EP1212806A1 - High-frequency band pass filter assembly, comprising attenuation poles - Google Patents

Abstract

The invention relates to a high-frequency band pass filter assembly, comprising a master resonator and at least one stop-band resonator which is coupled thereto. The aim of the invention is to construct a filter structure in such a way, that with a given number of poles, the highest possible number of transmission zero positions occur in the stop bands, whereby in relation to known resonator configurations, no overcoupling is used between non-adjoining resonators. To this end, the stop-band resonator(s) is/are coupled to the master resonator in such a way that the stop-band resonator generates both transmission zero positions and transmission pole positions in tandem with the master resonator.

Description

High frequency bandpass filter arrangement with attenuation poles

The invention relates to a high-frequency bandpass filter arrangement, consisting of a main resonator and at least one blocking resonator coupled to the main resonator, the main resonator being defined by a line piece delimited on both sides by discontinuities in the form of an interruption or metal wall, and one at a center frequency Has electromagnetic natural vibration. In particular, the invention relates to the construction of bandpass filters from coupled resonators for the highly selective filtering of high-frequency electromagnetic signals in one

Operating frequency range, which is above approx. 0.5 GHz and below approx. 100 GHz.

High-frequency bandpass filters form an important component in systems of communication technology, such as B. in terrestrial and satellite-based broadcasting, radio and cellular as well as in radar and navigation systems. Here take over z. B. in radio receivers individual filters the function of preselection, that is the negative pressure of unwanted interference signals and filter banks the function of frequency sewerage. In radio transmitters, individual bandpass filters are used, among other things, to suppress out-of-band spectral components in the output signal of the amplifiers, and filter banks are used in the form of output multiplexers Merging different carrier signals on a common antenna.

With high-frequency bandpass filters, a distinction can first be made between active and passive designs. If high demands are placed on linearity and low noise, only the passive filters considered further here can be considered. The function of passive electromagnetic filters is based on the storage of electrical and magnetic field energy. In the case of filters made of discrete components, the storage of electrical and magnetic field energy takes place separately from one another, in a finite number of spatially separated discrete elements, namely in capacitors and inductors. Since the geometrical dimensions of these discrete components have to be much smaller than the operating wavelength, typically less than one tenth of the guided wavelength, and on the other hand the idle quality of these components decreases sharply with a reduction in dimensions, structures are preferred for steep-sided filters above approx. 1 GHz Coupled resonators used instead of interconnections of discrete capacitors and inductors.

A large number of different types are available for the designs of resonators, which are the building blocks of the filter class considered here. Coaxial resonators or cavity resonators are formed from coaxial TEM line pieces and waveguide pieces, in which the electromagnetic field is completely enclosed by conductive surfaces. These resonators can partially or to reduce the volume and change the spatial field profile completely filled with low loss dielectric material. In dielectric resonators, the field is mainly enclosed by the interface between the dielectric material and the surrounding air, and the field that decays outwardly from this interface is shielded by a metal housing, if necessary. Planar resonators, which include microstrip, stripline and coplanar resonators, consist of planar interconnects on a dielectric substrate.

The selection of the design of the resonators is u. a. influenced by the idling quality of the resonators required by the filter specification (see below). In conventional technology, a high idling quality means a relatively large geometric dimension of the resonators. On the other hand, the volume available for all the resonators of a filter is limited in the lower GHz range. The volume requirement is reduced by approx. 50% by using resonators in two ways using orthogonal modes

(Dual mode resonators). An exception to the rule that high no-load quality means large geometric dimensions is achieved when using cooled planar resonators made of high-temperature superconductors. A further technological development in the direction of compact high-quality resonators results from the progress in the development of extremely low-loss dielectric materials with a high dielectric constant for dielectric resonators. The selection of the resonator design also has the required performance compatibility

(Warming, multipacting) an influence. The electrical behavior of a bandpass filter is characterized by the frequency bandwidth (passband width) and the position of the passband, by the maximum insertion loss and minimum reflection attenuation in the passband, by the width of the transition areas between the passband and the stopband, and by the minimum blocking attenuation in the stopband.

For further quantitative characterization of the properties of a filter structure, the number N of attenuation zeros (reflection zeros) in the pass band and the number M of attenuation poles (transmission zeros) at finite frequencies in the stop band are used. This characterization by reflection zeros and transmission zeros is based on the behavior in the (fictitious) lossless case and zeros are paid several times according to their order.

To implement a bandpass filter, N _R resonators can be coupled to one another such that the overall system of coupled resonators has a total of N = N _R damping zeros in the region of the pass band (N = 2N _R when resonators are used twice). Furthermore, by means of suitable coupling measures (see below), a total of M <N damping poles (transmission zero points) can occur at finite frequencies in the restricted areas.

From the ratio of the transition width to the passage width (“relative slope of the filter edges”), the number N of the necessary zero damping points and thus the minimum number of necessary resonators follows. For the following description of the advantages achieved by the invention, it is of great importance that, given the relative steepness of the filter edges, the necessary number N of damping zeros in the pass band decreases monotonically with increasing M / N. For a given pass width, a smaller number N, and thus a smaller number N _R, of resonators are sufficient for a required edge steepness if, instead of a Chebyshev filter with M = 0, a quasi-elliptical filter with M> 0 is used. The required number N is further reduced if, instead of a quasi-elliptical filter with M <Nl, a "really elliptical" filter with M = Nl is used.

Due to the ohmic and dielectric losses in the resonators of the filter, the frequency response of the filter is degraded in such a way that the achievable steepness of the filter edges is limited by rounding effects and the dissipative evaporation in the pass band is increased. However, since this degradation depends in the first approximation only on N and not on the number M of the transmission zeros, filters with higher slope steepness and less dissipative evaporation damping can be realized for a given idling quality of the resonators if M / N is increased.

The way in which filters from coupled resonators are predominantly used today to produce transmission zeros consists in the introduction of couplings between non-directly adjacent resonators (“overcouplings”), in addition to the direct couplings of neighboring resonators. The conventional bandpass consists of a cascade of resonators, the inner resonators having at least their two neighbors coupled and the two outer resonators are coupled to the filter gates. Without additional coupling between non-adjacent resonators, no transmission zeros occur at finite frequencies, i.e. M = 0 applies. Overcouplings with a suitable strength and sign, i.e. couplings between non-adjacent resonators, lead to transmission zeros in the blocking areas, whereby pro Overcoupling, depending on the position of the coupling path, one to two transmission zeros are produced. If one strives for the largest possible ratio M / N and the greatest freedom in the choice of the frequency position of the individual transmission zeros for the reasons mentioned above, this leads to a coupling scheme which is referred to as a "canonical coupling structure" and with an even number N using N-2 different overcouplings leads to N-2 freely placeable transmission zeros. For M = N-2 zeros, which are symmetrical to the pass band, at least (N-2) / 2 overcouplings are required. The practical implementation of such filters with a high number of overcouplings usually leads to topological problems in the choice of the spatial arrangement of the resonators and coupling elements. Since in the canonical coupling structure the first and the last resonator have to be coupled and thus arranged in close proximity to one another, a problem arises in the case of filters of high order N in the implementation of sufficiently high blocking vapors.

According to the prior art, in order to implement transmission zeros, one alternative to using a resonator arrangement with overcouplings between non-adjacent resonators is the Anglo-Saxon one Literature used as "Extracted-Pole Structure" configuration used, where additional resonators are coupled to the leads to the input and / or output port of a bandpass filter without transmission zeros at finite frequencies (M = 0) so that they zero transmission Realize in the restricted areas. Such an arrangement is known from DE 42 32 054 AI, in which a band-stop filter made of at least one coaxial resonator is connected in series in a microwave ceramic filter without transmission zeros at finite frequencies (M = 0) (cascade of band-pass filter with M = 0 and band-stop filter ). This bandstop is used to eliminate interference frequencies that are outside the pass band. In US Pat. No. 3,747,030 A, a line resonator about a quarter of a wavelength long is connected in parallel to the input or output of a filter composed of concentrated elements with M = 0. As a result, a bandstop is connected in series to the filter second gate. The disadvantage of this concept of cascading a bandstop with a bandpass filter with M = 0 is the need to use additional resonators for the bandstop, i.e. the need for a filter with N damping zeros in the pass band, to have to use a total of N _R > N resonators.

For the function of allowing the signals to pass through in a coherent frequency range and to block the signals in adjacent frequency ranges, a band-stop filter with two separated blocking ranges can also be used instead of a bandpass filter. Here, the used pass band lies between the two band band stop band. From US 5,291,161 A a filter of this type is known, which consists of a continuous main line and to this galvanically coupled stub lines exist and in which each stub line generates a transmission zero. From IC Hunter and JR Rhodes "Electronically tunable microwave bandstop filters" in IEEE Transactions on Microwave Theory and Techniques, vol. MTT-30, No. 9, September 1982, pages 1361 to 1367, it is known that for the generation of transmission zeros Capacitive-coupled stub lines can also be used instead of the galvanically coupled stub lines. A continuous transmission line with stub lines (branch lines) coupled to it is also known from DE 24 42 618 C2. A disadvantage of the use of such filter structures from a main line with N passing from the filter input to the filter output _R coupled stub lines as blocking resonators is the fact that the high blocking attenuation remains limited to frequency ranges of finite width and thus lets the filter through again beyond these ranges. The second disadvantage is that the number N of the dampers in the utilized passband between the two blocking ranges gs zeros is less than the number of resonators and thus the maximum steepness of the filter flanks between the pass band and the stop band that can be achieved for a given resonator number N _R cannot be achieved.

Accordingly, the present invention is intended to provide a way of realizing bandpass filters from coupled resonators with up to M = N-1 damping poles that can be placed anywhere in the stop band, with no overcouplings and no “extracted-pole” resonators and no band-stop structures with continuous ones Main line are used and thus the disadvantages of these concepts described above are avoided. The object is achieved according to the invention by the subjects presented in the claims. According to the invention, bandpass filter structures are proposed in which blocking resonators are integrated into the structure in such a way that each blocking resonator realizes both one of the desired transmission zero points in the blocking area and, together with the rest of the filter structure, a damping zero point in the pass band. These bandpass filter structures according to the preferred embodiments of the invention are characterized by the following features:

(a) The bandpass filters are made up of an impedance-symmetrical filter element with N = 2m + l (m = natural number) poles and Nl transmission zeros, described below, or from a cascade of such impedance-symmetrical filter elements, or a cascade formed under described impedance-asymmetrical filter elements, each with N = 2 poles and M = 2 transmission zeros.

(b) An impedance-symmetrical filter element with N = 3 poles and M = 2 transmission zeros consists of a line piece delimited by two discontinuities, referred to as the main resonator, to which a pair of blocking resonators is coupled in the middle, such that due to the longitudinal field distribution on the main resonator, the coupling to the blocking resonators at the resonance frequency of the main resonator (center frequency) disappears, but assumes a finite value at frequencies that deviate therefrom. The length of the main resonator will be like this chosen so that it corresponds approximately to half the line wavelength at the center frequency of the bandpass filter. The blocking frequency of the one blocking resonator is chosen to be lower and that of the other blocking resonator is chosen to be larger than the center frequency and as a result each of the two blocking resonators generates a transmission zero and an additional pole by interaction with the main resonator. If a single impedance-symmetrical filter element serves as a bandpass filter, one end of the main resonator is coupled electrically, galvanically or magnetically to the filter input and the other end to the filter output. If the bandpass filter is constructed from a cascade of several impedance-symmetrical filter elements, the adjacent main resonator ends that are not coupled to the input or output port are electrically, galvanically or magnetically coupled.

(c) An impedance-symmetrical filter element with N = 2m + l poles (m = natural number of large 1) and M = Nl = 2m transmission zeros consists of a line section, delimited by two discontinuities, called the main resonator, on the m pairs of Blocking resonators are coupled at a mutual distance of approximately half a center frequency wavelength, such that due to the longitudinal field distribution on the main resonator, the coupling to the blocking resonators at the resonance frequency of the main resonator (center frequency) disappears, but a finite one at frequencies that deviate therefrom Assumes value. The length of the main resonator is chosen so that it is approximately the same corresponds to m times half the line wavelength at the center frequency and the distance between the outer blocking resonator pairs and the ends of the main resonator is approximately a quarter line wavelength. The blocking frequencies of the two blocking resonators of each of the m blocking resonator pairs are chosen such that one is smaller and the other larger than the center frequency, and thereby each of the two blocking resonators generates a transmission zero and by interacting with it Main resonator an additional pole. If a single impedance-symmetrical filter element serves as a bandpass filter, one end of the main resonator is coupled to the filter output and the other end is electrically, galvanically or magnetically coupled to the filter output. If the bandpass filter is constructed from a cascade of several impedance-symmetrical filter elements, the adjacent main resonator ends that are not coupled to the input or output port are electrically, galvanically or magnetically coupled.

(d) In addition to the impedance-symmetrical filter elements, impedance-asymmetrical filter elements, each with N = 2 poles and M = 2 transmission zeros, can be used to construct a bandpass filter from a cascade of several filter elements. The impedance-unbalanced filter elements consist of a main resonator whose length corresponds to approximately a quarter of the line wavelength at the center frequency of the bandpass filter, in which one end is coupled to the adjacent filter element in such a way that this line end is terminated with high impedance (maximum of the electric field strength) and the other end is coupled to the adjacent filter element or the em or output gate of the bandpass in such a way that the line end is terminated with low impedance (current maximum at the line end), and at the low impedance end of the Main resonator a pair of blocking resonators is electrically or galvanically coupled.

The above distinction between impedance-symmetrical and impedance-asymmetrical filter elements is to be understood in such a way that with an impedance-symmetrical filter element when the input and output gates are connected with the same terminating resistance, the maximum values of the power transmission factor reach negligible losses , while with the transmission-asymmetrical filter element, complete power transmission can only be achieved for highly asymmetrical gate resistors.

The further explanation of the invention is based on the basic principle shown in the drawings 1 to 4 and the exemplary embodiments shown in the drawings 5 to 12.

Figure le shows in a schematic way the basic structure of an inventive impedance-symmetrical filter element with N = 3 poles and M = 2 transmission zeros, and Figures la to ld show in a schematic manner structures which correspond to the prior art and therefore only in steps Explanation of the basic principle of the structure according to the invention according to figure le serve. Fig. La symbolically shows a homogeneous high-frequency line 1, in which this line as a metallic TEM line z. B. as a coaxial line, as a planar line such. B. a microstrip line or strip line or coplanar line, or as a waveguide or as a dielectric line. If the dissipation is neglected, the frequency response of the power _{transmission factor 2, i.e.} the frequency dependence of the ratio of the power P ₂ emerging at the reflection-free gate ₂ to the power P incident at the gate 1 in the operating frequency range of the line considered, is equal to one regardless of the frequency.

FIG. 1b schematically shows a structure modified compared to FIG. 1 a, in which two discontinuities 3 are introduced symmetrically into the cable run. These discontinuities define a line segment of finite length a, on which electromagnetic natural vibrations occur at those frequencies at which the length a corresponds to an integer multiple of half a line wavelength, and these natural vibrations are characterized by standing waves with nodes and bulges of the electrical and magnetic field strength along the line , where m of the plane of symmetry 4 at the resonance frequency is a node of the electric or magnetic field strength. The structure thus created represents a 1-pole bandpass, which is well known in the prior art and which has a maximum due to a frequency response of the power transmission factor 5 1 (damping zero point) is marked at a frequency f ₀ . The discontinuities delimiting the line piece can technically e.g. B. in In the form of line interruptions or in the form of metallic diaphragms, and it is also well known from the prior art that the frequency bandwidth Δf of the transmission curve can be changed via the strength of the coupling between the supply lines and the ends of the line piece serving as a resonator ,

FIG. 1 c shows a structure modified from FIG. 1 a, in which a resonance circuit 6 (“blocking resonator”) is coupled to the line, so that the frequency response of the power transmission factor 7 has a transmission zero at the frequency f _s . This structure represents the construction of a single-pole bandstopper (“notch filter”), which is well known in the prior art.

FIG. 1d shows a structure modified from FIG. 1c, in which instead of a blocking resonator two blocking resonators 8 with different resonance frequencies are coupled and lead to two transmission zeros at f _s ι and f _s2 .

An essential aspect of the invention now consists in forming the structure according to FIG. Le from a combination of the structure according to FIG. 1b and the blocking resonator pair from FIG. The line section of finite length forms a resonator, here referred to as the main resonator, which has a node of the electric or magnetic field in the middle. An important aspect of the invention is the choice of the coupling between the blocking resonators and the main resonator in such a way that this coupling disappears at the frequency f ₀ , this z. B. is achieved in that in the presence of a node of the electrical Field an electrical coupling and in the presence of a node of the magnetic field, a magnetic coupling between the main resonator and the blocking resonators is selected. By this measure, on the one hand, the resonance of the main resonator at frequency f _{0 is} not disturbed by the blocking-resonator pair, and on the other hand, due to the coupling between the blocking-resonator pair and the main resonator, two additional natural oscillations are obtained for frequencies different from fn. In this structure according to the invention, the two blocking resonators thus take on a double function by, on the one hand, realizing two transmission zeros - as in the structure according to FIG. 1d - and on the other hand producing a total of 3 natural oscillations (3 poles) together with the line piece. The frequency response 10 of the structure according to FIG. Le is thus characterized by a suitable choice of the resonance frequencies and coupling strengths by three transmission maxima (damping zeros) at f _x , f ₂ and f ₃ and two transmission zeros at f _s ι and f _s2 . In this filter element for realizing 3 poles and two transmission zeros, the frequency position of the transmission zeros is determined by the resonance frequencies of the blocking resonators and the frequency position of the average transmission maximum by the length of the main resonator. The position of the two outer transmission maxima can be changed by the coupling strength between the main resonator and the blocking resonators, with an increase in the coupling these frequencies shifting towards the middle frequency.

Another essential aspect of the invention is the generalization of the principle according to FIG Filter elements with M = 2m transmission zeros and N = M + l = 2m + l poles. In Figure 2a the case m = 1 is shown again according to Figure le. If the line piece at the center frequency is half a wavelength long (“center frequency line wave length”), the type of coupling between the blocking resonators and the main resonator depends on whether the magnitude maxima of the electric or magnetic field. In the case of electric field maxima at the ends, the electric field at frequency fo has a node in the plane of symmetry and thus the two blocking resonators must be electrically coupled according to the above design rules, while in the case of magnetic field maxima at the ends, because of the node of the magnetic field , there must be a magnetic coupling. In order to be able to use a magnetic coupling between the blocking resonators and the main resonator in the case of magnetic field maxima at the ends, the length of the line stub must correspond to a full wavelength instead of half a center frequency line wavelength.

FIG. 2b shows the generalization according to the invention for m = 2, that is to say N = 5 poles and M = 4 transmission zeros, two pairs of blocking resonators being used at a mutual spacing of approximately half a line wavelength.

FIG. 2c shows the extension according to the invention to a filter element with N = 7 poles and M = N -1 = 6 transmission zeros.

The increase in the number of poles N of a filter element according to the principle shown in Figures 2a to 2c is limited by the frequency position of higher unwanted natural vibrations of the main resonator, the extension of the main resonator to increase the number of poles, the natural resonances of the main resonator in the frequency range more and more compressed. In order to be able to implement filters with a higher number of poles despite this limitation, in a further embodiment of the invention two alternative paths are followed, namely a cascading of impedance-symmetrical filter elements according to FIGS. 2a to 2c and the introduction of impedance-asymmetrical filter elements with two poles and two transmission zeros per filter element.

FIG. 3 shows how a filter with the number of poles N = N _g xQ and M = NQ transmission zeros is formed from a cascade of Q filter elements, each with N _g poles and M _g = Nl transmission zeros. The case of a 9-pole (9-circuit) filter with 6 transmission zeros from 3 filter elements with Ng = 3 and a 10-pole filter with 8 transmission zeros from 3 filter elements with Ng = 5 are shown as examples.

An impedance-unbalanced filter element is realized in accordance with the invention by modifying an impedance-symmetrical filter element with a pair of blocking resonators according to FIG. 1e, one of the two discontinuities being brought close to where the blocking resonator is located -Pair is coupled. This results in the T-shaped structure shown in FIG. 4a with a discontinuity 2 (“high-resistance end”) and a second discontinuity (“low-resistance end,” approx. A quarter of the center frequency line wavelength away from the coupling point of the blocking-resonator pair). ,, 3), which is close to the coupling point of the blocking resonator pair.

In order to compensate for the impedance asymmetry, at least one impedance-symmetrical element is added in a cascade of impedance-asymmetrical filter elements. Here, as shown in FIG. 4b, the impedance-symmetrical element 5 can be located at one end of the cascade, or it can be inserted centrally (see FIG. 4c).

For the filter structures according to the invention, which are shown schematically in principle in the figures le, 2a to 2c, 3 and 4, there is a very large number of technical design possibilities, which can be achieved. a. make a difference

a) the type of conduction from which the main resonator is built, b) the design of the blocking resonators c) the type of coupling between the blocking resonator and the main resonator d) the design of the discontinuities (coupling) between the main resonators in a cascade and the main resonators and gates.

5 shows an example of the implementation of a 7-pole filter with 6 transmission zeros in the form of a single filter element according to the principle shown in FIG. 2c in coaxial line technology. The main resonator 1 has a rectangular outer and inner conductor and a length equal to 1.5 times the center frequency wavelength. The discontinuities delimiting the line piece are designed in the form of capacitive couplers. The blocking resonators 2 are as on Realized short-circuited coaxial line pieces of a length of about a quarter of a line wavelength, which are capacitively coupled to the main resonator.

FIG. 6 shows a modification of the structure according to FIG. 5, in that the blocking resonators 2 are now galvanically connected to the inner cavity of the main resonator, but are capacitively loaded at the end.

FIG. 7 shows a structure consisting of two impedance-asymmetrical filter elements and one impedance-symmetrical element, in which one obtains 9 poles and 8 transmission zeros.

FIG. 8 shows a filter consisting of an impedance-symmetrical filter element with 5 poles and 4 transmission zeros, which is implemented on the basis of rectangular hollow lines for the HIO wave type. The main resonator 1 consists of a rectangular waveguide short-circuited at both ends, which has a length at the center frequency corresponding to a waveguide wavelength. The 4 blocking resonators 2 are realized in the form of short-circuited 1/4 hollow pieces. The coupling to the gates can e.g. B. via a coaxial transition 3.

FIG. 9 shows an example of an implementation with dielectric resonators in the case of a filter comprising two impedance-symmetrical filter elements, each filter element producing three poles and two transmission zeros, and thus the bandpass filter has a total of 6 poles and 4 transmission zeros. Those made of a suitable dielectric material, that is to say material with the highest possible dielectric constant, a low loss angle and a low one Temperature coefficients (eg barium titanate zirconate) produced main resonators 1 and blocking resonators 2 are spacers 3, z. B. made of quartz material; positioned to avoid excessive ohmic losses at a sufficient distance from the bottom of the metallic housing 5. The dimension of the main resonator is chosen so that it has a natural resonance at fo with the field distribution shown in Fig. 9b, and the dimension of the blocking resonators are chosen so that they resonate at the 4 blocking frequencies fi to f ₄ and thereby a field distribution according to Fig. 9c. Because of the spatial field distribution of the main resonator, it does not couple to the resonance fields of the blocking resonators at f ₀ . For frequencies other than f ₀ , however, a coupling is obtained between the main resonator and the blocking resonators, with the result that an additional 4 natural resonances occur. The coupling to the gates can e.g. B. via conductor loops 4.

10 shows an example of a further possible design of a filter element made of dielectric material. The main resonator 5 consists of a dielectric cuboid of length a, which corresponds approximately to a wavelength of the surface wave on the dielectric cuboid. In this way, a field distribution corresponding to FIG. 10b is obtained on the main resonator. The 4 blocking resonators 1 to 4 also consist of dielectric cuboids, the individual lengths bl to b4 of which influence the frequency position of the 4 transmission zeros. The entire structure of the main dielectric resonator and 4 dielectric blocking resonators realizes 5 natural vibrations. The frequency position of the poles can be adjusted via the coupling strength between the main and Resonators are changed. The “gaps” filled with air or a dielectric material with a relatively low dielectric number serve to change this coupling strength between the resomators with the widths hi to h ₄ .

The principle according to the invention can also be applied to planar resonator structures, such as, for. B. microstrip line structures are used, microstrip line structures made of high-temperature superconductors are also of interest, since they have a high level of idling despite an enormous degree of miniaturization.

11, the implementation of an impedance-asymmetrical filter element according to the invention in microstrip line technology is explained. 11a, the principle of a microstrip line resonator, which is well known in the prior art, is first brought to mind. In this structure there is a continuous conductor layer 2 on one side and a structured conductor layer on the other on a suitable dielectric substrate 1. FIG. 11 a shows the well-known structure of a microstrip line resonator 3, which at its ends is capacitively connected to the leads 4, 5 is coupled. The frequency response of the power transmission factor 6 shows a maximum at the frequency f ₀ and the width of this maximum can be changed via the strength of the coupling at the line ends (discontinuities). 11b shows how an impedance-asymmetrical filter element according to the invention can be realized in microstrip line technology. For this purpose, a T-shaped conductor structure is used, in which the length of the individual arms is approximately a quarter Line wavelength corresponds to the center frequency, whereby a well-defined asymmetry in the length or width of the side arms 3 is necessary for the function. The side arms represent a simple implementation of the blocking resonators, the blocking frequencies being influenced over the length of the arms. Together with the third arm, the side arms form e structures, which resonate at two different frequencies and thus the T-structure represents a special form of a dual-mode resonator. The output gate can be capacitively connected to the T in the manner shown in FIG. 11b Structure to be coupled. The frequency response 6 of the two-port thus created is characterized by two transmission maxima and two transmission zeros, the absolute value of the transmission maximum being able to be far below one due to the asymmetry. For this reason, an individual asymmetrical filter element - in contrast to the impedance-symmetrical filter element - is not yet a usable bandpass filter. As with all the implementation examples shown above, this microstrip line structure can also be modified in a variety of ways, e.g. B. by using inhomogeneous pipe pieces of variable width.

FIG. 12 shows an example of how 4 impedance-asymmetrical filter elements 1 and a conventional half-wave resonator 2 can be used to form a 9-pole filter with 8 transmission zeros. In addition to the provision of an additional pole, the resonator 2 in the cascade transforms the impedance at gate 2 (e.g. 50 ohms) to the low impedance level at the coupling point to the branching point of the T-shaped resonators. The dimensioning of the parameters of each Filter elements, here z. B. done so that a Cauer characteristic is achieved for the frequency response.

Claims

claims

1. High-frequency bandpass filter arrangement, consisting of a main resonator (1) and at least one blocking resonator (4, 6, 8) coupled to the main resonator (1), the main resonator (1) being caused by discontinuities (2 and 3 in Fig. to 2c) is defined in the form of an interruption or metal wall, and has an electromagnetic natural vibration at a center frequency (fo), characterized in that the blocking resonator (4) coupled to the main resonator at its blocking frequency ( f _s ) for a wave on the line section of the main resonator (1) realizes a reflection factor of one, and that the at least one blocking resonator is coupled to the main resonator at those locations along the line section where, due to the spatial variation of the electrical and magnetic field along the line, the frequency-dependent coupling between the blocking resonator and the main resonator at d the center frequency of the bandpass filter disappears.

2. High-frequency bandpass filter arrangement according to claim 1, characterized in that the at least one blocking resonator is formed by a pair of blocking resonators arranged symmetrically to one another.

, High-frequency bandpass filter arrangement according to Claim 1, characterized in that the coupling of the at least one blocking resonator to the main resonator takes place electrically.

4. High-frequency bandpass filter arrangement according to claim 1, characterized in that the coupling of the at least one blocking resonator to the main resonator takes place magnetically.

5. High-frequency bandpass filter arrangement according to claim 1, characterized in that the coupling of the at least one blocking resonator to the main resonator is carried out galvanically.

6. Bandpass filter according to claim 1 with three natural frequencies (Poland) and two transmission zeros, characterized in that the

The main resonator is formed by a line piece with a length which corresponds to about half a line wavelength at the center frequency of the bandpass filter, so that two blocking resonators in the center of the line piece are coupled to the main resonator in such a way that the frequency-dependent coupling disappears at the center frequency. that the blocking frequency of one of the two blocking resonators is lower than the center frequency of the bandpass filter and the blocking frequency of the other blocking resonator is higher than the center frequency of the bandpass filter, that for the blocking frequencies of the two blocking resonators those frequencies in the blocking range are selected, at which transmission zeros of the bandpass filter are desired, and that with the strength of the coupling between the blocking resonators and the main resonator, the three transmission maxima are shifted within the pass band in such a way that the reflection attenuation in the pass band lies above a predetermined minimum value.

7. Bandpass filter according to claim 1 with five natural frequencies (Poland) and four transmission zeros, characterized in that the main resonator is formed by a line piece with a length which corresponds approximately to a line wavelength at the center frequency, that two pairs of blocking resonators at a mutual distance of approximately half a center frequency line wavelength along the line section of the main resonator and a distance of approximately a quarter line wavelength between the outer blocking-resonator pairs and the ends of the line section are coupled to the main resonator in such a way that the frequency-dependent coupling disappears at the center frequency of the bandpass filter.

8. bandpass filter according to claim 1 with 2m + l (with m as a natural number) natural frequencies (Poland) and 2m transmission zeros, characterized in that the main resonator by a piece of line with a length of about m times half a center frequency Line wavelength is formed that m pairs of blocking resonators at a mutual distance of half a center-frequency line wavelength along the line piece and one A distance of about a quarter of the line wavelength between the outer blocking resonator pairs and the ends of the line section are coupled to the main resonator in such a way that the frequency-dependent coupling disappears at the center frequency of the bandpass.

9. bandpass filter according to claim 1 with 2m + l (with m as a natural number) natural frequencies (Poland) and 2m transmission zeros, characterized in that the main resonator by a line piece with a length of about (m + 1) times half a center frequency line wavelength is formed that m pairs of blocking resonators at a mutual distance of half a center frequency line wavelength along the line section and a distance of about half a line wavelength between the outer blocking resonator pairs and the ends of the line section the main resonator are coupled so that the frequency-dependent coupling disappears at the center frequency of the bandpass filter.

10. Bandpass filter according to claim 1 with a cascade of filter elements (Q number), in which these filter elements are formed from bandpass filters according to one of claims 2 to 5, characterized in that one end of the line section serving as the main resonator of a filter element is electrically or magnetically or galvanically is coupled to the adjacent end of the line section of the next filter element, and in which the two outer ends of the line sections of the outer filter elements are coupled to the input and output ports, respectively.

1.Bandpass filter according to claim 1, with two

Transmission poles and two transmission zeros (Fig. 4a), consisting of a main resonator in the form of a line piece (1 in Fig. 4a), which is approximately a quarter of a line wavelength long at the center frequency of the bandpass filter, characterized in that an end (2) is electrically, magnetically or galvanically coupled to the input gate (gate 1) of the bandpass filter in such a way that the electric field strength is produced at this end at the center frequency em, and the other end (3) is thus electrically connected to the output gate of the bandpass, is magnetically or galvanically coupled that at the center frequency em minimum of the electric field strength arises at this end that em pair of blocking resonators is galvanically or electrically or magnetically coupled in the vicinity of the second gate (3 in Fig. 4a) that the Blocking frequencies of the two blocking resonators are selected to be equal to the predetermined frequencies of the transmission zero points in the blocking range, that the F Requirement position of the two transmission maxima in the passband can be changed by changing the coupling strength between the blocking resonators and the approximately a quarter wavelength long line piece.

12.Bandpass filter according to claim 11, with galvanic

Coupling between the blocking resonator pair and the approximately one quarter line wavelength long line piece, characterized in that this line piece together with the two blocking resonators forms a T-shaped resonator (FIG. 11b) with two different natural frequencies, and that the filter input is electrically coupled to the lower end of the vertical portion of the "T" and the filter output is electrically coupled to the upper end of the vertical portion of the "T".

13.Bandpass filter from a cascade of filter elements, which partly consist of bandpass structures according to claims 11 or 12, and partly consist of bandpass structures according to one of claims 1 to 9.

14. Bandpass filter according to one of claims 1 to 13, characterized in that the resonators are designed as coaxial resonators.

15. Bandpass filter according to one of claims 1 to 13, characterized in that the resonators are designed as cavity resonators.

16. Bandpass filter according to one of claims 1 to 13, characterized in that the resonators are designed as dielectric resonators.

17. Bandpass filter according to one of claims 1 to 13, with planar microstrip line resonators or coplanar resonators including planar resonators made of high-temperature superconductors.