DE102006061141A1 - High frequency filter used in digital mobile technology has a transfer behavior with a coupling impedance resonance with a blocking site at a specified frequency - Google Patents

Abstract

High frequency filter has a transfer behavior with a coupling impedance resonance with a blocking site at a specified frequency. The blocking site can be adjusted at the specified frequency by prescribing and/or selecting a defined capacitive and inductive coupling between two coaxial resonators (15) directly connected to a signal path (10). Preferred Features: n-coaxial resonators are coupled together on the signal path. The filter has band pass filters and a pair of coaxial resonators lying directly next to each other in the signal path have a trap circuit coupling per band pass filter.

Description

The The invention relates to a high frequency filter with blocking circuit coupling according to the preamble of claim 1.

High frequency filter are used in a wide range.

For example in digital mobile technology, the communication of the mobile subscriber with the base station over Transceiver antennas that are provided in the base station are. It is desirable for the Transmit and receive signals to use only a common antenna.

Send- and receive signals use different frequency ranges. The antenna used must transmit and receive in both frequency ranges be suitable. To separate the transmit and receive signals is a appropriate frequency filtering is required, which ensures, on the one hand the transmission signals from the transmitter only to the antenna (and not in the direction Recipient) and on the other hand, the received signals from the antenna are only forwarded to the receiver become.

To For this purpose a pair of high-frequency filters can be used, both of them, namely the respectively desired Pass frequency band (bandpass filter). It can also be one Pair of high-frequency filters are used, which is a specific, namely the respectively unwanted Lock frequency band. One speaks here of band-stop filters. Is possible furthermore, the use of a pair of high-frequency filters, consisting of a first filter that has frequencies below one between the transmit and receive band frequency passes and the about that lying areas (low-pass filter), and a second filter, which frequencies below this between the transmit and receive band lying frequency locks and lets pass the higher frequencies. It is then a so-called high-pass filter. Other combinations from the mentioned types of filters come into use.

The Transmit-Empfangsaufaufplittung within the base station is doing usually performed with duplex switches, which have the mentioned task, the send-receive path as possible without feedback to switch together to the common antenna. The duplexer consists of two interconnected bandpasses, namely the so-called transmit bandpass (TX bandpass) and the receive bandpass (RX bandpass), wherein separate connections for the reception branch, the transmission branch and the jointly connected antenna are provided.

The Bandpasses used within the duplex switch Müs sen on the one hand to the Interconnection of the transmission and of the receive bandpass (TX / RX) Selection (ie the necessary Blocking attenuation) and should, on the other hand, be in their respective passband the useful signals as possible little steaming.

The Bandpass structures used in duplex switches are used in the common mobile radio frequency ranges (eg GSM / UMTS) predominantly Coaxial resonators constructed.

Construction and operation of coaxial resonators are known from the prior art, for example "Ian Hunter: Theory and Design of Microwave Filters", IEE Electromagnetic Waves Series, no. 48, 1. Microwave filters, page 197 ,

In filter theory, band passes (so-called Cauerband passes) are described, which have transmission zeroes (so-called blocking poles) in the stop band. This type of filter is very often realized in conjunction with coaxial resonators by so-called cross-coupling (overcoupling). In this case, non-adjacent resonators (ie, in the waveform not directly consecutive resonators) within a bandpass structure such capacitive or inductive coupled together that arise due signal splitting with subsequent phase-shifted merge amplitude cancellations (transmission zeros or blocking points) in the transmission characteristic. Such a cross-coupling technique is z. As described in IEEE Transactions on microwave theory and techniques, Vol. 51, no. 4, April 2003 "Cross-Coupling in Coaxial Cavity Filters - A Tutorial Overview", J. Brian Thomas, pages 1368-1376 ,

The But so-called cross-coupling has the disadvantage that the necessary Coupling resonators needed which are not adjacent to each other, so not consecutive are arranged. However, this requires filter topologies, which makes this coupling mechanically possible.

by virtue of The limited number of suitable pairs of resonators for cross-coupling may vary from therefore only a limited number of blocking poles are generated.

A generic high frequency filter with blocking circuit coupling, in particular in the form of a duplexer is basically from WO 2004/100305 A1 to be known as known. It is a high frequency filter with meh reren resonators, which are arranged between three terminals, namely between a terminal for a transmitting branch, a terminal for the receiving branch and a connection for the common antenna.

According to the generic Prior art is to improve such a duplexer provided that they at least a strongly coupled with each other Resonator pair, wherein the strongly coupled with each other Resonators in the coupled state in two different Coupling resonance frequencies oscillate that are different from the Resonant frequency, which is the two strongly coupled resonators for yourself considered in each case in the frequency range between the transmitting and receiving band have or on which the resonators are tuned.

task In the present invention, it is an improved high frequency filter to provide that improved passage and / or barrier action for specifiable Has frequencies or frequency ranges, with limitations in terms of the filter topology as possible should not be given.

The Invention is according to the features specified in claim 1 solved. Advantageous embodiments of the invention are specified in the subclaims.

According to the invention Improvement over achieved in the prior art, that the high-frequency filter, the electromagnetically coupled coaxial resonator comprises at least a selected one Coaxial resonator pair, whose two coaxial resonators in the transmission path immediately adjacent to each other, a special vorwähl- and / or assignable pre-adjustable coupling impedance that is dimensioned that is due to the combination of capacitive and inductive Coupling a coupling impedance with a defined blocking frequency results. Because this type of coupling in the transmission behavior of the high-frequency filter generates a blocking point, it will also be referred to below as blocking circuit coupling designated.

With other words lets Thus, in the context of the invention, this blocking circuit coupling, so the Notch frequency, so that they lie outside the passband of the RF filter, and on the other hand within the stop band of an RF filter lies.

Prefers let yourself the blocking frequency especially by changing and / or setting and / or Preselection of two essentially influencing the blocking frequency or determinate sizes. It is crucial that in addition to a defined inductive Resonator coupling a defined capacitive coupling takes place. The defined inductive coupling can be z. B. over the distance to be coupled Resonators are set. The required capacitive coupling let yourself In contrast, z. B. by an elongated Enlargement at the top of the resonators to be coupled realize. Even if the change each of the above two variables has some influence also applies to each other's size, so can but by specifying the inductive and the capacitive coupling the desired coupling so changed adjacent resonators set that to the desired damping outside the passband of an RF filter and within a stopband an RF filter is located.

• • Erstmals können nunmehr benachbarte Resonatoren so verkoppelt werden, dass darüber Sperrstellen erzeugt werden. Dies bietet den wesentlichen Vorteil, dass bei der Realisierung von Hochfrequenzfiltern keine derartigen Einschränkungen bei der Konzeption von Filter-Topologien, also bezüglich der Anordnung der Koaxialresonatoren, vorliegen, wie beim Stand der Technik. Beim Stand der Technik bestand der gravierende Nachteil, dass beim sogenannten "Cross-Coupling" (also bei der Herstellung einer Überkopplung) die notwendige Verkopplung nicht zwischen benachbarten Resonatoren durchgeführt werden konnte. Dies erforderte dann ganz spezifische Filter-Topologien, um eine Verkopplung zwischen zwei nicht benachbarten Resonatoren zu ermöglichen.
• • Da im Rahmen der Erfindung eine Verkopplung zweier benachbarter Resonatoren möglich ist, bietet dies grundsätzlich auch die Option, beliebige mehrere benachbarte Paare von Resonatoren miteinander zu verkoppeln. Es können im Rahmen der Erfindung bei n-Resonatoren sogar n – 1 Sperrstellen erzeugt werden, also viel mehr als bei einem konventionellem Cross-Coupling.
• • Im Rahmen der Erfindung kann zur entsprechenden Einstellung der kapazitiven Kopplung der Abstand zwischen zwei Innenleitern dadurch verringert werden, dass diese mit radialen Verlängerungen an ihrer Oberseite versehen sind. Dies kann auch zu einer Verringerung der Gesamtbauhöhe des Filters genutzt werden.

Within the scope of the invention, therefore, the following essential advantages can be realized:

• • For the first time, adjacent resonators can now be coupled in such a way that blocking positions are generated via them. This offers the significant advantage that, in the implementation of high-frequency filters, there are no such restrictions in the design of filter topologies, ie with regard to the arrangement of the coaxial resonators, as in the prior art. In the prior art there was the serious disadvantage that in the so-called "cross-coupling" (ie in the production of a cross coupling), the necessary coupling could not be performed between adjacent resonators. This then required very specific filter topologies to allow coupling between two non-adjacent resonators.
• As a coupling of two adjacent resonators is possible within the scope of the invention, this basically also offers the option of coupling any number of adjacent pairs of resonators to one another. In the context of the invention, it is even possible to produce n-1 blocking sites in the case of n resonators, ie much more than in the case of a conventional cross-coupling.
• In the context of the invention, for the corresponding adjustment of the capacitive coupling, the distance between two inner conductors can be reduced by providing them with radial extensions on their upper side. This can also be used to reduce the overall height of the filter.

The The invention will be explained in more detail with reference to drawings. there show in detail:

1 : The schematic structure of a high-frequency filter in the case of a duplex switch in a schematic basic representation;

2 a schematic plan view of a high-frequency filter with a signal path;

3 a schematic axial section along the line III-III in 2 ;

4 : An equivalent circuit diagram with respect to the imple mentation example 2 and 3 ;

5 FIG. 2 is a diagram for representing the transmission and attenuation behavior of a bandpass filter according to the invention for a duplexer; FIG. and

6a to 6f : different representations for different settings of a coupling capacity or coupling inductance.

In 1 is a schematic representation of a high frequency filter in the form of a duplexer 3 shown, the RF filter 1 three connections 5 . 7 and 9 comprising, namely a terminal TX, RX and a port for the antenna port AP, so that transmission signals over a first signal path from the transmission port 5 coming from the antenna port AP (from there the common antenna) and vice versa, the signals received by the antenna via the antenna port AP (connection 9 ) to the receiving terminal 7 can be supplied.

The duplexer 3 includes in the two signal paths a corresponding bandpass filter 11 respectively. 13 , which have the necessary selection (ie blocking attenuation), so that no signals can get into the reception branch of the transmission terminal. On the other hand, the pass-bands for the useful signals should be damped as little as possible.

In 2 For this purpose, for example, in schematic plan view (omitting an upper cover) a high-frequency filter 1 with a signal path 10 shown, the example of a connection 5 to a connection 9 that is, from a transmitting port to an antenna port port (that is, showing only one branch of a duplexer) and thereby six coaxial resonators 15 includes.

The coaxial resonators 15 are in a conductive housing 17 with several resonator chambers 19 arranged where in the illustrated embodiment, centrally or rather in the central region perpendicular to the housing bottom 17a each a conductive inner conductor 21 extends - as can be seen from the illustration according to 3 results - at a suitable distance below one on the housing 17 attachable electrically conductive housing cover 17b ends.

Each coaxial resonator 15 thus has a circumferential housing wall 17c on, along the signal path coupling openings 23 , so-called apertures, in the respective housing wall 17c are provided, whereby windows are formed, through which the electromagnetic waves can propagate.

At the coaxial connections 5 and 9 are in a known manner inner conductor 5a respectively. 9a provided in the associated resonator chambers 19 protrude into and, for example, in a conductive surface elements 5b respectively. 9b over what with the associated inner conductor in the respective coaxial resonators 15 by the capacity thus formed, the coupling of the electric field during connection 5 and the corresponding coupling of the electric field during connection 9 (for example, vice versa, the signal received by the antenna over the conductive surface elements 9b is coupled into the associated resonator on the second signal path, and via a second signal path to an in 2 not shown in detail 7 leads). Therefore, in 3 only a schematic sectional view, for example, by a section for the intended for the transmitting branch bandpass filter 11 represented by the in 3 left-side glare gate 23a the signal path for the second in 3 not shown receiving branch of the duplex could connect.

With regard to the explained signal path from terminal 5 to the terminal 9 are six coaxial resonators in this way 15.1 to 15.6 coupled together.

The corresponding equivalent circuit diagram is in 4 reproduced, with the signal path 10 from the connection 5 to the connection 9 , where the six resonators 11 as parallel resonant circuits 111 are shown, whose one output is grounded and the opposite output in the appropriate order on the signal path 10 connected. The parallel resonant circuits 24 are characterized in a known manner by a capacitor and an inductance. The distances between the connection points 25 the individual parallel resonant circuits 24 can also by inductors 27 are described, as far as it is conventional couplings between coaxial resonators, so not to the coupling of the invention explained below. As far as a coupling according to the invention comes into play, the connection between two adjacent parallel resonant circuits coupled together according to the invention can not be described by an inductive coupling, but by a blocking circuit coupling in the form of a parallel resonant circuit with a capacitance and an inductance, as described in US Pat 4 is shown. Between the first and fifth coaxial resonator 15.1 respectively. 15.4 As in the prior art, a capacitive cross-coupling using a capacitor C is additionally realized (see 2 and 4 ).

According to this equivalent circuit diagram 4 It is shown that between the first and the second coaxial resonator 15.1 and 15.2 and between the second and third coaxial resonators 15.2 and 15.3 as well as the third and fourth coaxial resonators 15.3 and 15.4 a coupling according to the invention is realized. In addition, in the embodiment shown, a conventional coupling (cross-coupling) between the first and the fifth coaxial resonators according to the prior art 15.1 and 15.5 which will also be discussed below.

From the page representation according to 3 It can be seen that for the coupling of the immediately adjacent resonators, ie in the signal run immediately following one another 15.1 and 15.2 the associated inner conductor lying in their connecting direction in each case with mutually facing, radially projecting inner conductor sections 21a are provided. This will clear the clearance 121 between the two inner conductors 21 adjusted so that this results in a desired capacitive coupling.

This capacitive coupling is for example between inner conductor sections 21a on the two inner conductors 21 the first two coaxial resonators 15.1 and 15.2 in 3 represented by correspondingly drawn E-field vectors 121 ( 2 ).

In addition, in 3 also for the first two resonators 15.1 and 15.2 an inductive coupling through an H-field line 121 ' shown. By specifying the distance 221 between the two inner conductors 21 (Regardless of the mentioned radially projecting inner conductor sections 21a ) is ultimately the inductive coupling 221 ' selected and / or set accordingly.

The but inductive coupling can be achieved by other alternative or complementary, So additional measures different preset or preselected. Generally is noted that for the setting of the blocking circuit coupling necessary coupling capacitances and coupling inductances can be adjusted by known Koppeleinstellvarianten. So can For example, the coupling diaphragms (ie the passages between two adjacent coaxial resonators in height and / or Width can be set differently, reducing the degree the coupling changes). As well can Coupling pins should be provided between the resonators, coupling loops or coupling webs. The coupling webs would, for example, in a partial height run between two inner conductors, so also parallel extend to the inner conductors (preferably perpendicular to the bottom wall) and thereby electrically connected to the bottom of the coupling resonators be. The coupling loops can in the manner of an inverted U-bracket electrically and mechanically connected between two internal conductors on the ground be. Possible is also that a coupling loop in vertical orientation (ie lying in a vertical plane) or in a slightly inclined plane over a vertical axis of rotation opposite the Floor is positioned and can be rotated in the circumferential direction. The bigger the from the magnetic surfaces interspersed area is, the bigger it is the coupling effect. The mentioned Effects can also used in combination or parts thereof in combination, to the desired Koppeleinstellmöglichkeiten to realize and implement accordingly.

The above-mentioned settings are, for example, based on 6a using electrically conductive coupling pins 301 reproduced, with one example in the upper lid 17b 301 the change to change the coupling capacity between two inner conductors 21 at different altitudes, so can be differently far in the interior between two resonators can be screwed, wherein in 6a also one in the ground 17a screwed or positioned there electrically conductive coupling pin 302 is arranged, whose height and diameter contributes to the change in the coupling inductance. Based on 6b is shown in plan view that along the connecting line of two adjacent inner conductor 21 a rising from the ground. Web is provided, which extends there compared to the height of the inner conductor in a partial height. It is a so-called coupling bridge 307 , This coupling bridge 307 is with the ground 17a of the housing 17 of the RF filter electrically connected.

According to a further embodiment according to 6c in plan view and according to 6d in vertical section is shown that, for example, a first window opening 303 (Coupling diaphragm) between the coaxial resonator 15.1 and 15.2 is significantly reduced and in contrast, a further coupling panel 303 between the resonator 15.2 and 15.3 is significantly increased, so that the coupling panel in any case has a greater width parallel to the bottom or top surface.

In the embodiment according to 6e is a coupling loop 305 shown to change the coupling inductance, which is positioned in the manner of an inverted "U" in the ground. Alternatively, by means of 6f the use of a coupling loop shown around its vertical axis 305 ' to be twisted can, so that the magnetic field strength, which passes through the loop, changed, whereby the coupling inductance can be changed and adjusted differently.

All Generally it is noted that the most diverse possibilities to produce a desired capacitive, as well as a desired inductive coupling can be combined as desired, rather, even all the aforementioned variants cumulatively applied can be. restrictions do not exist in this respect.

Due to the different design of the coaxial resonators 15 With the described deviating resonator shape, the desired blocking position can be generated with a defined blocking frequency outside the passband of an HF filter. It is crucial that in addition to the mentioned defined inductive resonator coupling a defined capacitive coupling is present. The aforementioned inductive coupling can, as mentioned by the distance 221 the resonators to be coupled (position of the inner conductor 21 the resonator in question), whereas the capacitive coupling across the clear distance 121 between two adjacent inner conductors 21 is set two neigh barter resonators whose size by the clear distance of said elongated (radially projecting) inner conductor extensions 21 can be specified.

In the embodiment shown is in addition to the coupling between the first and second coaxial resonator 15.1 and 15.2 as a result, a further immediately subsequent coupling between the second and third coaxial resonator 15.2 and 15.3 realized.

In deviation to the first inner conductor 21 of the first coaxial resonator 15.1 , which is formed in a cross-sectional view in the manner of an inverted L, is now the second inner conductor of the second coaxial resonator 15.2 formed in the manner of a T-shaped, namely with a further, generally parallel to the ground and thus transversely or radially to the inner conductor projecting, opposite inner conductor extension 21a , Also the third inner conductor to be coupled with it 21 of the third coaxial resonator 15.3 could also with a corresponding inner conductor extension 21a be provided, wherein the distance between these two adjacent inner conductor extensions 21a is much larger than the distance between the first and second coaxial resonators. In the example of the coupling of the second and third coaxial resonator is also an additional bridging member 221 ' provided, which is held and positioned isolated from the housing. This results in two distance columns 121 and 121b in which the electric field vectors propagate over air. The sum distance formed from the two individual distances 121 and 121b gives the quantity which is decisive for the specification of the desired defined capacity coupling.

Finally, according to the plan view 2 also to see that now by the further coupling between the third and fourth coaxial resonator 15.3 and 15.4 the associated inner conductor 21 not two 180 ° opposite inner conductor extensions (like the second inner conductor 21 of the second coaxial resonator 15.2 ), but two inner conductor extensions 21a has, which are arranged at a 90 ° angle to each other, namely according to the 90 ° angled signal path of the electromagnetic waves. That the two inner conductors 21 with respect to the second and third resonators 15.2 and 15.3 are positioned denser, results from the illustration according to 2 in plan view.

If the explained signal path represents, for example, the one signal path of a duplexer, this can realize a bandpass filter, as is shown in FIG 4 is reproduced, with one or more blocking frequencies f _S , so one or more so-called Sperrpolen. This transmission characteristic shows that, in accordance with the number of coaxial resonators coupled within the scope of the invention, the multiple blocking poles (blocking frequencies) can be generated such that these blocking frequencies lie, for example, in the passband (frequency range) of an adjacent bandpass filter which is offset.

In the exemplary embodiment shown, another coupling according to the invention can likewise be implemented at any other arbitrary point, that is to say, for example, between the fourth and fifth and / or fifth and sixth coaxial resonators. In general, in n-coaxial resonators so five, namely n - 1 Koppelim pedanzen dimensioned so that due to the communication of capacitive and inductive coupling a coupling impedance with each defined frequency f _S results, so by the nature of the coupling in the transmission behavior of the high-frequency filter Locking point at the at least one or more mutually offset frequencies f _S1 , f _S2 , f _S3 , etc. to f _Sn , results, which can be referred to as blocking circuit coupling.

In the exemplary embodiment shown, a conventional coupling is additionally realized, which can also be additionally provided in the case of the HF filter according to the invention. This conventional coupling (cross-coupling) is also in the equivalent circuit diagram according to 4 located there, namely there on the link 131 with the capacitor C provided there.

This is for example in 2 a coupling element 31 shown, which acts between the first and fifth coaxial resonator and is usually formed by an electrically conductive, in the respective cavity of the associated resonator protruding, in side view "bone-shaped" coupling element, which usually by its enlarged opposite end with the associated inner conductor generates a capacitive coupling in the respective coaxial resonator. This is also shown in the equivalent circuit diagram, namely by the capacitive coupling path 131 ,

In contrast, in the context of the invention is a blocking circuit coupling 35 realized with a parallel-connected inductance and a capacitance, as shown in the replacement circuit diagram according to 4 also shown.

Finally it will open 5 Reference is made to the diagram of the bandpass performance of a bandpass filter 11 for a transmission branch and for a bandpass filter 13 for a reception branch (in dashed lines) is reproduced. This shows the number of blocking poles f _Rs , f _TS , depending on the number of blocking circuit couplings used. In 5 is on the X-axis, the increasing frequency F and reproduced on the Y-axis damping D.

For the one Bandpass filter is also shown how the attenuation would go if not the coupling according to the invention would be realized (dash-dotted curve).

at the bandpass filter according to the invention can the at least one or more barrier poles are so placed for example, in one of them to the passband of the subject Bandpasses offset frequency range of an adjacent Bandpasses lie. In any case, sufficient benefits according to the invention can then be achieved be realized when the one or more locking poles completely or at least partially arranged so that they are outside the actual passband of the bandpass filter in a frequency range that of the center frequency of the bandpass filter in question less than ± 50%, in particular less than ± 40%, ± 30%, ± 20% and in particular less than ± 10% is removed.

in the Case of two mutually offset bandpass passage frequency ranges, as they most often Case can be used as part of a duplexer, the Advantages of the invention even then be realized to a sufficient degree, though at least one or more of the blocking poles (blocking points) of one considered bandpass filter by appropriate choice suitable coupling capacities and coupling inductances is placed so or are that this at least one Sperrpol is generated in a frequency range of not more than five times the duplex distance (ie the frequency center distance of two adjacent Bandpasses) from the center frequency of the relevant bandpass is removed. Prefers So should the Sperrpole viewed from a bandpass filter outside the Passage region of the bandpass filter be arranged so that the blocking poles no more than fivefold, especially not farther than the fourfold, threefold, twofold or the simple of the duplex distance (ie the center frequency distance of second adjacent Bandpass filters) to come to rest.

Independently of can Naturally one or more of the blocking poles also in a frequency range be positioned the adjacent bandpass.

Finally, it will noted that with appropriate choice of inductive or the capacitive coupling can be determined whether the respective Sperrpol below a bandpass filter or above a bandpass filter (ie with the bandpass filter of lower frequency or higher frequency) is trained. This is achieved by the coupling capacity and the Coupling inductance of Block circuit coupling selected be that the resulting resonant frequency as needed either is below or above the Bandpassdurchlassbereiches.

Claims (21)

High-frequency filter, in particular for a duplexer with a plurality of electromagnetically coupled coaxial resonators ( 15 ), characterized in that the high frequency filter has a transmission behavior with a coupling impedance resonance with at least one locking point at a frequency (f _S ), wherein the locking point at the frequency (f _S ) by presetting and / or preselection of a defined capacitive and inductive coupling between two on a signal path ( 10 ) immediately successive coaxial resonators ( 15 ) is adjustable. High-frequency filter according to claim 1, characterized in that the at least one coupling capacitance and the at least one coupling inductance are selected such that the at least one blocking position is at a frequency (f _S ) which does not exceed ± 50% of the center frequency of the bandpass filter not more than ± 40%, ± 30%, ± 20%, and in particular not more than ± 10% from the frequency of the bandpass filter. High-frequency filter according to Claim 1 or 2, characterized in that n-coaxial resonators ( 15 ) on a signal path ( 10 ) are coupled together, with more than one and less than n - 1 blocking circuit couplings are provided. High-frequency filter according to one of Claims 1 to 3, characterized in that the high-frequency filter ( 1 ) comprises at least two band-pass filters, wherein the per band-pass filter comprises at least one pair of adjacent coaxial resonators (7) immediately following one another in the signal path. 15 ) has a blocking circuit coupling with a frequency (f _S ) such that the blocking point is outside the passband of the bandpass filter in question, wherein preferably at least one blocking point lies in the passband of the other bandpass filter. High-frequency filter according to Claim 4, characterized in that the at least two bandpass filters form part of a duplexer ( 3 ) are. High-frequency filter according to claim 4 or 5, characterized characterized in that the at least one locking point or preferably the multiple stops from the center frequency of a bandpass filter consider no more than five times the duplex spacing, d. H. the center frequency spacing of the two bandpass filters one Duplexer are removed, preferably less than four times, triple, double or in particular the simple of duplex spacing lies or lie away. Radio-frequency filter according to one of Claims 1 to 6, characterized in that a plurality of signal paths ( 10 ) directly successive Koaxialresonator pairs to produce a plurality of defined blocking circuit couplings with defined frequencies (f _S1 , f _S2 , f _S3 , ...) are provided, wherein the blocking frequencies are at least partially different or at least partially the same. High-frequency filter according to claim 7, characterized in that the capacitive and the inductive coupling can be predetermined so that the at least one frequency (f _S ) of the associated blocking circuit coupling has a lower frequency or a higher frequency than the bandpass filter. High-frequency filter according to one of claims 1 to 8, characterized in that the degree of capacitive coupling between two adjacent inner conductors ( 21 ) of two adjacent coaxial resonators ( 15 ) by radially in the direction of the respectively coupled adjacent inner conductor ( 21 ) with radially projecting inner conductor extension ( 21a ) and thus by appropriate specification of the clear distance ( 121 ; 121 . 121b ) between two corresponding inner conductors ( 21 ) or associated inner conductor extensions ( 21a ) can be specified. High-frequency filter according to claim 9, characterized in that the inner conductor extension ( 21a ) transversely and preferably perpendicular to the axial extent of an associated inner conductor ( 21 ) in the upper end region of the inner conductor ( 21 ) is formed. High-frequency filter according to claim 9 or 10, characterized in that the inner conductor ( 21 ) with a corresponding inner conductor extension ( 21a ) is formed in the manner of an inverted L-shaped. High-frequency filter according to claim 10, characterized in that an inner conductor ( 21 ) with one in the signal path ( 10 ) preceding and following coaxial resonator ( 15 ) is coupled to produce two blocking circuit couplings, including the associated inner conductor ( 21 ) both in the direction of the preceding and the subsequent coupled coaxial resonator ( 15 ) with an inner conductor extension ( 21a ) is provided. High-frequency filter according to claim 12, characterized in that the inner conductor ( 21 ) with the associated inner conductor extension ( 21a ) Is T-shaped. High-frequency filter according to one of claims 1 to 13, characterized in that between two inner conductors ( 21 ), preferably in the upper free end region, a free path between the two inner conductors ( 21 ) shortening, electrically conductive bridge member ( 221 ' ) is provided, which at a distance to the respective inner conductors ( 21 ) or the inner conductor extensions ( 21a ), whereby a predefinable sum distance, consisting of the two clearances ( 121 . 121b ) between the bridge member ( 21b ) and the adjacent inner conductors ( 21 ) or the associated inner conductor extensions ( 21a ), can be predetermined, whereby the capacitive coupling is adjustable. High-frequency filter according to one of claims 1 to 14, characterized in that from the opposite side of the housing (cover 17b ) of the housing ( 17 ) of the coaxial resonator ( 15 ) a coupling pin ( 301 ) between two adjacent coaxial resonators ( 15 ) protrudes into the resonator interior to the changed setting of the coupling capacity. High-frequency filter according to one of Claims 1 to 15, characterized in that the inductive coupling between two adjacent coaxial resonators ( 15 ) by specifying the distance ( 221 ) between the position of the inner conductors ( 21 ) and / or from the housing bottom or the housing cover ( 17a . 17b ) transversely extending inner conductor ( 21 ) is vorgeb- and / or changeable. High-frequency filter according to one of Claims 1 to 16, characterized in that the inductive coupling between two adjacent coaxial resonators ( 15 ) by a different size of a coupling window ( 303 ) or a coupling panel ( 303 ) is vorgeb- and / or changeable between two adjacent coaxial resonators. High-frequency filter according to one of Claims 1 to 17, characterized in that the inductive coupling between two adjacent coaxial resonators ( 15 ) by coupling pins ( 302 ) can be preset and / or changed on the same side of the housing ( 17 ) like the inner conductors ( 21 ) on the housing ( 17 ; 17a ) are positioned. High-frequency filter according to one of Claims 1 to 18, characterized in that the inductive coupling between two adjacent coaxial resonators ( 15 ) by a coupling web ( 307 ) can be preset and / or changed between two inner conductors ( 21 ) extends in a partial height relative to the inner conductor and preferably on the same housing wall (housing bottom 17a ), on which the inner conductors ( 21 ) are electrically and mechanically connected and held. High-frequency filter according to one of Claims 1 to 19, characterized in that the inductive coupling between two adjacent coaxial resonators ( 15 ) by at least one coupling loop ( 305 ) can be preset and / or changed between two inner conductors ( 21 ) of two adjacent coaxial resonators ( 15 ), wherein the coupling loop ( 305 ) is bendable and / or rotatable for changing the coupling inductance. High-frequency filter according to one of claims 1 to 20, characterized in that the high-frequency filter in addition to a or more Sperrkreiskopplungen one or more capacitive overcouplings (Cross-coupling).