The present invention concerns a band pass filter for an electric or electromagnetic signal, especially for a high-frequency signal. Such filters play an important role in the design of components for modern telecommunications systems. The requirements that are generally imposed on such filters include steep filter flanks, high non-pass attenuation, uniform phase shift in the pass band region, etc. A distinction is made between different filter types, like Cauer, Tschebyscheff, Butterworth or Bessel filters, each of which satisfies one or more of these requirements particularly well.
A common feature of all these filters is that they are constructed from one or more resonators. In the simplest case of a filter with several resonators, the individual resonators are connected in series, so that a single signal path exists through the filter, on which a signal of all resonators pass through according to the sequence. The flank steepness, non-pass attenuation, etc., attainable with such an arrangement of resonators, are established, among other things, by the number of resonators.
Ordinary filter synthesis techniques additionally allow for the possibility, in addition to a pure series circuit, of connecting individual, not directly adjacent resonators of the filter to each other, in order to produce overlapping of signal contributions in one resonator, which can lead to zero setting of the transmission function of the filter during finite arguments in the complex number plane. Filters synthesized with such methods always have a main signal path that runs through all the resonators of the filter and, in addition to the main signal path, one or more secondary signal paths that run from the input to the output of the filter via at least one coupling between non-adjacent resonators on the main signal path, and therefore have a smaller number of resonators in the main signal path.
Band pass filters are known from U.S. Pat. No. 6,337,610 B1 having two main signal paths, i.e., two first signal paths, in which, unlike the secondary signal paths of the ordinary filter structures, each has a second signal path that passes through all the resonators of the first path in the same sequence, and one or more additional resonators between at least two directly consecutive resonators on the first path. These main signal paths of these known filters each have a common input or output resonator connected to the input or output.
Practical implementation of such filters is connected with significant demands and these demands are greater, the larger the number of resonators n is, the more resonators are connected in series, and the more numerous are the secondary signal paths. Tuning conducted on a resonator can require corrections on adjacent resonators, those of the main signal path, and also possibly secondary signal paths, starting from the corresponding resonator. In the filters known from U.S. Pat. No. 6,337,610 B1, coupling between main signal paths is also possible via the common input and output resonators.
The task of the present invention is to provide a band pass filter, whose structure permits a simpler, faster and therefore more cost-effective filter implementation than the previous filter structures.
The filter according to the invention is characterized by the fact that the several main signal paths that run from its input to its output have no common resonators at the input and/or output, i.e., they are connected via different resonators to the input and/or output. A change made on one of the main signal paths can influence the behavior of the other main signal path, at best, via a single common resonator at the input or output of the filter, and is therefore easy to handle in a simulation.
The main signal paths preferably have no common resonators either at the input or output of the filter. Mutual influencing of the main signal paths is then ruled out and they can be optimized fully independently of each other.
None of the main signal paths of the filter according to the invention runs through all n resonators of the filter, so that a transmission function can be assigned to each of these main signal paths, which corresponds to a smaller wave number than the total number n of resonators. Amazingly, by overlapping of these transmission functions, a total transmission function of the filter according to the invention that corresponds to an ordinary filter with a single main signal path through all end resonators is obtained. The advantage of the filter structure according to the invention, however, is that its main signal paths, because of the smaller wave number, can be implemented at lower cost that those of the ordinary filter, and that changes that are made during optimization on a resonator pertaining to only one of the main signal paths essentially affect only the transmission function of this main signal path and leave the other main signal paths uninfluenced. The problem of implementing an n-pole filter can then be broken down into implementation of several partial filters corresponding to a main signal path with a smaller wave number, these partial filters each having free parameters that can be optimized without changing the transmission functions of the other partial filters.
The filter structure according to the invention is applicable to a number of filter types that are described below in conjunction with the figures, with reference to practical examples.
a, 1b show examples of structures of a filter according to the invention with four resonators;
a, 4b show coupling matrices for implementation of the filter with the behavior depicted in
a, 7b show two sections through a first modification of the filter from
a, b show two sections through a second modification of a filter from
a to 1b each show a filter structure according to the invention in comparison with the ordinary filter structure of
In the ordinary filter structure, a signal path extends from input S of the filter to output L, passing through all four resonators 1 to 4 of the filter in series. The resonators 1 to 4 of the main signal path are strongly coupled to each other, so that the comparatively weak direct coupling of the resonators 1 and 4 to each other via the secondary signal path 5, depicted with a dashed line, during calculation of the behavior of the filter can be treated as a disturbance in the filter, characterized essentially by the main signal path.
In contrast to this, in the filters of
Since the main signal paths, in the case of
It is apparent that direct coupling between resonators 1 and 4 is much smaller than the coupling coefficients of the main signal path, so that direct coupling can be interpreted as a small correction of the signal mostly transmitted on the main signal path.
The trend of the transmission and reflection function as depicted in
In an opposite end of the resonator cavities 11, 12, there are iris diaphragms I12, I34, which discharge on cavities 12, 14, embodying series-connected resonators 2 and 4. The position and configuration of the iris diaphragm I12 corresponds to that of IS1, except for the dimensional differences reflecting the magnitude of the coupling coefficient, so that coupling between resonators 1 and 2 is again inductive; on the other hand, the iris diaphragm I34 is slit-like and extends in the immediate vicinity of a side wall of the resonator cavities 13, 14 over their entire width (in the x-direction) and is capacitive on this account. A negative coupling coefficient between resonators 3, 4 is thus obtained.
Iris diaphragms I2L, I4L, which couple the resonator cavities 12, 14 to the output connection 16, again have the same configuration as the iris diaphragms IS1, IS3. Tunings of resonator frequencies of cavities 11 to 14 that can be required because of different couplings between the resonators are achieved by tuning the widths of the cross sections or other tuning means known from prior art, for example, screws, pins, etc.
Since the two main signal paths S, 1, 2, L and S, 3, 4, L are fully separated from each other between the input and output connection, the corresponding parts of the filter can be developed independently of each other and tuned in production, in order to satisfy the corresponding requirements of the coupling matrix. The connection of both main signal paths at the input S and output L requires only slight corrections, since the interaction between the two is limited. The development and production are therefore reduced to implementation of two partial filters, consisting of the resonators 1, 2 and 3, 4, which is much simpler than the usual development or tuning of a filter with four series-connected resonators, and the sensitivity of the behavior of a finished filter relative to manufacturing scatter also diminishes, since the effects of such scatter in a main signal path are essentially restricted to it, and the second, or optionally other main signal paths that can be present in more complex filter structures than those shown here are not affected detrimentally.
The input and output S, L of the filter are formed by coaxial line sections 30 and 31, whose external conductors 32 are each connected to housing 20, whereas their internal conductor 33 is short-circuited to the partition 21.
The coupling coefficients between the input S, the different resonators 1, 2, 3, 4 and the output L are tunable by means of tuning screw 34, 35. Tuning screws 34, guided through the bottom of housing 20, near internal conductor 23, determine the coupling of input S to the resonators 1, 3. Screws arranged in the vicinity of output L in a mirror image of screws 34 for tuning of the coupling between resonators 2 and 4 and output L are covered and not visible in the figure. The tuning screws 35, which are inserted into the side walls of housing 20 and, with their tips, lie opposite a transverse plate of the cross-like partition 21, serve for tuning the coupling between resonators 1 and 2 or between 3 and 4.
a, 7b show a first modification of the filter from
The metal wire 36 is bent into a circle in a horizontal plane, and its two ends resting on wall 21 face each other. The metal wire 37, on the other hand, is bent S-shaped in the same horizontal plane; its two ends are supported on wall 21 on the sides of hole 29 facing away from each other, through which it is guided. If we assume that the wave types excited in chambers 22, 24 are of the same phase, it is easy to comprehend that, because of the different geometries of metal wires 36, 37, magnetic fields with opposite direction or a phase differences of π can be excited in chambers 23, 25, i.e., the coupling coefficients between resonators 1, 2, on the one hand, and resonators 3, 4, on the other hand, have opposite signs.
A similar effect is achieved in the variants of
Whereas in wire 38, both free ends are deflected to the same side in the direction of the longitudinal center plane of the filter, defined by the internal conductor 33, those of the wire 39 are deflected to opposite sides. These two wires 38, 39 assure probe coupling between resonators 1, 2 and 3, 4, each with opposite signs of the coupling coefficients.
The pass band 43 between resonator element 45 is free, except for a tip of a tuning screw 48 that extends into the pass band, which serves for tuning the coupling between the two resonators of pass band 43. The pass band 44 is blocked between these two resonator elements 45 on part of its cross section by a partition 49. A tuning screw (not shown) that is arranged in the same manner as the tuning screw 48 depicted for the pass band 43 in wall 46 and is opposite the upper edge of partition 49, permits tuning the coupling coefficient between resonators 3, 4 of pass band 44.
Whereas the coupling between resonators 1, 2 of pass band 43 is inductive in nature, capacitive coupling of resonators 3, 4 is achieved by the partition 49 in pass band 44.
The strip conductor resonators 61, 62, 63, 64 are coupled to each other and to an input conductor S and an output conductor L, extending parallel and closely adjacent to each other over part of their length. In the main signal path formed by the strip conductors S, 61, 62, L, the strip conductors 61, 62 are arranged so that the signal propagation direction from input S to output L, each shown by arrows, is oriented in the same direction in the sections of the strip conductors connected to each other. In this way, the same sign of the coupling coefficient is obtained for all couplings on a main signal path S, 61, 62, L. In contrast to this, on the main signal path S, 63, 64, L, the sections of the strip conductors 63, 64 connected to each other have oppositely oriented signal propagation directions, so that a coupling coefficient with a negative sign results between these two strip conductors.
Generally, the length of the strip conductor resonators can be nλ/2, in which n is a small natural number. When n is greater than 1, it is also possible to achieve different signs of the coupling coefficients on the main signal paths to produce couplings between the different half-waves of the standing waves excited in the resonators, similar to the practical example described below with reference to
The coupling coefficients on the individual iris diaphragms are established by their position relative to the field distribution in the cavities connecting them, as well as their cross section area. The diaphragms IS2, IS3 each couple the left half-wave of input S in the signal propagation direction (from left to right in
The diaphragms I24 and I34 are laid out so that the first half-wave of resonator 4 is coupled essentially to the third half-wave of resonator 3 and the second half-wave of resonator 2, i.e., to half-waves with opposite sign. In this way, coupling coefficients with different sign can be obtained for coupling to diaphragm 134 and to diaphragm 124.
Number | Date | Country | Kind |
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102 08 666 | Feb 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB03/01061 | 2/28/2003 | WO | 00 | 5/11/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/073606 | 9/4/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3345589 | Di Piazza | Oct 1967 | A |
4477785 | Atia | Oct 1984 | A |
4725797 | Thompson et al. | Feb 1988 | A |
5097236 | Wakino et al. | Mar 1992 | A |
5699029 | Young et al. | Dec 1997 | A |
6337610 | Williams et al. | Jan 2002 | B1 |
Number | Date | Country |
---|---|---|
0 541 284 | May 1993 | EP |
1 148 576 | Oct 2001 | EP |
1062269 | Mar 1967 | GB |
62097404 | May 1987 | JP |
Number | Date | Country | |
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20050212622 A1 | Sep 2005 | US |