an extreme section 134, 135 of the first portion 131. Extreme section should be understood to mean the top section 134 and the bottom section 135 of the first portion 131 of thickness e.

(30) The particular form of the dielectric element associated with an optimized dimensioning (cavity and dielectric element) makes it possible to obtain a filter with performance levels that are enhanced compared to those of the filters of the prior art.

(31) According to a variant, the dielectric element 13 comprises a single pyramidal portion, bottom 132 or top 133.

(32) According to a preferred variant, the dielectric element 13 comprises two pyramidal portions on either side of the first portion 131, the top base Bsup coinciding with the top extreme section 134 and the bottom base Binf coinciding with the bottom extreme section 135 of the first portion 131.

(33) In order to simplify the calculations for optimizing the dielectric element in the cavity, according to a preferred embodiment, the top and bottom pyramidal portions are identical. According to a preferred embodiment, the filter according to the invention comprises a plane of symmetry xy. The existence of a symmetry in the form of the dielectric element makes it possible to obtain a better insulation, because of the symmetry of the modes which devolve therefrom. A distortion of the modes renders the behaviour of the filter non-optimal.

(34) Preferentially, the filters according to the invention operate according to a TE (transverse electrical) mode.

(35) FIG. 2 schematically illustrates an exemplary pyramidal structure whose base consists of vertices arranged on a polygon P of barycentre Ba, and of apex Asup. In this example, the barycentre Ba and the apex Asup are not arranged on the longitudinal axis z of the cylindrical cavity.

(36) In order to simplify the optimization calculations, according to a preferred variant illustrated in FIGS. 1a, 1b and 1c, the apexes Asup and Ainf of the pyramidal portions are arranged on the longitudinal axis z of the cavity 11.

(37) In order to position and fix the dielectric element 13 more easily in the cavity 11, according to a preferred variant, the barycentre Ba of the polygon P serving as base for the pyramidal portion is arranged on the longitudinal axis z of the cavity 11, as illustrated in FIGS. 1a, 1b, 1c.

(38) Preferentially, the dielectric element 13 is produced from a single block, which offers the advantage of simplifying the industrial production of the element 13, obtained by moulding, machining or grinding or by additive manufacture (stereolithography).

(39) FIG. 3 illustrates a preferred embodiment of a pyramidal portion, whose base is a regular polygon (3a: square, 3b: pentagon) whose apex A has a projection orthogonal to the base, defining a height h, which passes through the barycentre Ba of the polygon.

(40) Examples of this particular pyramidal portion case are the regular tetrahedron, square pyramid (FIG. 3a), pentagonal pyramid (FIG. 3b), hexagonal pyramid, etc.

(41) The angle between the base of the pyramid and a face of the pyramid is called angle . According to a preferred embodiment, the angle (or all the angles when they are not equal) is(are) less than or equal to 45.

(42) FIG. 4 represents a variant dielectric element 13 inside a cylindrical cavity 11 of directing curve C according to a circle (circular cylinder). FIG. 4a illustrates a perspective view, FIG. 4b a profile view.

(43) According to this variant, the pyramidal portion is truncated, for example along a plane T at right-angles to the longitudinal axis z. The apex is then virtual.

(44) The truncation is defined by a distance Dtr corresponding to the fraction k of the height for which the material has been eliminated.
Dtr=kh

(45) The truncation offers the advantage of limiting the sensitivity of the filter performance levels to the value of the angle .

(46) Preferentially, k is between 0.1 and 0.5. For lower values of k, the advantage of the truncation is not significant. For higher values of k, the quality factor Q decreases substantially.

(47) FIG. 5 represents another variant dielectric element 13 inside a cylindrical cavity 11 of directing curve C according to a circle. FIG. 5a illustrates a perspective view, FIG. 5b a plan view and FIG. 5c a profile view. In the example of FIG. 5, the polygon is a square: the 4 vertices S1, S2, S3 and S4 are distributed according to a square.

(48) In the example illustrated in FIG. 5, the perimeter 51 of the dielectric element is rounded (chamfer 55) in the vicinity of the vertices to closely follow the form of the cylindrical wall.

(49) According to this variant illustrated in FIG. 5, the perimeter 51 of the dielectric element 13 does not coincide with the sides of the square according to which the vertices are distributed. Thus, at least one recess 52 is produced at any point on the perimeter 51 of the dielectric element 13. Preferentially, all the sides of the polygon have a recess 52 to ensure symmetry of the electromagnetic field.

(50) This involves removing dielectric material in the zones where the electrical field is of weak intensity. One advantage is that a smaller dielectric volume is obtained. Another advantage is that a better insulation is obtained by controlling the frequency of the other modes (spurious modes) which depend more strongly on this dielectric part.

(51) Preferentially, the recess is produced in such a way as to not add right-angled edges.

(52) The filter of FIG. 5 has a dielectric element which combines recess and truncation. These two variants are independent.

(53) In the design of a radiofrequency filter according to the invention, the resonance frequencies depend primarily: on the dimensions (thickness and transversal dimensions of the first portion, height of pyramidal portion) and on the form (square, pentagonal, hexagonal base) of the dielectric element, on the dimensions and on the form of the resonant cavity wherein the dielectric element is arranged, on the dielectric material used to produce the latter.

(54) The values of these variables therefore depend on the radiofrequency band wherein the filter operates. According to a preferred variant, the filter according to the invention is dimensioned to operate in the bands C, X and Ku and Ka, that is to say comprising a resonance frequency within the range [3 GHz; 30 GHz].

(55) An example of dimensioning for a resonance frequency of 12 GHz is:

(56) Metallic cavity:

(57) circular cylindrical of diameter between 20 and 25 mm and of length between 20 and 25 mm.
Dielectric element: square base closely following the form of the cavity for the 4 vertices, thickness e of the first portion between 2 and 4 mm, angle of the pyramid: between 8 and 11, dielectric permittivity: 9.5 and 10.

(58) For these dimensions, a non-loaded quality factor of between 18 000 and 19 000 and a total range insulation between 1 GHz and 1.5 GHz around the resonance frequency were calculated with a temperature-compensated dielectric.

(59) The presence of a recess enhances the insulation range, the presence of a truncation reduces the sensitivity of the resonance frequency to the value of the angle of the pyramid, thus relaxing the manufacturing constraints of the dielectric element.

(60) From an electromagnetic point of view, two types of filters are conventionally distinguished based on the manner wherein the dielectric element is used.

(61) In a first type, the dielectric element is used as resonator, which means that the electrical field is concentrated inside it. The resonator modes (also called dielectric modes) are thus modes for which the electrical energy is concentrated mainly in the dielectric material (typically 90 to 95%). Their losses are essentially dielectric and depend on the characteristics of the material (losses tangent).

(62) Conversely, in a second so-called cavity modes type, the resonant cavity is said to be loaded by the dielectric element which modifies the dielectric permittivity of the medium. The losses are essentially metallic.

(63) An enhanced mode of operation of the filter according to the invention is called hybrid, and consists in loading the cavity with a dielectric in order to partially concentrate the electrical energy therein, so as to reduce the metallic losses while limiting the dielectric losses. The electromagnetic operation of the filter according to the invention thus combines the two types of conventional operation, which makes it possible, partly by virtue of the specific form of the dielectric element, to minimize the losses (high quality factor) while maintaining a good insulation.

(64) In hybrid operation, the resonant mode exhibits an even number 2n of zones for which the electrical field exhibits a maximum, the zones being arranged in equal numbers on either side of the first portion 131 of the dielectric element 13.

(65) In practice, only the values n=1, n=2, n=3 and n=4 offer any practical benefit. In practice, the higher the order number rises, the more maxima there are, and beyond 4 maxima on each side, the insulation becomes insufficient.

(66) Given constant dimensions, the higher n becomes, the higher the resonance frequency of the corresponding mode. It is therefore essential to increase the dimensions to bring this resonance frequency to the frequency of the filter.

(67) When a filter is produced per channel, one option is to use, for each channel, a filter of identical structure and operating in the same mode, but of proportionally scaled dimensions, to obtain proportional and determined resonance frequencies.

(68) In an enhanced embodiment of the filter according to the invention illustrated in FIGS. 6 and 7, each of the zones for which the electrical field exhibits a maximum is distributed partially inside and partially outside the pyramidal portion positioned on the same side as the zone in question.

(69) According to the plate prior art, the plates are positioned on the field maxima in order to concentrate the electrical energy there.

(70) For a filter according to the invention, intrinsically hybrid, the first portion of the dielectric (common base of the pyramids) is positioned on a field minimum (between the 2 field maxima). Since the dielectric still has a tendency to concentrate the electrical energy, by adjusting the dimensions of the pyramid, this energy is partially concentrated, partly inside, partly outside, the dielectric, optimally.

(71) One advantage of using a hybrid mode wherein the field maximum is located partially outside the dielectric and partially inside consists in obtaining dielectric losses lower than those obtained for a conventional resonator type mode and metallic losses lower than those obtained for a conventional loaded cavity type mode.

(72) FIG. 6 illustrates a filter 10 according to the invention operating in hybrid mode, wherein the dielectric element comprises two square pyramids, truncated and with recesses in a circular cylindrical cavity 11 as illustrated in FIG. 5, the contact between element 13 and wall 12 being made by the four vertices of the square, as well as the distribution of the field lines of the resonant mode in the cavity. FIG. 6 also illustrates the distribution of the field lines in such a way as to highlight the position of the field maxima, for example for a polarization. FIG. 6a represents a profile view, and FIG. 6b a perspective view.

(73) It can be seen in FIG. 6a that there are two zones which concentrate the electrical field, each arranged on either side of the first portion of the dielectric element (case n=1). The zones 61 and 62 correspond to the points for which the electrical field exhibits a maximum. Each zone 61, 62 is distributed partially in the dielectric element and partially outside it. By concentrating the electrical energy at the centre of the cavity, partially inside the dielectric, the metallic losses are substantially reduced, while limiting the dielectric losses.

(74) FIG. 7 illustrates the same filter as that of FIG. 6 wherein a resonant mode exhibiting eight zones is favoured, four in cross section (71 and 72; 73 and 74) which concentrate the electrical field on either side of the first portion of the dielectric element (case n=4). FIG. 6a represents a profile view and FIG. 6b a perspective view of the dielectric element 13 and of the distribution of the field lines.

(75) To obtain a resonant mode with eight maxima, it is advisable for example to find a resonance frequency on this mode, without modifying the dimensions of the cavity and of the dielectric 13.

(76) For example, the resonance frequency of the mode n=4 is 14.5 GHz when the resonance frequency of the mode n=1 is 12 GHz, all other things remaining equal.

(77) Another variant of the form of the dielectric element is illustrated in FIG. 8. The truncated pyramid has a recess 80 produced on a top face of the truncated pyramidal portion.

(78) The recess is of any form, for example an emerging hole, or an inverted pyramid and is positioned in a zone exhibiting a weak electrical field. This variant is advantageous for the case n=4 (see FIG. 7) wherein the electrical field at the centre of the truncated part is weak. Producing this recess according to optimal dimensions makes it possible to control the frequencies of the spurious modes.

(79) FIG. 9 illustrates the distribution of the field lines of the resonant mode in the cavity, with a truncated pyramid, whose truncated planar part is hollowed, for a mode n=4. The recess disturbs the distribution of the maxima of the electrical field very little, partially inside and partially outside the pyramidal portion.

(80) A first exemplary embodiment of a filter 10 according to the invention is schematically illustrated in FIG. 10. The filter comprises at least one input cavity 101 and one output cavity 102, input coupling means 103 for a radiofrequency wave originating from an external source with the input cavity 101 and output coupling means 104 between the output cavity 102 and an external waveguide, and comprises intermediate coupling means 105 for coupling the cavities together. Metallic transversal walls 106 and 107 at least partially close the input and output cavities.

(81) The filter may also comprise one or more intermediate cavities coupled together, as described in FIG. 1 of the document U.S. Pat. No. 5,880,650. All these cavities are, for example, defined electrically inside a cylindrical waveguide section through a plurality of walls transversal to the longitudinal axis of the cylinder 106, 105, 107, which close the cavities at least partially at the two ends of each cavity. The materials used to construct the waveguide and the transversal walls are those commonly used by those skilled in the art for such a production. The input and output coupling means are also those used commonly by those skilled in the art.

(82) The intermediate coupling means are conventionally different forms of slots or of irises, or capacitive probes, inductive irises or a combination of the two.

(83) The filter according to the invention may also comprise resonance frequency tuning means known to those skilled in the art.

(84) In FIG. 10, a dielectric element according to the invention is arranged inside a cavity, but the filter according to the invention may also comprise a plurality of pyramidal dielectric elements per cavity, possibly combined with plate-type dielectric elements such as those described in U.S. Pat. No. 5,880,650.

(85) For example, with a single dielectric element per cavity, the element is preferentially positioned in the middle of the cavity. With two dielectric elements per cavity, an element is positioned on either side of the middle of the cavity.

(86) Another exemplary embodiment of a filter according to the invention is described in FIG. 11, for which the input and output coupling means 103, 104 are positioned on the transversal walls 106, 107, in a so-called in-line configuration.

(87) FIG. 12 illustrates a third exemplary embodiment of a filter according to the invention comprising an input cavity and an output cavity. According to this example, there is no single waveguide section, but two cylindrical parts of parallel longitudinal axes, each cavity being at least partially closed by transversal walls 106, 107 for the input cavity and 108, 109 for the output cavity. The input and output coupling means are arranged on the cylindrical wall of the corresponding cavity.

(88) With a filter according to the configurations illustrated in FIG. 10 or 12, it is possible to locate an external temperature compensation system, as described in the patent US2006097827, on the covers 106, 107, 108 and 109. It is thus possible to use non-temperature-compensated dielectrics which makes it possible to substantially increase the non-loaded quality factor (typically 25 000).

(89) FIGS. 13 and 14 illustrate the frequency response of a filter 10 according to the invention as illustrated in FIG. 10 and dimensioned for a resonance frequency of 12 GHz. The parameter S is a parameter which takes into account the performance levels of the filter in terms of reflection and transmission. The curve S11 corresponds to the reflection and S12, or S21, to the transmission. The tuning of the filter makes it possible to obtain a transmission maxima (reflection minima) for a given frequency band. The bandwidth of the filter is determined with equiripple of S11 (or S22), for example with 15 dB or 20 dB reduced reflection compared to its outbound level.

(90) FIG. 13 illustrates the wideband response and a good insulation compared to the spurious modes can be seen. FIG. 14 corresponds to a zoom around the resonance frequency and illustrates the response within the bandwidth. The filter comprises 4 poles and is centred around 11.950 GHz, and the bandwidth is 40 Mhz.