JP4081671B2 - Waveguide filter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a waveguide filter mainly applied to electrical / electronic / communication equipment and parts thereof, and more specifically, in a structure in which a cover is assembled to an iris-processed case when changing frequency and bandwidth. The present invention relates to a waveguide filter having a structure in which these members can be used in common and any one parameter can be semi-unadjusted.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as this type of waveguide filter, a type in which a waveguide is formed by assembling another member on an iris-processed member (see Patent Document 1 and Patent Document 2) is known. Here, when designing a waveguide filter in which an irised member is used as a case and another member is regarded as a cover, the design value of the case dimensions is derived by a desired frequency and bandwidth. . That is, the length of the waveguide is derived from the frequency (in-tube wavelength), and the dimension of the iris portion is derived from the bandwidth (interstage coupling).
[0003]
By the way, in the waveguide filter having such a structure, when the case is generally used with a common case, the adjustment range is narrow, so that problems such as loss deterioration due to excessive adjustment and unnecessary resonance are likely to occur. In the case of a structure with different specifications with different frequencies and bandwidths, several cases with different dimensions are designed and prepared, and the type of case that meets the specifications is used.
[0004]
[Patent Document 1]
JP 60-38901 A (FIGS. 1, 2 and 3)
[0005]
[Patent Document 2]
Japanese Utility Model Publication No. 6-66107 (summary)
[0006]
[Problems to be solved by the invention]
In the case of a waveguide filter having a structure in which a waveguide is formed by assembling a cover to the above-mentioned iris-processed case, the adjustment range is narrow and it is difficult to use the case in common. When manufacturing products with different bandwidths, it is necessary to prepare several types of cases with different dimensions. In this situation, as the types of frequencies and bandwidths increase, there are many types of cases. It must be designed, prepared and prepared, and the development design, manufacturing, and parts management for that purpose are complicated, which causes high costs and makes production management difficult during mass production. As a result, there is a problem that it is difficult to easily change the frequency and bandwidth.
[0007]
That is, in the case of a conventional waveguide filter, in order to prepare various types of cases, not only the development and design stage may be lengthened, but also the frequency and bandwidth are determined in the manufacturing process. Otherwise, manufacturing (manufacturing) of the case cannot be started, and development design costs and parts are required due to various circumstances such as careful and strict management of parts by type so as not to mix various cases after production. The high management cost increases the cost, making it unsuitable for short-term delivery, and therefore it is difficult to easily change the frequency and bandwidth.
[0008]
Therefore, with this type of waveguide filter, these problems can be solved and many merits can be obtained if the case and the cover that have been subjected to the iris processing can be used at least when changing the frequency and bandwidth. Although it can be played, no improvement measures have been taken at present.
[0009]
The present invention has been made to solve such problems, and the technical problem thereof is that the case and the cover subjected to the iris processing can be used in common when changing the frequency and bandwidth, and can be arbitrarily used. It is an object of the present invention to provide a waveguide filter having a convenient structure capable of semi-tuning one parameter.
[0010]
[Means for Solving the Problems]
According to the present invention, a structure in which a waveguide is formed by assembling a cover so as to cover a plurality of iris portions with respect to a case provided with a plurality of iris portions so that a predetermined bandpass filtering characteristic can be obtained by iris processing. In the waveguide filter, the case has an opening for mounting the cover, and is used in common when changing any one parameter including at least frequency or bandwidth. A waveguide filter is obtained that is mounted as the same component that can accommodate any one parameter change including at least frequency or bandwidth with respect to the opening in the case.
[0011]
According to the present invention, in the waveguide filter, the case has a substantially U-shaped cross section and extends in a uniaxial direction, and a plurality of iris portions are provided on the flat bottom surface at predetermined intervals along the uniaxial direction. Thus, the waveguide filter can be obtained that is slidably mounted in a direction perpendicular to the bottom surface of the case so that the distance between the cover and the plurality of iris portions can be varied with respect to the opening.
[0012]
Furthermore, according to the present invention, in the above-described waveguide filter, the case has a substantially U-shaped cross section, extends in a uniaxial direction, and has a plurality of iris portions on a bottom surface having steps with different thicknesses along the uniaxial direction. Is provided so as to define the step with a predetermined interval between the steps, and the cover is an average of the steps on the bottom surface when the main surface facing the plurality of iris portions is in the case. A waveguide filter that is inclined along a uniaxial direction at an angle that substantially matches the gradient value, and is slidably mounted in the uniaxial direction so that the distance from the plurality of iris portions can be varied with respect to the opening. Is obtained.
[0013]
In addition, according to the present invention, in the above-described waveguide filter, the case has a substantially U-shaped cross section and extends in a uniaxial direction, and a plurality of iris portions are formed on the flat bottom surface at predetermined intervals along the uniaxial direction. The cover has a plurality of mounting surfaces each mountable to an opening in the case, and the plurality of mounting surfaces correspond to a change in any one parameter including at least frequency or bandwidth. Waveguide filters having different shapes are obtained so that they can be assembled.
[0014]
In this waveguide filter, the cover has a concave groove and a convex step processed in different depths as different shapes of a plurality of mounting surfaces, and a plurality of iris portions in the case are provided. The lowest frequency mode is set according to the assembled state in which the waveguide interval dimension from the flat inner bottom surface to the first mounting surface of the concave groove, which is one of the plurality of mounting surfaces in the cover, is maximum. In addition, the waveguide spacing dimension from the flat inner bottom surface of the case to the second mounting surface of the concave groove, which is another of the plurality of mounting surfaces of the cover, is smaller than the maximum value. The intermediate frequency mode is set according to the assembled state that is an intermediate value, and the third step of the convex step that is another one of the plurality of mounting surfaces in the cover from the flat inner bottom surface in the case Intermediate waveguide spacing to mounting surface Each preferred to be set to the highest frequency mode by the assembled state a smaller minimum value than. In the waveguide filter, it is preferable that the intermediate frequency mode is set to 1 GHz higher than the lowest frequency mode, and the highest frequency mode is set to 1 GHz higher than the intermediate frequency mode.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. First, the technical background and outline up to the development of the waveguide filter of the present invention will be briefly described.
[0016]
FIG. 1 is a side cross-sectional view in the longitudinal (side) direction showing the main structure of a waveguide filter prior to the present invention. Here, a structure is formed in which a waveguide is formed by assembling a cover 2 so as to cover each iris 1a with respect to case 1 provided with a plurality of irises 1a so that a predetermined band-pass filtering characteristic can be obtained by iris processing. When designing a waveguide filter having, for example, bandwidth (interstage coupling degree K _{j, j + 1} ) Is constant, and a filter of a type that differs only in frequency f is desired, and a filter designed with a low frequency is used as it is at a high frequency, the guide wavelength λ becomes short when the frequency f is high. In case 1 designed at a low frequency, the interval L between the iris portions 1a is too long, making frequency adjustment very difficult, and the ratio band becomes small. _{j, j + 1} Becomes too large, and the interstage coupling degree K _{j, j + 1} Must be reduced.
[0017]
That is, in general, if the same case 1 is used at a high frequency, the bandwidth (degree of interstage coupling K _{j, j + 1} In such a case, forcibly adjusting it often deteriorates the characteristics, and it is necessary to design the case 1 according to the frequency. When it is desired to use the designed case 1 even at a high frequency, the in-tube wavelength λ is not shortened, and the interstage coupling degree K _{j, j + 1} Should not be large.
[0018]
Accordingly, in the waveguide filter as shown in FIG. 1, the waveguide interval dimension a (structure) from the flat inner bottom surface provided with each iris 1a in the case 1 to the mounting surface in the cover 2 is shown. In addition, as a matter of course, when attention is paid to the height t from the flat inner bottom surface of each iris portion 1a), when only the waveguide interval dimension a is reduced, the guide wavelength λ becomes longer and Interlinkage degree K _{j, j + 1} Therefore, both of the two parameters, frequency and bandwidth, exhibit a desired change. As a result, if only the waveguide interval dimension a is changed, the same bandwidth (interstage coupling degree K) is obtained. _{j, j + 1} ) Can be changed while the frequency f is maintained.
[0019]
The waveguide filter of the present invention can be used in common with the case 1 and the cover 2 that have been subjected to the iris processing with the change of the waveguide interval dimension a as a focus, and any parameter can be adjusted semi-unadjusted. The case 1 has an opening for mounting the cover 2 and is used in common when changing any one parameter including at least frequency or bandwidth. The cover 2 is mounted as the same component that can cope with a change in any one parameter including at least a frequency or a bandwidth with respect to the opening in the case 1.
[0020]
As a specific structure of the case and the cover in such a waveguide filter, the case has a substantially U-shaped cross section and extends in a uniaxial direction, and a plurality of iris portions are arranged at predetermined intervals along the uniaxial direction on a flat bottom surface. The cover is structured to be slidable in a direction perpendicular to the bottom surface of the case so that the distance between each cover and the iris can be varied with respect to the opening, or the case has a substantially U-shaped cross section. A plurality of iris portions are provided on the bottom surface having steps with different thicknesses along the uniaxial direction so as to partition the steps with a predetermined interval between the steps. The main surface on the side facing the iris portion is inclined along the uniaxial direction at an angle substantially matching the average gradient value of the step difference on the bottom surface of the case, and the distance from each iris portion to the opening is set. Variable The case is constructed so as to be slidable in a uniaxial direction, or the case has a substantially U-shaped cross section and extends in the uniaxial direction, and a plurality of iris portions are provided on the flat bottom surface at predetermined intervals along the uniaxial direction. And a plurality of mounting surfaces each capable of mounting the cover with respect to the opening in the case, and the plurality of mounting surfaces can be assembled in response to a change in any one parameter including at least frequency or bandwidth. In the case of a structure having a different shape.
[0021]
If such a structure is applied, in any case, for example, only the above-described waveguide interval dimension a is changed, and the same bandwidth (interstage coupling degree K) is changed. _{j, j + 1} ) Is maintained and the frequency f can be changed.
[0022]
FIG. 2 is an external perspective view showing the basic structure of the waveguide filter according to one embodiment of the present invention with the case 1 and the cover 2 disassembled.
[0023]
In the case of this waveguide filter, a cover 2 is attached to the case 1 provided with a plurality of iris portions 1a so as to obtain a predetermined band-pass filtering characteristic by iris processing so as to cover each iris portion 1a. Specifically, the case 1 has the same structure as that of the conventional case. Specifically, the case 1 has a substantially U-shaped cross section and extends in a uniaxial direction, and has a flat bottom surface and a plurality of iris portions at a predetermined interval along the uniaxial direction. Although the point 1a is provided in the conventional manner, the case 1 is used in common when changing the frequency with a constant bandwidth, and the cover 2 has an opening in the case 1. Each has three mounting surfaces that can be mounted, and each mounting surface has a different shape so that it can be assembled in response to a change in frequency with at least a constant bandwidth. One has a structure.
[0024]
FIG. 3 is a sectional view in the end face direction showing a frequency setting mode corresponding to an assembling change pattern for the case 1 of the cover 2 provided in the waveguide filter, and FIG. 3A relates to the lowest frequency mode. (B) relates to the intermediate frequency mode, and (c) relates to the highest frequency mode.
[0025]
As shown in FIG. 2, the cover 2 here forms a mounting surface with respect to the opening of the case 1 for three of the four side surfaces extending in the uniaxial direction. As shown in 2 (a) to (c), the three mounting surfaces M1 to M3 are formed in different shapes so as to have concave grooves and convex steps that have been processed to different depths in advance. Accordingly, the waveguide filter has a structure in which the waveguide interval dimension a described in FIG. 1 can be changed by changing the mounting surfaces M1 to M3 of the cover 2 while using the case 1 in common. .
[0026]
That is, in FIG. 2 (a), the first mounting of the concave groove, which is one of the mounting surfaces of the cover 2, from the flat inner bottom surface where the iris portions 1a of the case 1 are provided. This shows that the lowest frequency mode 21.4 GHz is set depending on the assembly state in which the waveguide interval dimension a1 to the surface M1 is the maximum value.
[0027]
Similarly, in FIG. 2B, the lead from the flat inner bottom surface of the case 1 to the second mounting surface M2 of the concave groove, which is the other mounting surface of the cover 2, is provided. It shows that the frequency interval dimension a2 is set to 22.4 GHz in the intermediate frequency mode according to the assembled state in which the wave interval dimension a2 is an intermediate value smaller than the maximum value.
[0028]
Similarly, in FIG. 2C, from the flat inner bottom surface in the case 1 to the third mounting surface M3 having a convex step which is another one of the mounting surfaces in the cover 2. It shows that the waveguide frequency dimension a3 is set to 23.4 GHz of the highest frequency mode according to the assembly state in which the minimum value is smaller than the intermediate value.
[0029]
In short, this waveguide filter has a structure in which the intermediate frequency mode is set to 1 GHz higher than the lowest frequency mode, and the highest frequency mode is set to 1 GHz higher than the intermediate frequency mode.
[0030]
By the way, in the case of this waveguide filter, considering the common use of the cover 2, a concave groove having a different depth and a convex step are formed on the three side surfaces of the cover 2 to have different shapes. Since the surfaces M1 to M3 are provided and a flat surface (a flat surface without unevenness) facing the mounting surface M3 can be used as a mounting surface, as a result, one cover 2 can cope with four types of frequency changes. If there are few types of frequency required, the cover 2 may be processed only on a pair of opposing side surfaces (for example, upper and lower surfaces) (a structure that can handle three types of frequency changes). good.
[0031]
By the way, when designing and producing such a waveguide filter, the case 1 is designed on the assumption that only the frequency can be adjusted in order to simplify the design and strictly adjust the frequency. Do.
[0032]
First, a design value at a reference frequency is derived. Here, if it is described with reference to the structure shown in FIG. 1, a low frequency (21.4 GHz) at which the waveguide interval dimension “a” is maximum is used as a reference. Since the waveguide interval dimension “a” decreases in a higher frequency than this, the case 1 does not become larger than that at a low frequency, and the case where the mounting space is limited is considered.
[0033]
Next, the design is performed at a higher frequency with the height t from the flat inner bottom surface of the iris portion 1a derived here as a reference value. Here, the design is derived first using the waveguide spacing dimension a as a parameter. In addition, the waveguide interval dimension a is derived so that the reference value of the tall dimension t of each iris part 1a and the tall dimension t of each iris part 1a coincide as much as possible.
[0034]
As a result, the design value of case 1 at each frequency has a structure in which the height t of each iris part 1a is the same and the distance L between the iris parts 1a and the waveguide distance dimension a are different. . The height t of each iris part 1a of the case 1 to be used in common is the reference value determined here, but the interval L between the iris parts 1a is a design value at the highest frequency. Such a method is convenient because the overall length of the case 1 can be shortened and the adjustment from a high frequency to a low frequency is flexible.
[0035]
The waveguide spacing dimension a at each frequency has been derived as described above. Next, if the processing dimensions of the grooves and steps of the cover 2 are designed to obtain the desired waveguide spacing dimensions a1 to a3 at each frequency. good. Depending on the frequency, it is difficult to completely match the height t of the iris portions 1a, but in this case, it is only necessary to adjust only the portions that cannot be matched (each case 1 shown in FIG. 2). The height t of the iris portion 1a is shown with emphasis on the appearance of some variation after adjustment).
[0036]
That is, the technical point in producing the waveguide filter according to the above-described embodiment is to derive the waveguide interval dimension a such that the tall dimensions t of all iris portions 1a coincide at each frequency. Case 1 is to be designed. Incidentally, although the value to be matched as the reference value of the height dimension t of each iris part 1a has been described at the time of low frequency, it is designed when the height dimension t of each iris part 1a can be matched at each frequency. You may design arbitrarily according to conditions.
[0037]
Therefore, using the case 1 described above and the cover 2 having the mounting surfaces M1 to M3, the adjustment frequencies on the mounting surfaces M1 to M3 are 21 as shown in FIGS. 3 (a), 3 (b), and 3 (c), respectively. .3 GHz, 22.4 GHz, and 23.4 GHz, and a waveguide filter designed and manufactured with a bandwidth of 400 MHz was actually measured for bandwidth and frequency transmission and reflection characteristics. .
[0038]
As a result, in the case of the lowest frequency 21.4 GHz of the waveguide interval dimension a1 using the mounting surface M1, the bandwidth is 400 MHz, and the bandwidth when the waveguide interval dimension a2 at this time is compared is 332 MHz, It was found that the bandwidth when the waveguide interval dimension a3 was compared was 272 MHz. In addition, in the case of an intermediate frequency of 22.4 GHz with a waveguide interval dimension a2 using the mounting surface M2, the bandwidth is 416 MHz, and the bandwidth when the waveguide interval dimension a1 at this time is compared is 524 MHz. It was found that the bandwidth when the wave interval dimension a3 was compared was 342 MHz. Further, in the case of the maximum frequency 23.4 GHz of the waveguide interval dimension a3 using the mounting surface M3, the bandwidth is 428 MHz, and the bandwidth when the waveguide interval dimension a1 at this time is compared is 670 MHz. It was found that the bandwidth when the wave interval dimension a2 was compared was 528 MHz.
[0039]
FIG. 4 shows the measurement level (dB) of the transmission characteristic and reflection characteristic with respect to the frequency (GHz) in the lowest frequency mode with the waveguide interval dimension a1 shown in FIG. Similarly, FIG. 5 shows the measurement level (dB) of the transmission characteristic and reflection characteristic with respect to the frequency (GHz) in the case of the intermediate frequency mode having the waveguide interval dimension a2 shown in FIG. Similarly, FIG. 6 shows the measurement level (dB) of the transmission characteristic and the reflection characteristic with respect to the frequency (GHz) in the case of the maximum frequency mode with the waveguide interval dimension a3 shown in FIG.
[0040]
4 to 6 show a pass curve C1 showing a pass characteristic having a peak in the vicinity of the adjustment frequency and a reflection curve C2 showing a reflection characteristic attenuated in the vicinity of the adjustment frequency in comparison with the reference zero level. However, although there are some differences from the measurement results, there is almost no characteristic deterioration because there is no unreasonable adjustment despite the change in the frequency, and the design is sufficiently satisfied. I understand.
[0041]
In general, when making a waveguide filter, it is necessary to make adjustments to compensate for the common use of the members, and conversely, if an attempt is made to make a non-adjustable structure, the members are specified individually. However, according to the waveguide filter of the present embodiment, a semi-unadjusted structure that eliminates the need for common use of members and adjustment of interstage coupling. Can be realized at the same time.
[0042]
By the way, in the case of the above-described waveguide filter, a structure in which the waveguide interval dimension a can be changed by changing the mounting surfaces M1 to M3 of the cover 2 while using the case 1 in common (a structure in which the frequency can be changed). However, in addition, it is possible to obtain a structure in which the cover 2 is mounted as the same component that can cope with any change in one parameter with respect to the opening in the case 1.
[0043]
For example, in the previous embodiment, a structural example in which the bandwidth is constant even at different frequencies has been described, but it is also possible to design the same frequency in different bandwidths. . When designing a waveguide filter having such a structure, the waveguide interval dimension a is derived so that the intervals (electric lengths between elements) L of the iris portions 1a coincide with each other in each bandwidth. The tall dimension t may be designed on the assumption that strict adjustment is possible. In this case, since the adjustment can be made more flexibly from the narrower bandwidth toward the wider bandwidth, the design value may be a value when the height t of each iris portion 1a is the longest. If these derived values are used to design the shape and dimensions of the case 1 and the cover 2 in the same manner as in the previous embodiment, the frequency adjustment can be made non-adjustable only by adjusting the bandwidth. It becomes a structure. Of course, the present invention can be applied to other parameters in addition to the above-described structural example in which the frequency and bandwidth are constant.
[0044]
FIG. 7 is a cross-sectional view in the lateral (end face) direction showing a basic structure of a waveguide filter according to another embodiment of the present invention in a state where the case 1 and the cover 2 ′ are assembled. The case 1 here has the same structure as that of the previous embodiment (a substantially U-shaped cross section extending in a uniaxial direction, and a plurality of iris portions at a predetermined interval along the uniaxial direction on a flat bottom surface. 1a), but the cover 2 'here is perpendicular to the bottom surface of the case 1 (arrows) so that the distance from each iris 1a to the opening of the case 1 can be varied. It is a structure that can be slid in parallel. In the case of the waveguide filter having such a structure, flexible adjustment can be performed continuously at various frequencies.
[0045]
FIG. 8 is a cross-sectional view in the longitudinal (side) direction showing the basic structure of a waveguide filter according to another embodiment of the present invention in a state in which a case 1 ′ and a cover 2 ″ are assembled. In the case of a tube filter, the case 1 ′ has a substantially U-shaped cross section and extends in a uniaxial direction, and a plurality of iris portions 1 a ′ have a predetermined interval between the steps on the bottom surface having steps with different thicknesses along the uniaxial direction. And the cover 2 ″ has a structure in which the main surface on the side facing each iris portion 1a ′ substantially matches the average gradient value of the step on the bottom surface of the case 1 ′. A structure that is inclined along a uniaxial direction at an angle, and is slidably mounted in a uniaxial direction (indicated by an arrow) so that the distance between each iris part 1a 'and the opening of the case 1' can be varied It is said. Also in the waveguide filter having such a structure, flexible adjustment can be continuously performed at various frequencies as in the case of the waveguide filter according to the other embodiments.
[0046]
The waveguide filter according to each embodiment of the present invention basically has a structure in which any one parameter is not adjusted. However, in some cases, it is not necessary to unnecessarily adjust the parameter. There is. For example, depending on the design content, it may be difficult to match the height t of the iris portions 1a and 1a ′ as in the structure according to each embodiment. In such a case, adjustment is performed. A reference value may be determined as a premise to design, and if it is assumed that adjustment is performed, a wider range of members can be used in common, but this can be achieved and a flexible design is possible.
[0047]
【The invention's effect】
As described above, according to the waveguide filter of the present invention, the case has an opening for mounting a cover, and is used in common when changing any one parameter including at least frequency or bandwidth. Since the cover is structured to be mounted as the same component that can accommodate a change in any one parameter including at least frequency or bandwidth with respect to the opening in the case, the frequency and bandwidth can be changed. At this time, the case and the cover subjected to the iris processing can be used in common, and a convenient structure can be obtained in which any one parameter can be made semi-unadjusted. As a result, the common use of parts and the non-adjustment structure can be realized at the same time, the characteristic deterioration due to excessive adjustment can be prevented, and no adjustment of the interstage adjustment and the accompanying interstage adjustment member can be reduced. In addition, since it is possible to use parts in common, a variety of parts are required, making it possible to realize castings that were difficult in the past, thereby reducing costs and reducing the types of parts. As a result, management is facilitated, productivity is improved, and management troubles such as case mistakes at the time of manufacture are prevented, and various advantages are exhibited.
[Brief description of the drawings]
FIG. 1 is a side cross-sectional view in the longitudinal (side) direction showing the main structure of a waveguide filter prior to the present invention.
FIG. 2 is an external perspective view showing a basic structure of a waveguide filter according to one embodiment of the present invention with a case and a cover disassembled.
3 is a cross-sectional view in an end face direction showing a frequency setting mode corresponding to an assembling change pattern for a cover case provided in the waveguide filter shown in FIG. 2, wherein (a) relates to the lowest frequency mode; (B) relates to the intermediate frequency mode, and (c) relates to the highest frequency mode.
FIG. 4 shows measurement levels of pass characteristics and reflection characteristics with respect to frequency in the lowest frequency mode shown in FIG.
FIG. 5 shows measurement levels of pass characteristics and reflection characteristics with respect to frequency in the case of the intermediate frequency mode shown in FIG. 3 (b).
FIG. 6 shows measurement levels of pass characteristics and reflection characteristics with respect to frequency in the highest frequency mode shown in FIG. 3 (c).
FIG. 7 is a cross-sectional view in the short side (end face) direction showing a basic structure of a waveguide filter according to another embodiment of the present invention in a state where a case and a cover are assembled.
FIG. 8 is a sectional view in a longitudinal (side) direction showing a basic structure of a waveguide filter according to another embodiment of the present invention in a state where a case and a cover are assembled.
[Explanation of symbols]
1,1 'case
1a, 1a 'Iris part
2,2 ', 2 "cover

Claims (8)

A waveguide filter having a structure in which a waveguide is formed by assembling a cover so as to cover the plurality of iris portions with respect to a case provided with the plurality of iris portions so that a predetermined bandpass filtering characteristic can be obtained by iris processing. In
Wherein the case, possess an opening for mounting the cover, extending in a uniaxial direction at a substantially U-shaped cross-section, said plurality of iris portions are provided at predetermined intervals along the axial direction in the flat inner bottom surface And is used in common when changing any one parameter including at least frequency or bandwidth,
The cover is mounted as the same component that can cope with any one parameter change including at least a frequency or a bandwidth with respect to the opening in the case, and the distance from the plurality of iris portions to the opening. A waveguide filter, wherein the waveguide filter is slidably mounted in a direction perpendicular to the bottom surface of the case so as to be variable . A waveguide filter having a structure in which a waveguide is formed by assembling a cover so as to cover the plurality of iris portions with respect to a case provided with the plurality of iris portions so that a predetermined bandpass filtering characteristic can be obtained by iris processing. In
Wherein the case, possess an opening for mounting the cover, extending in a uniaxial direction at a substantially U-shaped cross-section, said plurality of iris portion inner bottom surface with a different step of sequentially thickness along the axial direction is It is provided so as to partition the step with a predetermined interval between the steps, and is used in common when changing any one parameter including at least frequency or bandwidth,
The cover is mounted as the same component that can cope with any one parameter change including at least a frequency or a bandwidth with respect to the opening in the case, and a main surface on a side facing the plurality of iris portions is the surface. Inclined along the uniaxial direction at an angle that substantially matches the average gradient value of the step on the bottom surface of the case, and the distance from the plurality of iris portions to the opening can be varied. A waveguide filter which is slidably mounted in a uniaxial direction . A waveguide filter having a structure in which a waveguide is formed by assembling a cover so as to cover the plurality of iris portions with respect to a case provided with the plurality of iris portions so that a predetermined bandpass filtering characteristic can be obtained by iris processing. In
Wherein the case, possess an opening for mounting the cover, extending in a uniaxial direction at a substantially U-shaped cross-section, said plurality of iris portions are provided at predetermined intervals along the axial direction in the flat inner bottom surface And is used in common when changing any one parameter including at least frequency or bandwidth,
The cover is mounted as the same component that can accommodate a change in any one parameter including at least a frequency or a bandwidth with respect to the opening in the case, and a plurality of covers that can be mounted on the opening in the case, respectively. And a plurality of mounting surfaces having different shapes so that the mounting surfaces can be assembled in response to changes in any one parameter including at least frequency or bandwidth. Wave tube filter. 4. The waveguide filter according to claim 3 , wherein the cover has a concave groove and a convex step processed in advance to different depths as different shapes of the plurality of mounting surfaces. Tube filter. 5. The waveguide filter according to claim 4 , wherein the concave shape is one of the plurality of mounting surfaces in the cover from the flat inner bottom surface in which the plurality of iris portions in the case are provided. A waveguide filter characterized by being set to a lowest frequency mode according to an assembly state in which a waveguide interval dimension to the first mounting surface of the groove is maximum. The waveguide filter according to claim 5 , wherein the second mounting of the concave groove, which is another one of the mounting surfaces of the cover, from the flat inner bottom surface of the case. A waveguide filter characterized by being set to an intermediate frequency mode according to an assembled state in which a waveguide interval dimension to a surface is an intermediate value smaller than the maximum value. The waveguide filter according to claim 6 , wherein a third of the convex steps, which is another one of the plurality of mounting surfaces in the cover, from the flat inner bottom surface in the case. A waveguide filter characterized in that the maximum frequency mode is set according to an assembled state in which a waveguide interval dimension to the mounting surface is a minimum value smaller than the intermediate value. 8. The waveguide filter according to claim 7 , wherein the intermediate frequency mode is set to 1 GHz higher than the lowest frequency mode, and the highest frequency mode is set to 1 GHz higher than the intermediate frequency mode. Waveguide filter.

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