FR2509535A1 - Coupled line section tunable microwave filter - has parallel resonators extending across rectangular resonant cavity and tuning provided by variable capacitor - Google Patents

Abstract

The filter includes a resonant metal cavity (1) inside which there is a set of parallel conductors forming resonators (Ri-Rn). The number of resonators varies according to the required filter characteristics. The filter also includes an input impedance adaptor (ZE) and an output impedance adaptor (XS). Each resonator is fixed by one end to the front face of the box, and by the other end to the back surface of the box via capacitive coupling (Ci-Cn). The capacitive coupling is provided by threaded shafts penetrating part way into each resonator. Each shaft is accessible from the outside so that it may be screwed in or out to tune the resonator. Input and output signals are applied and taken respectively from two points (E,S) on the front surface of the filter. The filter operates in the range 500 MHz - several GHz.

Description

MICROWAVE FILTER HAVING SECTIONS
OF COUPLES AND ADJUSTMENT MEANS
The present invention relates to microwave filters comprising coupled line sections and adjustment means, with distributed constants, of the bandpass type, these filters being presented in different technologies and in different embodiments which are conventionally known as name of filters "comb", "interdigitated", "quarter wave", "evanescent", "microstrip".

 Generally, the technology to be used is determined according to a certain number of criteria which are in particular the tolerated loss in bandwidth, the constraints of space, weight, cost, the possibility of changing the frequency of use of the filter or the width of its bandwidth, the usual specifications relating to the central frequency and the bandwidth mask, the value of the echo loss in bandwidth, and the bandwidth mask (out of band).

 The criterion which is retained in the following description is above all the size of the weakened band filter. Generally, to obtain a very significant attenuation of the order of 90 to 100 dB for one or certain frequencies out of band, only folded comb filters are used. The other technologies mentioned above do not make it possible to obtain the very significant attenuations defined above.

The attenuations result in a drop in gain (or amplitude) on the frequency response curve of the filter. When these drops are 90 to 100 dB, they correspond to infinite peaks that cannot be seen on this response curve. The peaks of infinite attenuation are generally obtained by carrying out so-called "secondary" couplings, that is to say couplings between nonadjacent resonators; This explains the use of folded comb filters, in which the resonators are superimposed two by two.

 The main drawbacks of folded comb filters are their cost and size. Indeed, the manufacture of these filters requires precision on the sides of the order of 100th of a mm, and the production of these folded filters involves the use of two comb filters - superimposed, the cost and the bulk are therefore double. A second drawback appears when one wants to move the infinite loss peaks in a frequency band taken outside the useful band. An already known mechanical embodiment consists in varying the driving of a screw in coupling irises, but this embodiment has certain handicaps and is relatively expensive.

 To remedy these problems, the present invention provides a filter comprising coupled line sections and adjustment means, making it possible to obtain a weakening of the order of - a hundred decibels for frequencies varying continuously outside the range. useful band of the filter, the size of the filter being the same as that of a conventional coupled resonator filter and the cost being substantially the same.

The invention provides a microwave filter comprising line sections and adjustment means, the line sections being coupled together and placed in a resonant cavity parallel to a first face of this cavity, one of the ends of each section of line being connected directly to a second face of - the cavity and the other being connected by capacitive coupling - to a third face of the cavity, the cavity comprising a fourth face parallel to the first supporting the adjustment means and enclosing the sections of line with the other faces, characterized in that the fourth face comprises opposite sections of line at least urre ptaqux :: - elongated conductor integral and electrically isolated from the fourth face extending parallel to this face and perpendicular to the sections of line ; the ends of this plate being folded respectively towards a first and a second non-adjacent line sections to operate a secondary coupling between these two sections and to determine an infinite weakening point at a frequency determined by the position of the plate along the sections of line and by the distance between its ends and the sections towards which they fold back; and in that the adjustment means consist of a variable capacitor, a first armature of which is connected to the fourth face and a second armature of which is connected to one of the
ends of the plate.

Other features and advantages will appear in the description
following with regard to the appended figures. Of course the description and
drawings are given for information only and are not limitative of the invention.

- Figure 1 shows a filter according to the invention;
- Figure 2 shows a schematic section of the filter of Figure 1;
FIG. 3 represents a second embodiment of the ends of the conductive plate 6 of FIGS. 1 and 2.

 Filters comprising line sections and coupled resonators are generally made in different technologies and the choice of technology depends on the working frequency, the useful bandwidth and the frequency response curve that one wishes to obtain. In this embodiment, a technology and a particular embodiment will be limited, the invention being applicable to other technologies.

 The filter according to the invention comprises a metallic resonant cavity 1 inside which are placed a set of conductors in line sections which are resonators Ri, Rj, ... Rn, parallel to each other. The filter shown in FIG. 1 corresponds to an embodiment of a comb filter, the cavity is in this embodiment, a housing 1 provided with a first face corresponding to the bottom 2 of this housing and the resonators are tubular. The number of resonators is variable and depends on the frequency response that one wishes to have. This number makes it possible to determine the number of poles of the amplitude / frequency function. The filter additionally conventionally comprises an impedance adapter ZE to adapt the input signal and an impedance adapter ZS to adapt the output signal. Each resonator is fixed at one end to a second face of the cavity corresponding in this embodiment to a vertical side 3 of the case, and is connected to a third face corresponding to the opposite vertical side 4 by a capacitive coupling Cj. These capacitive couplings are produced in this case not conductive threaded rods referenced respectively Ci ... Cn which penetrate partly inside the resonator. Each rod is accessible from outside the housing and can be screwed or unscrewed - to obtain the tuning frequency of each resonator. The rods therefore make it possible to vary the corresponding tuning capacity. An input É of the filter is taken on the vertical side 3 corresponding to the side close to the zero electric field.

The input impedance adapter ZE is a section of conductive line placed upstream of the first resonator Ri. This ZE adapter is connected to input E by one of its ends and is connected to earth by the other end. An output S of the filter is taken on the vertical side 3.

The adapter ZS is a section of conductive line placed downstream of the last resonator Rn. This adapter ZS is connected to the output S by one of its ends, and is connected to the ground by the other end.

 The filtering frequency range of such a filter can range from 500 MHz to a few GHz. For microstrip or interdigitated filters and others, the frequency domain can be relatively less than 500 MHz and relatively greater than 1 GHz, ie 10-0 MHz to a few GHz.

 The useful bandwidth of such filters is low on the order of one percent of the central frequency for certain embodiments, or very wide up to 10% of the central frequency for other embodiments. We choose a filter - of which Fc is the central frequency and A F the passband. The useful bandwidth is limited by the frequencies Fc + au / 2 and Fc dF / 2.

On the other hand, we chose an amplitude frequency response according to
Tchebycheff, therefore having a minimum of undulation in the useful band. The ratio between the diameter of the resonators (for tubular resonators) and the distance between the cover 5 and the bottom 2, makes it possible to obtain an overvoltage optimun. Resonators have primary couplings
Mi, j between them. These couplings between adjacent resonators are generally capacitive and a function of the distance separating two adjacent resonators Ri and Rj. We chose this distance so as to obtain the desired coupling function corresponding to the size of the filter that we set and which results in the amplitude / frequency curve (or filter transfer function) by more or less slopes steep out of band.

 The identical -references- in the -3-figures indicate the same elements. We now refer to Figure 2.

The cover 5 of the filter is provided on its internal face and parallel to it, that is to say also on the opposite face of the resonators Ri,
Rj ... Rn, of at least one conductive plate 6 of elongated shape integral with this cover 5 but without being in direct contact with Jui. The plate 6 is metallic and parallelepiped in this embodiment. The contact is made by means of spacers inserted between the plate 6 and the cover 7. These spacers are made with simple non-conductive seals 15 and 16. The plate is fixed perpendicular to the resonators by two fixing screws II and 12 , not electrically conductive. The seals 15 and 16 are placed around each read screw and 12 respectively. The number of fixing screws is chosen so as to keep the plate 6 secured to the cover 5 in a reliable manner. This number can therefore vary according to the dimensions of the plate 6 without changing the result obtained. The head of the screws is placed against the inner face of the plate 6 opposite the resonators. Two nuts 13 and 14 are screwed around the screws Il and 12 respectively against the outside face of the cover 5. If a reverse arrangement is adopted for these elements, that is to say if the head of the screws is outside the case , and the nuts inside, it is obvious that the nuts should be thin and preferably be made of an insulating material. The dimensions of each plate are relative to the dimensions of the filter, to the spacing between the two resonators that it is desired to couple and to the number of conductive plates used. This number of conductive plates used depends on the number of infinite attenuation points that we want to get out of band. The ends 7 and 8 of each plate are arranged so as to capture the maximum energy of a resonator Ri for example and send it to another resonator Rn for example which is not adjacent to the resonator Ri, to thus achieve coupling secondary Mi, n. The choice of resonators on which the secondary coupling is carried out in order to obtain an infinite attenuation at a given frequency and determined using coupling matrices obtained by a conventional method of synthesis of the filters. According to a first embodiment the ends 7 and 8 (of each plate) are bent towards the bottom 2 of the shoemaker I and have flat folds 9 and 10 opposite the resonators to be coupled. The distance d existing between the flat folds 9 and lrj, and the corresponding resonators determines the value of the secondary coupling and consequently determines the frequency position of the infinite weakening tip. The secondary coupling is also a function of the position of the plate with respect to the electric field existing along the resonators.

When the plate is close to the minimum electric field (to ground), the distance d must be minimum (as close as possible to the limit of correct operation) to obtain a strong coupling and thus have a point of infinite attenuation at a frequency very close to the useful band. Since this solution for obtaining a weakening tip at a frequency very close to the useful band is not the best since there is a risk of causing electrical contact between the end 8 of the plate 6 and the resonator Rn, it is preferable to place the plate near the maximum electric field, the distance d then being chosen maximum, this maximum still making it possible to obtain a very strong coupling and therefore an infinite weakening tip at the desired frequency very close to the useful band. The frequency position of the infinite weakening peaks only depends on the value of the secondary coupling which itself depends firstly on the distance d and secondly on the position of the conductive plate with respect to the electric field.

When the distance d and the position of the plate have been fixed, it is then possible to act on the secondary coupling by means of a variable capacitor 17 which electrically connects one of the ends 8 of the plate 6 to the cover 5.

 The capacitor 17 is welded to the plate 6 by one of the connection wires 18b and to the cover by the other connection wire 18a. This capacitor i7 is placed so as to be accessible from the outside of the box 1. The variable capacitor 17 appears in FIG. 2 housed in the cover 5 and integral with the latter. The electrical coupling produced by this capacitor 17 is variable and varies according to the positioning of the armature 17a relative to the armature 17b. When the surface facing the two armatures 17a and 17b is increased, the capacity of the capacitor 17 increases, the coupling between the plate 6 and the cover 5 increases, and therefore the secondary coupling Mi, n between the plate and the resonator considered decreases this. which provides infinite loss peaks at varying preferences and for higher out-of-band frequencies.

when the capacitance of the capacitor 17 is reduced, the coupling between the plate and the cover decreases, and therefore the secondary coupling Mi, n between the plate and the resonator considered increases which makes it possible to obtain infinite weakening peaks for lower out-of-band frequencies and close to the cut-off frequencies delimiting the useful band of the filter. Variations in the capacitance of the capacitor allow continuous adjustment of the frequency positions of the infinite attenuation peaks.

 According to a second embodiment, the ends 9 and 10 of each conductive plate 6 are in the form of a ring 9a in accordance with FIG. 3.

The radius of the ring is chosen according to the same criteria as the distance d in the first embodiment to obtain an infinite point of weakening in order to have a pseudo-elliptical response.

 The fixing of such conductive (metal) plates makes it possible to carry out secondary couplings between resonators and thus to have one or more infinite weakening peaks at determined frequencies, to obtain a pseudo-elliptical response and respond to the size of the requested filter, without having to double the costs and size of such a filter; the variable capacitor 17 connecting one end of each plate to the cover makes it possible to obtain a continuous frequency adjustment of the infinite weakening peaks.

Claims (8)

 1. Microwave filter comprising line sections (Ri-Rn) and adjustment rnayens (l7y, the line sections (Ri-Rn) being coupled together and placed in a resonant cavity (1) parallel to a first face (2 ) of this cavity (1), one end of each section of line being connected directly to a second face (3) of the cavity - and the other being connected by a capacitive coupling (Cj) to a third face ( 4) of the cavity, the cavity (1) comprising a fourth face (5) parallel to the first supporting the adjustment means (17) and enclosing the line sections with the other faces, characterized in that the fourth face (5 ) comprises opposite line sections (Ri-Rn) at least one conductive plate (6) elongated integral and electrically isolated from the fourth face (5) extending parallel to this face (5) and perpendicular to the line sections; the ends (7, 8) of this plate (6) being folded respectively towards a first ( Ri) and a second (Rn) non-adjacent line sections to operate a secondary coupling between these two sections (Ri, Rn) and determine an infinite weakening point at a frequency determined by the position of the plate (6) the along the line sections and by the distance between its ends (7, 8) and the sections to which they fold back; and in that the adjustment means consist of a variable capacitor (17), a first frame of which is connected to the fourth face (5) and a second frame of which is connected to one of the ends of the plate (6).  2. Microwave filter according to claim 1, the line sections of which (Ri ... Rn) are resonators having primary couplings (Mi, given in the passband of the filter, characterized in that the ends (7 and 8) of the plate (6) each have a flat fold (9 and 10) opposite the resonators to be coupled (Ri, Rn).  3. Microwave filter according to claim 1, characterized in that the ends (9 and 10) of the conductive plate (6) are in the form of a ring (9a), each of these rings coming to surround a resonator (Rn) .  4. Microwave filter according to any one of claims 1 to 6, characterized in that the conductive plate (6) elongated is of parallelepiped shape.  5. Microwave filter according to any one of claims 1 to 4, characterized in that the conductive plate (6) is fixed to the fourth face (5) using fixing screws (11 and 12) insulating tightened by nuts (13,14) placed on the outside of this face (5) -.  6. Microwave filter according to any one of claims 1 to 5, characterized in that it has insulating spacers (15 and 16) placed between each conductive plate (6) and the fourth face (5), fixed to the using the plate fixing screws (13 and 14).  7. Microwave filter according to any one of claims 1 to 6, -characterized in that the insulating spacers are produced by insulating seals (15 and 16) placed around the fixing screws (13 and 14) of the plate (6 ), between the plate (6) and the fourth face (5).  8. Microwave filter according to any one of claims 1 to 7, characterized in that the resonators (Ri-Rn) are of tubular shape.