DE2714181A1 - Microwave filter with resonators in interdigital structure - has additional resonators before and after input and output resonators to give additional finite frequency attenuation peak - Google Patents

Abstract

The microwave filter has several resonators in the form of comb or interdigital structures coupled with each other. The first and last resonators are provided with connections for the electromagnetic energy supply or collection. These two resonators are each coupled with a further resonator in order to produce at least one additional attenuation peak at finite frequencies. All resonators are arranged in a row, so that their inner conductors (1-8) lie in a common plane, and the above connections are connected to inner conductors (2, 7) of the resonators which were initially the first and last resonator.

Description

Filter for very short electromagnetic waves

The invention relates to a filter for very short electromagnetic Waves with several coupled together, in the form of a combline or interdigital structure trained resonators, each in the direction of the energy to be transmitted first and last resonators with connections for the supply and removal of the electromagnetic energy are provided and in which to generate at least one additional damping poles at finite frequencies the first and / or last resonator is coupled to a further resonator in each case.

Microwave filters are generally made up of several microwave resonators coupled to each other, the coupling of which is capacitive, can be done inductively or electromagnetically.

In many applications, in a frequency range above of about 100 MHz with such filters in the pass band a small reflection factor and at the same time striving for the best possible phase linearity. Furthermore, the Achieving a sufficiently high quality of the resonant circuit is a realization of such filters required by means of line elements.

Special difficulties arise, for example, when to Achievement of a larger pass bandwidth and thus a more favorable phase characteristic than with undivided filters same circuit complexity in the damping characteristics of the filter, so-called damping poles, i.e. infinity points the attenuation are to be generated. One way of solving these difficulties is known for example from the USA-PS 2 749 523, and consists in not directly following each other in their electrical mode of operation Additionally to couple resonators with each other. This coupling can be via line elements where, on the one hand, attention is paid to the special dimensioning of the length must be, and which also require additional space, because these lines are arranged outside the filter resonators.

Another possibility for realizing bandpass filters with attenuation poles at finite frequencies by means of coaxial resonators with additional overcouplings is from the essay "Realization." Increase in reflection factor and time-of-flight leveled microwave bandpasses with bridges " made famous by G. Pfitzenmaier. Although the length of the inner conductor is such in The microwave filter described in this article was chosen to be significantly smaller than / 4 However, the overall height of these filters generally exceeds that by the limit required for use in common assemblies.

One in the article "The Digital Elliptic Filter - A Compact Sharp-Cutoff Design for Wide Bandstop or Bandpass Requirements "by M.C. Horton and R.J. Wenzel (IDEE Transactions on Microwave Theory and Techniques, Vol.MTT-15, No. 5, May 1967) The described implementation of elliptic filters is only applicable to filters whose inner conductors are dimensioned with a length of ho / 4. With such a However, the construction of the necessary shaping of inner conductors becomes the second dimension such a filter is generally unacceptably large.

Furthermore, it is known that interdigital filters, which are both characterized by simple structure and high quality, then attenuation poles have below and / or above the pass band if at the first and / or a further inner conductor is coupled to the last inner conductor. Such Filters are, for example, by the one in the magazine "The Radio and Electronic Engineer ", July 1967, published article" The Practical Design of Interdigital and Comb-Line Filters "by B.F.

Nicholson described. Such a structure is also still off the article "Design Equations for a Class of Wide-Band Bandpass Filters" by E.G. Cristal (published in October 1972 in IEEE Transaction on Microwave Theory and Techniques).

For adapting the wave resistance of comb and interdigital filter structures to the terminating resistors of a filter, it is also known, the decoupling to be carried out in a space-saving manner on the first and last inner conductor, whereby the Filter input and output each an otherwise necessary, the resistance transformation serving inner conductor can be omitted. Notes on this can be found, for example in the table book Microwave Band Passes by G. Pfitzenmaier, published in 1972 by Siemens AG, Berlin and Munich, as well as in KIESE Transactions on Microwave Theory and Techniques, Vol. MTT-23 ", Article published Dec. 1975 "Tapped-Line Coupled Transmission Lines with Applications to Interdigital and Combine Filters "by E.G. Cristal.

The invention is based on the object mentioned above To remedy difficulties as far as possible and to set up a structure for microwave filters specify, which is guaranteed to have a small reflection factor and a The best possible phase linearity is characterized by a particularly low overall height.

Starting from a filter for very short electromagnetic waves with several coupled together, in the form of a comb line or interdigital structure trained resonators, each in the direction of the energy to be transmitted first and last resonators with connections for the supply or Decrease in electromagnetic energy are provided and in which to generate at least one additional damping pole at finite frequencies, the first and / or the last resonator is coupled to a further resonator in each case This object is achieved according to the invention in that all resonators in a row are arranged in such a way that their inner conductors run in a common plane, and that the connections for the supply or removal of electromagnetic energy galvanically to the inner conductor of the originally first or last resonators are coupled.

There is a particular advantage of the filter structure according to the invention in its compactness, which can be achieved through the particularly low overall height, which also through the possibility of using inner conductors that are shorter than Ao / 4 results. As a result, the filter according to the invention is also particularly suitable for installation in suitable for flat assemblies.

The invention will be explained below with the aid of an exemplary embodiment explained in more detail.

In the drawing, FIG. 1 shows a sectional illustration of a eight-circuit interdigital filter constructed according to the invention FIG. 2 shows a representation of a section placed perpendicular to the sectional illustration according to FIG. 1, FIG. 3 a trace of the attenuation characteristics and the reflection factor of the filter according to FIGS. 1 and 2.

In the embodiment according to FIGS. 1 and 2, an eight-circle, steepened by one pole of attenuation below and above the pass band Interdigital filter shown, its round inner conductor 1 to 8 alternately connected to opposite housing sides and thereby are grounded at one end. Fig. 1 shows a through the central axes of the Inner conductor 1 to 8 of the resonators laid section. In the rectangular resonator case, the one common filter base plate 9 and firmly connected to this base plate Has end and side walls 10, the oscillating circuits are interdigital arranged such that the inner conductors 1 to 8 of the resonators each on the one Side are electrically conductively connected to an end face of the housing, while they end up on their other side as cylindrical capacitors. The "original" six-circle interdigital filter is realized by resonators, the inner conductor of which 2 to 6 are arranged in a row such that their central axes are in a common Run level. Connections 21 and 71 for the supply or

Decrease in electromagnetic energy are coaxial, and their inner conductors are connected to inner conductors 2 and 7 of the originally first or galvanically coupled last resonators and run with respect to their central axis perpendicular to that formed by the central axes of the inner resonator conductors 2 to 7 common level. The filter connections are made by tapping on the second or seventh inner conductor. The additional ones represented by the inner conductors 1 and 8 Resonance circles are used to generate the damping poles at finite frequencies.

It is therefore through the additionally coupled inner conductor 1 and 8 the structure of the original interdigital filter over the beginning and the end of the filter continued. To achieve a low overall height are also the Inner conductors 1 and 8 in a row next to the original inner conductors 2 to 7 arranged so that their central axes in the through the central axes of the inner conductor 2 to 7 formed common level run.

The inner conductors 1 to 8 can each on one side by a Screw connection by means of a counter screw electrically conductive with the end faces connected to the filter housing and thus axially adjustable if necessary, what is not in the figure is shown in more detail. On the ungrounded On the side, the inner conductors 1 to 8 can also have a section with a larger diameter have, through a corresponding hole in the face of the filter housing is recorded, creating the effect of a cylinder capacitor. Through this it is possible to further reduce the length of the inner conductor and for example shorter than Ao / 4 by a factor of 2.84. For tuning the oscillating circuits to a center frequency selected in the exemplary embodiment of, for example, f = 480 MHz, the cylinder capacitors are designed to be variable as described above. In Fig. 1, the tunable capacitors are shown symbolically and wear the reference characters C1 to C8.

As from the sectional illustration placed perpendicular to the illustration according to FIG. 1 2 can be seen, the rectangular metal housing contains a common filter base plate 9 with raised side walls 10 or end walls, on which one of the filter base plate opposite cover plate 11 is placed.

The metal housing contains in its interior each parallel to Filter base plate 9 aligned resonator inner conductor 1 to 8, the central axes of which run in a common plane.

The filter cover plate 11 is connected to the coaxial connections 21 or 71 provided, the inner conductor with the inner conductors 2 and 7 of the original first and last resonance circuits of the filter are galvanically connected and with respect to its central axis perpendicular to that through the central axes of the resonator inner conductor 1 to 8 formed common level run. As can also be seen from FIG is, the filter is characterized by a special due to its geometric structure low overall height with the inside dimension h and is shortened because of the Ao / 4 Inner conductor very compact and particularly suitable for installation in flat assemblies. This advantage also arises, inter alia, when the inventive concept is implemented Filters in stripline technology or in microstrip technology.

Fig. 2 shows a curve of the operational attenuation ab and the reflection factor r in a filter according to FIGS. 1 and 2 as a function of the frequency. As can be seen from the figure, for a center frequency of fo = 480 MHz within the bandwidth of f-f, | # 115 MHz the operating attenuation ab 20 dB. The usable bandwidth #f for a reflection factor r of r '9,' is 160 in the exemplary embodiment MHz. Within the useful bandwidth in the frequency range between 400 MHz and 560 t4Hz the deviation from the linear phase in the filter according to the invention is clear smaller than with a corresponding one with regard to blocking attenuation and reflection factor eight-circle undivided interdigital filter.

7 claims 3 figures

Claims (7)

Claims 1 + filters for very short electromagnetic waves with several coupled together, in the form of an Eammleitungs- or interdigital structure trained resonators, each of which points in the direction of the energy to be transmitted first and last resonators with connections for the supply and removal of the electromagnetic energy are provided and in which to generate at least one additional damping poles at finite frequencies the first and / or last resonator is coupled to a further resonator, d u r c h e k e n n -z e i c h n e t that all resonators are arranged in a row in such a way that their inner conductors (1 to 8) run in a common plane, and that the connections (21,71) for the supply or removal of the electromagnetic energy galvanically coupled to the inner conductors (2,7) of the originally first or last resonators are. 2. Filter according to claim 1, d a d u r c h g e k e n n z e i c h -n e t that the length of the inner conductors (1 to 8) of the resonators is chosen to be shorter than Ao / 4 is. 3.Filter according to claim 1 or claim 2, d a d u r c h g e -k e n It is not indicated that the inner conductors (1 to 8) of the resonators are on one side are electrically connected to the filter housing and on the opposite Side by appropriate shaping of the filter housing as cylinder capacitors are trained. 4.Filter according to claim 3, d a d u r c h g e k e n n z e i c h -n e t that to vote in the filter housing the free end faces of the resonator inner conductor (1 to 8) oppositely arranged, capacitive tuning screws are provided are. 5. Filter according to claims 1 or 2, g e k e n n z e i c h -n e t d u r c h a version in stripline technology. 6.Filter according to claims 1 or 2, g e k e n n z e i c h -n e t d u r c h a design in microstrip technology. 7.Filter according to claims 1 or 2, g e k e n n z e i c h -n e t d u r c h a version in coaxial technology.