JP2003069306A - Band pass filter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a band pass filter comprising a plurality of resonators whose spurious response can be suppressed over a very wide frequency. SOLUTION: The higher order resonance frequency of the resonators 2 being the components of the band pass filter are deviated from each other. For example, in each resonator 2 comprising a cascade connection of a low impedance line 3, a high impedance line 4 and a low impedance line 3, the low impedance line 5 of a small length is placed to the high impedance line block of at least one resonator and any of the characteristic impedance, the length, and the position of the low impedance line 5 is made different among the resonators 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bandpass filter composed of a microwave transmission line such as a coaxial line or a microstrip line.

[0002]

2. Description of the Related Art In a bandpass filter composed of a distributed constant circuit, an SIR (Stepped) is used as a resonator in order to suppress a spurious response at a high frequency.
The Impedance Resonator) has been widely used.

FIG. 7 shows the IEEE Trans. on M
icrowave Theory and Techni
QUES, VOL. MTT-28, No. 12, "Ba
ndpass Filters Using Para
llle Coupled Stripline Ste
pped Impedance Resonator
It is a block diagram of the conventional band pass filter in s ". The filter is constituted by a microstrip line,
In the figure, 109 is a dielectric substrate whose back surface is lined with a conductor,
Reference numeral 100 is an input / output terminal, and 101 is an SIR, which is a low impedance line 102 and a high impedance line 103.
Are cascaded in the order of low-high-low impedance line. The SIRs 101 in the filter all have the same shape.

[0004]

In the conventional bandpass filter having the above-described structure, a half-wavelength transmission line having a uniform characteristic impedance is used as a resonator forming the bandpass filter. Although it has been used, since a high-order resonance occurs at a frequency that is an integral multiple of the fundamental next resonance frequency, a filter composed of the same resonator has all frequencies that are an integral multiple of the fundamental next pass frequency band. There was a problem that became. On the other hand, when SIR is used as the resonator, the resonator has a higher resonance frequency of about 5 times the fundamental frequency.
Since it can be increased almost twice, it has an advantage that the spurious response in the high frequency band of the filter can be suppressed.

However, when trying to suppress the spurious response over a higher frequency band higher than that, when the SIRs in the filter have the same shape, the higher resonance frequency becomes a pass band and a spurious response occurs. There was a problem that caused it.

The present invention has been made to solve the above-mentioned problems, and a plurality of S's constituting a bandpass filter are provided.
It is an object of the present invention to provide a bandpass filter in which the spurious response of the filter is suppressed over an extremely wide range of frequencies by providing means for shifting the IR, that is, the higher resonance frequencies of the resonator from each other.

[0007]

In view of the above-mentioned object, the present invention is a bandpass filter comprising a plurality of resonators, wherein each resonator is constituted by a cascade connection of low-high-low impedance lines, and at least 1 A small impedance low impedance line is provided in the high impedance line section of each resonator, and any one of the characteristic impedance, length and position of the low impedance line is made different in each resonator. It is characterized by having done.

Further, in a bandpass filter composed of a plurality of resonators, each resonator is constituted by cascade connection of low-high-low impedance lines, and at least one resonator is further provided in the high-impedance line section. A minute impedance high impedance line having a high characteristic impedance is provided, and any one of the characteristic impedance, the length and the position of the high impedance line having a higher characteristic impedance is made different in each resonator. Is characterized by.

Further, in a bandpass filter composed of a plurality of resonators, each resonator is constituted by a cascade connection of high-low-high impedance lines, and at least one resonator has a small amount in the low-impedance line section. A high-impedance line having a different length is provided, and any one of the characteristic impedance, the length, and the position of the high-impedance line is made different in each resonator.

Further, in a bandpass filter composed of a plurality of resonators, each resonator is constituted by a cascade connection of high-low-high impedance lines, and at least one resonator is further provided in the low-impedance line section. A small length low impedance line having a low characteristic impedance is provided, and any one of the characteristic impedance, the length and the position of the low impedance line having a lower characteristic impedance is made different in each resonator. Is characterized by.

Further, a band pass filter comprising a plurality of resonators is characterized in that the various resonators are mixed.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below according to each embodiment. Embodiment 1. FIG. 1 shows the structure of a bandpass filter according to Embodiment 1 of the present invention, and shows the case of a microstrip line. In the figure, 9 is a dielectric substrate whose back surface is lined with a conductor, 1 is an input / output terminal, and 2 is an SIR that is a resonator, and the low impedance line 3 and the high impedance line 4 are low-high-low impedance lines. Although it has a basic configuration in which the high impedance lines 4 are connected in series in order, a part of the high impedance line 4 is a low impedance line 5 having a minute length. Any of the length, position, and characteristic impedance of the low impedance line 5 is different for each SIR2.

Next, the operation will be described. The low and high impedance lines 3 and 4 of each SIR 2 that compose the band pass filter have substantially the same shape, and the low impedance line 5 having a minute length has almost no influence on the fundamental next frequency of the SIR. Since they are not present, each SIR2 has the same fundamental resonance frequency. On the other hand, the influence of the low-impedance line 5 becomes large at a higher resonance frequency that is twice or more that frequency, and a difference occurs in the higher resonance frequencies of the SIRs due to the difference in shape and position. Therefore, as compared with the conventional bandpass filter in which all SIRs have the same shape and the higher-order resonance frequencies are matched with each other in addition to the fundamental-order resonance frequency, the spurious response of the filter at the higher frequency band can be reduced. it can. Note that FIG. 2 shows a conceptual diagram of the characteristics of the bandpass filter of the present invention in the higher resonance frequency band with respect to the conventional operation related to the above operation.

As described above, according to the configuration of the first embodiment, by making the high-order resonance frequencies of the resonators constituting the bandpass filter different from each other, the spurious response of the filter is spread over an extremely wide frequency range. Can be suppressed.

Embodiment 2. FIG. 3 shows the structure of a bandpass filter according to the second embodiment of the present invention, and shows the case of a microstrip line. In the figure, 19 is a dielectric substrate whose back surface is lined with a conductor, 11 is an input / output terminal, and 12 is an SIR. A low impedance line 13 and a high impedance line 14 are cascade-connected in the order of low-high-low impedance line. Although it has the basic configuration described above, a part of the high impedance line 14 is a high impedance line 15 having a minute length. The length and position of the high impedance line 15,
Any of the characteristic impedances is made different in each SIR 12.

Next, the operation will be described. In the first embodiment, a low impedance line is provided as a minute length line for changing the higher resonance frequency of each SIR, but the second embodiment is different in that a high impedance line is provided instead. The high impedance line functions as an inductive element while the low impedance line functions as a capacitive element, but this embodiment also changes the higher resonance frequency of each SIR as in the first embodiment. Can be made. Also, since the high impedance line occupies a smaller area than the low impedance line,
According to this embodiment, the circuit can be downsized.

As described above, according to the configuration of the second embodiment, by making the higher-order resonance frequencies of the resonators constituting the bandpass filter different from each other, the spurious response of the filter is spread over an extremely wide frequency range. Can be suppressed.

Embodiment 3. FIG. 4 shows the structure of a bandpass filter according to Embodiment 3 of the present invention, and shows the case of a microstrip line. In the figure, 29 is a dielectric substrate whose back surface is lined with a conductor, 21 is an input / output terminal, 22 is an SIR, and a low impedance line 23 and a high impedance line 24 are connected in cascade in the order of high-low-high impedance line. Although it has the basic configuration described above, a part of the low impedance line 23 is a high impedance line 25 having a minute length. The length and position of the high impedance line 25,
Any of the characteristic impedances is made different in each SIR 22.

Next, the operation will be described. While the low-high-low impedance line cascade connection is used as the basic configuration of each SIR in the first and second embodiments, the high-low-high impedance line cascade connection is used in the third embodiment. The points are different. When the former is used as the basic configuration of SIR, the secondary resonance frequency thereof is twice or more the fundamental frequency, while when the latter is used, it is less than twice the fundamental frequency. Therefore, depending on the characteristics required for the spurious response of the bandpass filter, it may be preferable to use the SIR of this embodiment. Then, similarly to the second embodiment, each high-order resonance frequency can be changed by providing each SIR 22 with a very long high impedance line 25.

As described above, according to the third embodiment, the spurious response of the filter is suppressed over an extremely wide frequency range by making the high-order resonance frequencies of the resonators constituting the bandpass filter different from each other. be able to.

Fourth Embodiment FIG. 5 shows the structure of a bandpass filter according to Embodiment 4 of the present invention, and shows the case of a microstrip line. In the figure, 39 is a dielectric substrate whose back surface is lined with a conductor, 31 is an input / output terminal, and 32 is an SIR, and a low impedance line 33 and a high impedance line 34 are cascade-connected in the order of high-low-high impedance line. Although it has the basic configuration described above, a part of the low impedance line 33 is a low impedance line 35 having a minute characteristic and having a lower characteristic impedance. Any of the length, position, and characteristic impedance of the low impedance line 35 is different for each SIR 32.

Next, the operation will be described. Embodiment 4
The third embodiment is different from the third embodiment in that a low-impedance line is used instead of a high-impedance line as a minute length line for changing the higher-order resonance frequency of each SIR. Further, as in the third embodiment, the higher resonance frequency of each SIR 32 can be changed. Further, since the low-impedance line can reduce the conductor loss as compared with the high-impedance line, this embodiment can also reduce the circuit loss.

As described above, according to the configuration of the fourth embodiment, by making the higher-order resonance frequencies of the resonators constituting the bandpass filter different from each other, the spurious response of the filter can be spread over an extremely wide frequency range. Can be suppressed.

Embodiment 5. FIG. 6 shows a bandpass filter according to a fifth embodiment of the present invention, and here shows a case where the bandpass filter is configured by a coaxial line. 40 in the figure
Is an outer conductor of the coaxial line, 41 is an input / output terminal, and 42 is an SIR, both of which have a basic configuration in which a low impedance line 43 and a high impedance line 44 are cascade-connected in three stages. A part of the line is a transmission line 45 which is a high impedance or low impedance line having a minute length. Same line 45
The length, position, or characteristic impedance of each SI
R42 is different from each other. 48 is S
It is a dielectric for holding IR. The first embodiment
Therefore, also in the fourth embodiment, a coaxial line can be formed in the same manner as in FIG.

Next, the operation will be described. Embodiment 5
Is a mixture of SIRs used in the band-pass filters according to the first to fourth embodiments, and like this, the high-order resonance frequency of each SIR 42 is changed with a high degree of freedom according to the present embodiment. You can

As described above, according to the configuration of the fifth embodiment, by making the high-order resonance frequencies of the resonators constituting the bandpass filter different from each other, the spurious response of the filter can be spread over an extremely wide frequency range. Can be suppressed.

[0027]

As described above, according to the present invention, in a bandpass filter including a plurality of resonators, each resonator is formed by cascade connection of low-high-low impedance lines, and at least one resonator is provided. At the same time as providing a small length low impedance line in the high impedance line section, the characteristic impedance of the low impedance line,
Since either the length or the position is made different in each resonator, the high-order resonance frequencies of the resonators are different from each other, and the spurious response of the filter can be suppressed over an extremely wide frequency range.

Further, in a bandpass filter composed of a plurality of resonators, each resonator is constituted by cascade connection of low-high-low impedance lines, and at least one resonator is further provided in the high impedance line section. Since a high-impedance line with a minute length having a high characteristic impedance is provided, and any one of the characteristic impedance, the length, and the position of the high-impedance line having a higher characteristic impedance is made different in each resonator. The high-order resonance frequencies of the resonators are different from each other, and the spurious response of the filter can be suppressed over a very wide frequency range. Further, since the high impedance line occupies a smaller area than the low impedance line, the circuit can be downsized.

Further, in a bandpass filter composed of a plurality of resonators, each resonator is constituted by a cascade connection of high-low-high impedance lines, and at least one resonator has a small amount in the low-impedance line section. Since a high impedance line with a different length is provided and the characteristic impedance, length and position of the high impedance line are made different in each resonator, the higher resonance frequencies of the resonators are different from each other. , The spurious response of the filter can be suppressed over a very wide frequency range. Further, when the low-high-low impedance line is used as the basic structure of the resonator, the secondary resonance frequency is twice or more the fundamental frequency, while the high-low-high impedance line is used. In this case, since the frequency is twice the fundamental frequency or less, it is possible to select and use a resonator of high-low-high impedance line depending on the characteristics required for the spurious response of the bandpass filter.

Further, in a bandpass filter composed of a plurality of resonators, each resonator is constituted by a cascade connection of high-low-high impedance lines, and at least one resonator is further provided in the low impedance line section. Since a minute impedance low impedance line having a low characteristic impedance is provided and any one of the characteristic impedance, the length and the position of the low impedance line having a lower characteristic impedance is made different in each resonator. The high-order resonance frequencies of the resonators are different from each other, and the spurious response of the filter can be suppressed over a very wide frequency range. Further, since the low impedance line can reduce the conductor loss as compared with the high impedance line, the loss of the circuit can be reduced.

Further, in the bandpass filter composed of a plurality of resonators, since the various resonators are mixed to form the bandpass filter, the high-order resonance frequencies of the resonators are different from each other, and the spurious response of the filter is extremely high. It is possible to suppress over a wide frequency range, and it is possible to change the high-order resonance frequency with a high degree of freedom.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a bandpass filter according to a first embodiment of the present invention.

FIG. 2 is a diagram for explaining characteristics of a bandpass filter according to the present invention in a high-order resonance frequency band.

FIG. 3 is a diagram showing a configuration of a bandpass filter according to a second embodiment of the present invention.

FIG. 4 is a diagram showing a configuration of a bandpass filter according to a third embodiment of the present invention.

FIG. 5 is a diagram showing a configuration of a bandpass filter according to a fourth embodiment of the present invention.

FIG. 6 is a diagram showing a configuration of a bandpass filter according to a fifth embodiment of the present invention.

FIG. 7 is a diagram showing a configuration of a conventional bandpass filter.

[Explanation of symbols]

1, 11, 21, 31, 41 I / O terminals 2, 12,
22, 32, 42 SIR (resonator), 3, 5, 13, 2
3, 33, 35, 43 Low impedance line, 4, 1
4, 15, 24, 25, 34, 44 High impedance line, 40 Coaxial line outer conductor, 45 Transmission line, 9, 1
9, 29, 39 Dielectric substrate, 48 Dielectric.

Continued front page    (72) Inventor Yukinobu Furukawa             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. (72) Inventor Miya ▲ Saki ▼ Mamoru ▲ Yasushi ▼             2-3 2-3 Marunouchi, Chiyoda-ku, Tokyo             Inside Ryo Electric Co., Ltd. F-term (reference) 5J006 HB03 JA01 LA01 MB01 NA08                       NC02 NE13 NE14

Claims (5)

[Claims] 1. A bandpass filter comprising a plurality of resonators, wherein each resonator is constituted by a cascade connection of low-high-low impedance lines, and at least one resonator has a small amount in a high-impedance line section. A band-pass filter, wherein low-impedance lines of different lengths are provided, and each of the characteristic impedances, lengths, and positions of the low-impedance lines is made different in each resonator. 2. A band pass filter comprising a plurality of resonators, wherein each resonator is constituted by cascade connection of low-high-low impedance lines, and at least one resonator is further provided in the high impedance line section. A minute impedance high impedance line having a high characteristic impedance is provided, and any one of the characteristic impedance, the length and the position of the high impedance line having a higher characteristic impedance is made different in each resonator. A bandpass filter characterized by. 3. A band pass filter comprising a plurality of resonators, wherein each resonator is constituted by a cascade connection of high-low-high impedance lines, and at least one resonator has a small amount in a low impedance line section. A band-pass filter, characterized in that a high-impedance line having a different length is provided and any one of characteristic impedance, length and position of the high-impedance line is made different in each resonator. 4. A band pass filter comprising a plurality of resonators, wherein each resonator is constituted by a cascade connection of high-low-high impedance lines, and at least one resonator is further provided in the low impedance line section. A small length low impedance line having a low characteristic impedance is provided, and any one of the characteristic impedance, the length and the position of the low impedance line having a lower characteristic impedance is made different in each resonator. A bandpass filter characterized by. 5. A bandpass filter comprising a plurality of resonators, wherein the resonators according to any one of claims 1 to 4 are mixed.