JPH0216801A - Triple mode dielectric filter - Google Patents

Abstract

PURPOSE:To eliminate a spurious response on the side of a low frequency from an objective filter band and to miniaturize and lighten a whole reception device by generating a dielectric resonator in such a way that it simultaneously resonates at an HE11delta mode and a TE01delta mode. CONSTITUTION:A filter selects the rate L/D of the dielectric resonator 26 in such a way that the resonant frequency of a point A can be obtained. Thus, they are simultaneously resonated at respective modes of HE11delta and TE01delta and they do not have the spurious response on the side of the frequency. A probe 18 for exiting the HE11delta mode is connected with an input connector 14, and the probe 18 consisting of a linear conductor extends perpendicularly to the axis of the dielectric resonator 26, whereby an electric field in the probe 18 is connected with that of the HE11delta mode in the resonator 26. On the other hand, a probe 20 for detecting TE01delta mode on is connected with an output connector 16, and the magnetic field of TE01delta mode in the resonator 26 is connected with that on the probe 20 in the circular probe 20.

Description

Detailed Description of the Invention (Field of Industrial Application) The present invention relates to a triple mode dielectric filter, and in particular to a triple mode dielectric filter that is compact and has low spurious response and is suitable for use in radio equipment of communication satellites. Regarding.

(Prior art) Dielectric filters using dielectric resonators have been made small and lightweight, and the material properties of the scales and dielectric have been improved (temperature change in dielectric constant is small and loss is low). It has been rapidly developed in recent years due to the development of small materials. It has already been proposed that this dielectric filter be configured as a dual mode filter.

However, as far as the present inventor knows, triple mode dielectric filters are used by simultaneously resonating HE11, δ mode I, which is an orthogonal mode in which two modes are degenerated, and TM old δ mode, which is a non-orthogonal mode. Things are just made public in principle. The triple mode filter mentioned above is
By appropriately selecting the height-to-diameter ratio of the cylindrical dielectric resonator loaded in the cold cavity, the resonant frequencies of the HEl]δ mode and the TMo and δ modes can be matched, thereby creating a pair of HE + +δ mode and one T, M. ,
A total of three modes, including the δ mode, are configured to resonate in one dielectric resonator.

Note that the details of the specific configuration (main body, input connector, output connector, coupling screws, etc.) of this triple mode dielectric filter itself have not been made public.

(Problem to be Solved by the Invention) However, as will be explained in detail later in the embodiments of the present invention, this triple mode dielectric filter has a TEOIδ mode on the lower frequency side than the resonance frequency of these three modes. Exists as a spurious response. Note that spurious responses due to higher-order modes naturally exist on the higher frequency side than the resonant frequency.

When the triple mode dielectric filter is configured as a bandpass filter, the spurious response produces passbands (low frequency side and high frequency side) other than the desired passband.

For example, if such a triple-mode dielectric filter is used in a receiving device, the triple-mode dielectric filter will also pass the radio waves at the frequency corresponding to the spurious response, making it impossible to effectively remove interfering radio waves, resulting in reception interference due to the interfering radio waves. It has the disadvantage of causing Note that if the interference is too large to ignore, an extra band-stop filter can be installed to eliminate the reception interference, but the above-mentioned case where there are spurious responses on both the low-frequency side and the high-frequency side When a triple mode dielectric filter is used in a receiving device, there is a possibility that the number of band rejection filters must be increased, and the power of the desired received radio wave may be attenuated. have.

Therefore, an object of the present invention is to provide a triple mode dielectric filter that does not generate spurious responses at least on the low frequency side.

Another object of the invention is to provide a preferred embodiment of a triple mode dielectric filter of the type described above.

(Means for Solving the Problems) In order to achieve the above-mentioned object, in particular in principle, the present invention provides a method for generating a pair of orthogonal modes and a non-orthogonal mode within one metal cavity loaded with a dielectric resonator. A triple mode dielectric filter in which a pair of orthogonal modes are HE and □δ momo and one non-orthogonal mode is a TE01δ mode, in which the triple mode dielectric filter has electromagnetic resonance at the same time. This will be adopted.

Further, as a specific configuration, the present invention provides a triple mode dielectric filter including a main body having a cylindrical cavity;
A cylindrical dielectric resonator placed in the center of the cavity of the main body, an input connector attached to one side of the main body, an output connector attached to the other side wall of the main body, and a connection from the input connector into the cavity of the main body. a first mode excitation probe that protrudes and excites the first mode; a first means that protrudes from the main body into the cavity and couples the first mode and the second mode; and a first means that protrudes from the main body into the cavity. and a third mode detection probe that protrudes from the output connector into the cavity of the main body to detect the third mode. A triple mode dielectric filter is used.

(Function) The configuration of the triple mode dielectric filter of the present invention includes a metal cavity, a cylindrical dielectric resonator loaded inside the cavity, an input/output probe, and a screw for coupling between each mode. Also, the ratio of the height and diameter of the cylindrical dielectric resonator is
+1δ mode and one TEOIδ mode are selected so that they resonate at the same frequency.

With the above-described structure, three-stage filter characteristics can be realized for j metal cavities. Further, although the details will be described later, as can be seen from Figure 1, if the ratio of the height and diameter of the cylindrical dielectric resonator is selected so that the HE11δ mode and the TEOIδ mode resonate at the same frequency, the conventional triple Spurious responses on the low frequency side as seen in mode dielectric filters are not excited, and a filter with inferior spurious characteristics can be obtained.

"Orthogonal mode" as used herein throughout the specification
is a mode that, when the electromagnetic field distribution of that mode is rotated by 90 degrees about the axis of the cylindrical dielectric resonator, is completely orthogonal to the electromagnetic field distribution before rotation. Therefore, the electromagnetic field distributions before and after rotation have no influence on each other and can be used as two independent modes. Moreover, "non-orthogonal mode" refers to a mode other than "orthogonal mode", and many general modes belong to "non-orthogonal mode".

rTE01δ” as used throughout this specification,
We will discuss the names of the resonance modes rHE11δ'' and rTM(,1δ''.Generally, the cylindrical dielectric resonance mode has an electric field component in the axial direction of the cylinder but has no magnetic field component, and the TM mode has a magnetic field component but has no magnetic field component. The three subscripts following TE and TM indicate the number of peaks of change in the amplitude of the electric or magnetic field in the circumferential, radial, and axial directions of the cylinder. It shows.

However, the number of ridges in the axial direction, which is the third subscript, is 1.2
．． 3,... without counting, δ, δ"-1, δ"-2, .
I count... Therefore, the T E o 1δ mode is a mode that does not have an electric field in the axial direction of the cylinder (TE mode).
Therefore, there is one peak of change in the amplitude of the electromagnetic field in the radial direction and one in the axial direction. Furthermore, apart from the above-mentioned TM mode and TE mode, there is a mode that has both a magnetic field component and an electric field component in the axial direction of the cylinder.

Such a mode is referred to as a hybrid mode, and the HE mode is not referred to as the EH mode.

The HE mode is considered to be a case where a mode that is originally a TM mode has a magnetic field component in the axial direction, and the EH mode is a case where a mode that is originally a TE mode has an electric field component in the axial direction.

Furthermore, the meanings of the subscripts in this case are the same as in the TM mode and TE mode.

(Example> Next, the present invention will be explained with reference to the drawings.

Figure 1 shows the height (L) and diameter (L) of a cylindrical dielectric resonator.
Resonance frequency versus ratio (L/D) of D FIG. 3 is a cross-sectional view taken from line 3-3 in the direction of the arrow.

First, referring to Figure 1, the horizontal axis in Figure 1 is the ratio (I-) to diameter (1) of the cylindrical dielectric resonator.
L/D), and the vertical axis shows the resonant frequency, which is a ratio of the resonant frequencies of the various modes of the resonator to l-1. As is clear from FIG. 1, the HE + 1δ mode and the TMoIδ mode match at the resonant frequency indicated by point "B". In the conventional triple mode dielectric filter mentioned above, the ratio (L/D) of the dielectric resonator is selected so that the resonance frequency is at this point B, and as is clear from the drawing, for example, on the low frequency side, This causes spurious responses in the TEo and δ modes.

On the other hand, the triple mode dielectric filter of the present invention has a point '.

The ratio (L / D) of the dielectric resonator was chosen so that the resonant frequency could be obtained, not indicated by A.
The basic mode H E + 1δ mode and TE
It can simultaneously resonate in the 01δ mode and has no spurious response on the low frequency side.

Next, referring to FIGS. 2 and 3, the triple mode dielectric filter (hereinafter simply referred to as filter) of the present invention]0
It is shown. The filter 1o has a body 2 which is a metal casing, the body 2 having a cylindrical cavity 12
It has a. An input connector 14 is attached to one side wall of the main body, and an output connector 16 is attached to the other side wall. Input connector 14 and output connector 16 are preferably provided facing each other as shown, but are not limited to this arrangement.

A cylindrical dielectric resonator 26 is mounted in the center of the cavity 1.2a of the main body 12 on a support base 28 made of sujiroohm (Fig. 3).
It is installed through. This dielectric resonator 26 has a height (I-) to diameter (D) ratio (1/D) selected so as to have a resonant frequency indicated by point ``A'' in FIG. A pair of orthogonal modes, HE and □δ modes, and one non-orthogonal mode, TEo1δ mode, are formed to resonate simultaneously.

When the filter 10 is configured as a triple mode, a probe is provided at the input connector so as to excite the dielectric resonator 26 in one of the three modes described above, and a probe is provided at the input connector to excite the dielectric resonator 26 in one of the three modes described above. furthermore, another second means is provided for combining the other one mode and the remaining mode, and furthermore, the remaining mode is detected. A probe must be provided at the output connector. For convenience of explanation below,
The mode excited at the input connector is called the first mode, the other mode coupled to the first mode by the first means is called the second mode, and the remaining mode is called the third mode. Therefore, the first mode, second mode and third mode are HE
11δ mode, H E orthogonal to this, 1δ mode and T E O]δ mode, HE++δ mode, T E o +δ mode and the first HE ] I
If H E is orthogonal to δ mode, □δ mode,
In addition, there may be a TE01δ mode, a HE11δ mode, and an HE11δ mode orthogonal thereto. Although the filter of the present invention can take any of the above-mentioned combination forms,
FIG. 2 and FIG. 3 show a filter corresponding to the first described embodiment as an example, and the following explanation will also be based almost on this example. Note that the last form can be realized by using the input connector and the output connector as the output connector and the input connector, respectively.

A first mode (one mode among the HE11δ modes) excitation probe 18 is connected to the input connector 14 described above, and this probe 18 is made of a substantially straight conducting wire and efficiently transmits only the first mode. It extends directly above the dielectric resonator 26 so that it can be excited. That is, it extends perpendicularly to the axis of the dielectric resonator 26. Due to this arrangement, the first mode excitation probe 18 is connected to the electric field input from the input connector 14 and generated in the probe 18, and the first mode (HE, , δ The electric field of one of the modes is coupled to the electric field of one of the modes.

Also, the output connector 16 described above has a third mode (TE0
1δ mode) A detection probe 20 is connected. This probe 20 is a circular probe made of a looped conductor, and is resonant in a third mode (T) in a dielectric resonator 26.
The magnetic field of the EOI δ mode) and the magnetic field of the probe 20'' are coupled.

A coupling screw (first means, first screw) 22 is provided at one corner adjacent to the input connector of the main body 12 so as to protrude into the cavity, and the extent of the protrusion can be adjusted. It extends perpendicularly to the axis of the dielectric resonator 26.

That is, it forms an angle of approximately 45° with respect to the probe ]8. This screw is preferably made of a dielectric material such as plastic. The screws 22 are a pair of H screws that are completely orthogonal.
It disturbs the electromagnetic field distribution of the E 1+δ mode, destroys the orthogonality of the electromagnetic field distribution between these two modes, and couples these modes.

That is, the screw 22 has the first mo I~(I-I E +
+δ mode) and the second mode (HE+
+δ mode (orthogonal mode).

Further, a metal screw 24 (second means, second screw) 24 is provided from the bottom of the main body 12 parallel to the axis of the dielectric resonator 26 so as to adjust the degree of protrusion into the cavity. This screw 24 is used for the second mode () - (orthogonal mode of E, , δ mode) and the third mode (TE01δ mode)
and are coupled by disturbance of the electromagnetic field distribution.

These screws 22 and 24 strengthen the coupling between the dots inserted into the cavity. Accordingly, these screws 22 and 24 are adjusted to appropriate positions depending on the specifications of the filter used. In addition, as mentioned above, one screw 22 is made of a dielectric material and the other screw 24 is made of metal (conductor), so the drop in Q (quality factor) that would occur if both screws were made of conductor is avoided. It can be avoided.

TakumiNext, a specific example will be explained. For experiments, the main body]
Cavity 1.2 a has an inner diameter of 20 mm and a height of 16 mm.
The material of the dielectric resonator 26 has a dielectric constant of 3.
7 was selected and set to have a diameter of 7.7 mm and a height of 7.85 mm. The probe 18 was a conductive wire with a diameter of 1 mm, and had a length that reached almost directly above the dielectric resonator. The probe 20 was formed as a circular probe with a diameter of 2 mm using a conductive wire with a diameter of 0.5 mm. The filter thus formed was tested and found to have good triple mode filter characteristics.

Although the preferred single filter of the present invention has been described, the filter of the present invention can be used by connecting a plurality of filters in series in order to improve the frequency characteristics like conventional filters. Such series-connected filters are disclosed in Japanese Patent Laid-Open No. 59-80002. This publication relates to a dual-mode filter, and discloses a filter in which a plurality of cavities arranged in series connection through an iris aperture are formed within a single body. The filter of the present invention can also be configured as a series-connected filter similar to the filter disclosed in this publication.

(Effects of the Invention) As explained in detail above, the present invention has a triple mode dielectric filter configured to almost completely eliminate spurious responses on the lower frequency side than a desired filter band. When used in a receiving device, it can prevent the contamination of low-frequency interference radio waves caused by spurious responses, reducing the need for extra auxiliary means, and thus reducing the size and weight of the entire receiving device. This is something that can be achieved.

[Brief explanation of the drawing]

Figure 1 shows the height (L) and diameter (D) of a cylindrical dielectric resonator.
) is a graph showing resonator frequency characteristics versus the ratio (L/D). FIG. 2 is a plan view of the triple mode dielectric filter of the present invention. FIG. 3 is a cross-sectional view taken from line 3--3 in FIG. 2 in the direction of the arrow. 0... Triple mode dielectric filter, 2... Main body, 2a... Cavity, 4... Input connector, 6... Output connector, 8... First mode excitation probe, O... - Third mode detection probe, 2... first screw, 4... second screw, 6... dielectric resonator, 8... support body. 1. Figure L/D 1. Indication of the case 1988 Patent Application No. 166546 2. Name of the invention Triple mode dielectric filter 3. Person making the amendment Name of relationship to the case 4. Agent

Claims (7)

[Claims] (1) In a triple mode dielectric filter in which a pair of orthogonal modes and one non-orthogonal mode simultaneously resonate electromagnetically in one metal cavity loaded with a dielectric resonator, the pair of orthogonal modes are HE_1_1δ modes, A triple mode dielectric filter characterized in that one non-orthogonal mode is a TE_0_1δ mode. (2) In a triple mode dielectric filter, there is a main body having a cylindrical cavity, a cylindrical dielectric resonator placed in the center of the cavity of the main body, an input connector attached to one side of the main body, and an input connector attached to the other side of the main body. An output connector attached to one side wall, a first mode excitation probe that protrudes from the input connector into the cavity of the main body to excite the first mode, and a probe that protrudes from the main body into the cavity to excite the first mode and the first mode. a first means for combining the second mode;
a second means protruding into the cavity from the main body to combine the second mode and the third mode; and a third mode detection probe protruding from the output connector into the cavity of the main body to detect the third mode. A triple mode dielectric filter comprising: (3) In the triple mode dielectric filter according to claim 2, the first mode and the second mode are a pair of orthogonal modes, HE_1_1δ mode, and the third mode is one non-orthogonal mode, TE_0_1δ mode. Features a triple mode dielectric filter. (4) In the triple mode dielectric filter according to claim 3, the first mode excitation probe is a substantially straight conducting wire and extends perpendicularly to the axis of the dielectric resonator, and the third mode detection probe is The first means is a loop-shaped conducting wire, and the first means is at an angle of approximately 45 degrees with the first mode excitation probe, and the first means is perpendicular to the axis of the dielectric resonator and the degree of protrusion into the cavity can be adjusted. A triple mode dielectric filter, characterized in that the second means comprises a second screw extending parallel to the axis of the dielectric resonator and capable of adjusting the degree of protrusion into the cavity. (5) The triple mode dielectric filter according to claim 4, wherein the first screw is a dielectric and the second screw is a conductor. (6) In the triple mode dielectric filter according to any one of claims 2 to 5, one triple mode dielectric filter is connected in series with at least one other triple mode dielectric filter. A triple mode dielectric filter featuring: (7) A triple mode dielectric filter according to claim 6, wherein the bodies of the triple mode dielectric filters connected in series are integrally formed.