EP0035922B1 - Tuning device with variable capacity and tunable microwave filter with at least one such device - Google Patents

Description

The invention relates to the field of frequency tunable microwave filters and more particularly to a variable capacity tuning device for such filters.

In general, the transmission systems and in particular the telecommunication systems are designed to operate in a given frequency band, possibly comprising several channels and the system's microwave filters must be tuned to the desired channel. When the system is intended to operate on a fixed frequency channel, the filters can be adjusted at the factory or when they are permanently installed; when the system is intended to operate successively on several frequency channels, the filters, then called "frequency agile", must be able to pass quickly and simply from one channel to another. In all cases, it is necessary to provide means for tuning the microwave filters used, and this tuning will be easier if the number of elements to be varied will be small and their adjustment will have little influence on the characteristics. of the filter other than the tuning frequency.

The microwave filters commonly used are of several types: there are filters whose resonator elements are line sections, others for which these elements are in waveguide. The most commonly used TEM inline resonator filters are the quarter wave resonator filters and the peigen resonator filters charged by localized capacitive elements forming obstacles. Waveguide resonator filters are distinguished by their operating mode: when they work in propagation mode, that is to say above the guide's own cut-off frequency, the the most used type is the half-wave resonator filter of the series type coupled by inductive susceptance; when they work in evanescent mode, that is to say at a frequency lower than the natural cut-off frequency of the guide, their structure is of the type with parallel resonators coupled by admittance inverters and they then comprise capacitive obstacles located.

The agreement of the filters is obtained by varying the shape of the localized inductive or capacitive obstacles associated with the TEM lines or the waveguides to form the filter.

The invention relates specifically to capacitive type obstacles and more particularly relates to a capacitive tuning device, usable in all filters comprising localized capacitive obstacles.

The capacitive tuning devices currently used are most often made using metal plungers penetrating into the guide or the line, and the adjustment of the capacity is obtained by varying the depression of this plunger; the variation of the susceptance of the capacitive element (linked to the variation of the tuning frequency) thus obtained, as a function of the frequency, depends on the physical configuration of this element and on the section of the guide or of the line; but generally the law of variation of the tuning frequency, as a function of the displacement of the plunger is not at all linear. In addition, in the filters in evanescent mode, the dimensions of the guide in the plane orthogonal to the axis of propagation are less than the wavelength corresponding to the natural cut-off frequency of the guide; consequently the localized capacity necessary to obtain the agreement, which is all the greater the lower the working frequency, must be housed in a smaller space. The increase in the value of the capacity achieved by means of two opposite plungers is obtained by decreasing the interval separating them. Beyond a certain limit, this interval is too small to be adjusted with precision, all the more since the variations in temperature can, by the expansion of the metals which they entail, create very significant relative variations in this interval . Other types of variable capacity tuning devices comprising two coaxial fingers, one hollow, and the other comprising a movable plunger inside the hollow finger, make it possible to perform a capacity variation. Different embodiments of such tuning devices have been described for example in French patents 1,046,593 or 880,808, in English patent 1,163,896, in American patent 3,273,083 or in German patent application 2,412 759. These devices always have only a variable component of the capacity determining the tuning frequency, its variation being determined by the greater or lesser penetration of the plunger.

However, the ranges of variations in tuning frequencies of this type of device do not allow tunable filters to be produced in a wide band while retaining suitable characteristics.

The subject of the invention is a tuning device with double capacity component, which makes it possible to produce such filters.

According to the invention a tuning device with variable capacity, for tunable microwave filter, comprising two coaxial fingers movable relative to each other, a first finger being hollow and the second comprising a plunger capable of penetrating into the part hollow of the first finger and movable relative to it between a minimum insertion position where the plunger and the hollow finger have no facing side surfaces and a maximum insertion position where the plunger and the hollow finger have maximum opposite side surfaces, to determine a first component of the variable capacity, is characterized in that the second finger has in addition to a cylindrical end of the same outside diameter as a cylindrical end of the first finger, these two ends being intended to face each other by their flat surfaces and being movable relative to each other, the variable distance between the flat surfaces in look at the cylindrical ends determining a second component of the variable capacity.

The invention also relates to a tunable microwave filter comprising at least one such tuning device with variable capacity.

The invention will be better understood and other characteristics will appear from the following description with reference to the appended figures.

Figures 1, 2, 3 and 4 show, in section different embodiments of the variable capacity tuning device according to the invention, particularly intended for fixed frequency filters.

FIG. 5 represents an embodiment of the tuning device according to the invention, particularly intended for so-called "frequency agile" filters.

In all the figures, similar elements have been designated by the same references.

FIG. 1 represents the simplest embodiment of the tuning device according to the invention. This device is shown in section, in place in a guide 1, 1 '. This guide can be a wave guide in evanescent mode with a square, rectangular, round or even ellipsoidal section. 1-1 'can also represent the walls of a TEM line. The capacitive device mainly comprises a metal finger, fixed in the wall 1 ′ is a threaded movable finger, 20, the wall 1 being tapped. A nut 21 allows the movable finger 20 to be held in place. The fixed finger 10 and the movable finger 20 are interpenetrating, their ends having complementary shapes, the end of the finger 20 forming a tuning plunger in a corresponding cavity formed in the finger. 10. To obtain agreement in a given frequency range, F _min (minimum frequency of the range) to Fax (maximum frequency of the range), the minimum facing surfaces are chosen so that, when the end of the movable finger 20 forming a plunger is at the minimum insertion e _min corresponding to the minimum capacity C _min , this capacity C _min or the tuning capacity for the highest frequency of the range, F _max . This capacity essentially depends on the distance d between the planar surfaces opposite the ends of the two fingers 10 and 20 for this minimum penetration e _min and the surfaces of opposite fingers. The stroke of the end of the movable finger forming a plunger 20 and the corresponding height of the cavity formed in the fixed finger 10, as well as their respective diameters, are chosen so that the maximum capacity C _max corresponds to the minimum frequency F _min of the desired frequency range of tuning, the facing surfaces of the two fingers being then maximum. In FIG. 1, the minimum depression e _min corresponding to the frequency F _max has been assumed to correspond to the position of the two fingers such that the end of the plunger is in the same plane as the flat surface of the end of the finger 10 But this minimum sinker plunge corresponding to the frequency F _max could be greater. This setting is related to the highest frequency of the tuning band.

In this embodiment, it should be noted that the external shape of the tuning device thus produced varies a little and that the capacity produced evolves as a whole with the depression of the plunger, the component of capacity due to the plunger and the component of capacity due to the flat surfaces opposite the tips of the fingers varying at the same time.

The embodiments shown in the following figures are improved: they include a movable finger comprising a movable body allowing tuning at the high frequency of the tuning range and a small central plunger, also movable, introducing a variable additional capacity which is added to the minimum capacity C _min corresponding to the minimum insertion of the small plunger but which does not modify the external shape of the tuning device.

The tuning device shown in FIG. 2 comprises a hollow fixed finger 10 and a movable finger 20 comprising a corpos, 22, movable in the wall 1, the movable body being held in position by a nut 21. This body 22 penetrates slightly in the cavity of the fixed finger 10. With this hollow movable body is associated a small movable plunger 23 screwed into the body 22, the depression of which is likely to vary between a minimum depression and e _min , the end of the small movable plunger then being flush at the end of the movable body 22 and the capacity thus produced being a capacity C _min corresponding to the highest frequency of the tuning range F _max , and a maximum depression e _{max '} the small plunger then coming into abutment at l inside the body 22 and the capacity thus produced being the maximum capacity C _max corresponding to the minimum frequency of the tuning range. Displacement of the small plunger can be in the range of 5 mm to 1 cm to cover the tuning range; the distance d between the flat surfaces of the two opposite fingers for the minimum insertion of the plunger, of the order of 5 tenths of a millimeter, is definitively adjusted for the highest frequency of the range, and only the small plunger is moved to get the variations of the tuning frequency. The end of the finger 10, with its cavity, and the end of the finger 20, with the flat surface of the cylindrical end of the body 22 and the plunger 23, have roughly complementary shapes.

The variation in capacitance obtained is such that the tuning frequency varies almost linearly with depression. The small plunger 23 is fixed in position by means of a nut 24 while resting on the head of the movable body 22.

FIG. 3 represents an analogous embodiment but for which the outside diameter of the fingers is large relative to the diameter of the cylindrical ends whose opposite planar faces achieve the minimum capacity and relative to the diameter of the plunger which determines the additional variable capacity which is added to it. The fixed finger 10 and the body 22 of the movable finger 20 have their ends thinned so that the planar surfaces facing the ends of the fingers, which achieve the minimum capacity C _min, are fairly small. The mobile body 22 does not enter the cavity of the fixed finger 10. On the other hand, the hollow of the fixed finger 10 and the hollow of the body 22 of the mobile finger have the same diameter, adapted to the diameter of the small mobile plunger 23, the ends of the finger fixed and the end of the body of the movable finger therefore have the same shape. The minimum capacity C _min is adjusted when the plunger 23 is placed in the high position at the minimum insertion e _min and as in the embodiment of FIG. 2, the variation in capacity generated by the displacement of the plunger is such that the variation tuning frequency is linear as a function of the displacement of the plunger. The respective diameters of the hollow of the finger 10 and of the plunger are such that the displacement of the plunger makes it possible to cover the desired frequency range. Such an embodiment of the capacitive tuning device has made it possible to cover the range of tuning frequencies 1.7 GHz to 2.1 GHz in a filter in evanescent mode, that is to say relatively high frequencies, the initial capacity for the 2.1 GHz frequency being relatively low.

The embodiment represented in FIG. 4 makes it possible to cover a relatively lower frequency range, the capacitance C _min produced for the highest frequency in the range being higher than in the embodiment of FIG. 3. For this the hollow body 22 has its end cut so as to enter a hollow of corresponding diameter provided in the hollow fixed finger 10. The ends of the body 22 of the movable finger and the end of the fixed finger therefore have complementary shapes. The flat surfaces and the cylindrical surfaces opposite the fixed finger 10 and the body 22 of the movable finger 20 make it possible to achieve this capacity C _min for the highest frequency in the range. The body 22 is then fixed by means of the nut 21. The external shape presented by the variable capacity tuning device in the guide does not vary in the tuning frequency range. The variation in additional capacity is obtained, as in the embodiments of FIGS. 2 and 3, by a small plunger 23, the fixed finger comprising a second hollow part, but this time with a diameter corresponding to the diameter of the small plunger. As before, from the minimum sinking, the tuning frequency varies linearly with the sinking of the tuning plunger. This embodiment made it possible to produce a tuning device with variable capacity allowing tuning in the 1.35 GHz to 1.7 GHz range of a microwave filter in evanescent mode.

FIG. 5 represents an embodiment of a variable capacity tuning device particularly intended for so-called "frequency agile" filters, that is to say capable of passing rapidly from one tuning frequency to another within a determined range. The fixed finger 10, the body 22 of the movable finger 20 and the nut 21 which is linked to it are the same as those of the embodiment of FIG. 2, except that the interior of the body 22 is smooth and not threaded. On the other hand, the mobile plunger 25 has the shape of a smooth piston capable of sliding in the hollow body 22. The electrical contact between the piston 25 and the body of the microwave filter is obtained by means of the body 22 by means of a end piece 26 forming clamps and extending the intermediate part of the piston 25.

As in the embodiments described above, the external shape presented by the variable capacity tuning device is invariable regardless of the tuning frequency. Consequently, throughout the tuning frequency range, the coupling of the resonator to the neighboring resonator or to the ports of the filter does not vary as a function of the tuning frequency. Similarly, the bandwidth is almost independent of the tuning frequency.

It should also be noted that the embodiments of the variable capacity tuning device described above lead to filters that are very easy to compensate for in temperature. Indeed, the variation of the tuning frequency being a linear function of the depression of the tuning plunger, and the elongations of the various mechanical elements constituting the capacitive elements also following linear laws, the materials and the dimensions of the elements relative to each other can be chosen in a fairly simple manner so that the temperature filter compensation can be achieved throughout the entire tuning range. Thus, the overvoltage coefficient remains high throughout the frequency range of the filter. Because the small plunger has a small diameter compared to the outer diameter of the two fingers, the stroke of the plunger is large compared to the previous embodiments and the adjustment of the filter is greatly facilitated. The resolution is also greatly improved.

The invention is not limited to the embodiments described and shown. In particular, the external shapes of the fixed finger and of the movable finger are not limited to the shapes described by way of nonlimiting example with reference to FIGS. 1, 2, 3 and 4 (FIG. 5 repeating in this the shape shown in Figure 2). The shapes are determined from the minimum capacity to be produced, in particular in conjunction with the diameter of the fingers and the dimensions of the guides in which the tuning devices are placed to produce the filters.

In addition, for frequency agile filters, it is possible to use a small mobile plunger in the shape of a piston of the type described with reference to FIG. 5 in place of the mobile plunger 23 used in the embodiments of the figures. 2, 3 and 4 to produce agile filters with higher or lower frequency ranges.

Furthermore, the fixed finger has been, in all the embodiments described, chosen as being the hollow finger, the movable finger in the body of the filter being of finger comprising the tuning plunger. It is of course possible to do the opposite, the finger movable relative to the body of the filter then being the hollow finger and the fixed finger then being the finger comprising the chord plunger, the chord plunger then being movable in a finger fixed.

The invention also relates to a tunable microwave filter comprising at least one such tuning device with variable capacity, this filter can be a filter of the waveguide type in evanescent mode or a filter of the TEM line type comprising Localized capacitive elements.

Claims (10)

1. Variable capacity tuning device, for tunable hyperfrequency filter, comprising two coaxial fingers movable with respect to each other, a first finger (10) being hollow and the second (20) comprising a plunger adapted to penetrate in the hollow part of the first finger (10) and movable with respect to it between a minimal sinking position where the plunger and the hollow finger have no opposite facing lateral surfaces and a maximal sinking position where the plunger and the hollow finger have maximal opposite facing lateral surfaces, in order to determine a first variable capacity component, charactei ized in that the second finger presents furthermore a cylindrical end having the same external diameter as a cylindrical end of the first finger, these two ends being intended to oppose each other by their plane faces and being movable with respect to each other, the variable distance (d) between the opposite facing plane surfaces of the cylindrical ends determining a second component of variable capacity.

2. Tuning device according to claim 1, characterized in that the second finger (20) formed of a cylindrical body extended by a plunger is an integral part, the displacement of the plunger with respect to the hollow finger (10) being obtained by displacement of the whole of the movable finger (20), the two components of the variable capacity varying at the same time.

3. Turning device according to claim 1, characterized in that the second finger (20) comprises a hollow body (22) and a plunger (23, 25) moveable with respect to the hollow body (22) of the same finger along their common axis in order to realize the first component of the variable capacity by sinking of the plunger (23, 25) in the hollow finger (10), the second component of the variable capacity being adjusted, when the plunger is in minimum sinking position, by adjusting the distance (d) between the plane surfaces of the cylindrical ends of the fingers by displacing one of the two fingers in its entirety, in the body of the filter, this minimum capacity determining the maximum tuning frequency of the device, the external shape of the tuning device thus being preserved during the sinking variation of the plunger.

4. Tuning device according to claim 3, characterized in that the second finger (20) comprising the moveable plunger (23) is the moveable finger.

5. Tuning device according to claim 3, characterized in that the hollow finger (10) is the moveable finger.

6. Tuning device according to any one of claim 3 to 5, characterized in that the hollow body (22) of the second finger has a threaded internal surface, the external surface of the plunger (23) being equally threaded and the sinking variation of the plunger (23) being ob- taiiied by screwing it in the corresponding hollow body (22).

7. Tuning device according to any one of claims 3 to 5, characterized in that the internal surface of the hollow body (22) of the second finger is smooth, the plunger having the shape of a piston (25), adapted to slide in the corresponding hollow body in order to obtain the sinking variation, clamp contacts (26) integral with the plunger bearing on the internal surface of the hollow body in order to ensure the electric contact between the plunger (25) and the hollow body (22).

8. Tuning device according to any one of claims 3 to 7, characterized in that the ends of the first and of the second finger have complementary shapes such that one of the fingers penetrates in the other, their opposite facing surfaces being formed, in addition to the cylindrical surfaces, of planes surfaces determining by their adjustable distance and their dimensions the second component of the variable capacity, this second component being, at the minimal sinking of the plunger, the minimal capacity of the tuning device thus formed.

9. Tuning device according to any one of claims 3 to 7, characterized in that the ends of the first finger (10) and of the hollow body (22) of the second finger (20) have the same shape and determine, by the adjustable distance between their opposite facing plane surfaces, the second component of the variable component that is the minimal capacity of the tuning device thus realized.

10. Tunable hyperfrequency filter comprising at least one variable capacity tuning device according to any one of the preceding claims.

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