CN209515949U - A kind of plane bandpass filter based on parallel coupled line - Google Patents
A kind of plane bandpass filter based on parallel coupled line Download PDFInfo
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- CN209515949U CN209515949U CN201920159105.XU CN201920159105U CN209515949U CN 209515949 U CN209515949 U CN 209515949U CN 201920159105 U CN201920159105 U CN 201920159105U CN 209515949 U CN209515949 U CN 209515949U
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Abstract
The utility model discloses a kind of plane bandpass filters based on parallel coupled line, are produced on double-sided copper-clad micro-strip plate in the manner of a printed circuit board, wherein one side is micro-strip routing layer, in addition for one side to cover copper earth plate, centre is dielectric layer;The first feeder line port and its first feeder line, the second feeder line port and its second feeder line, the first, second and third resonator are respectively equipped on micro-strip routing layer;First, second and third resonator is between the first and second feeder line, and between the first and third resonator, the first, second and third resonator is made of the second resonator the microstrip line of half wavelength.The utility model can improve bandpass filter selection characteristic in passband two sides two transmission zeros of formation by adjusting the length of coupling line segment to realize.Such structure is simple, and the resonant element to be intercoupled by several is constituted, and brings the problems such as design is complicated, volume is big without increasing order or additional microstrip line.
Description
Technical field
The utility model relates to the technical fields of filter, refer in particular to a kind of plane band logical filter based on parallel coupled line
Wave device.
Background technique
Wireless communication technique is grown rapidly, and the division between each frequency range is more and more finer, therefore each communications band of bring
Between interference phenomenon it is also increasingly severe, so the performance of bandpass filter determines the work quality of communication system.Band logical
Filter refers to that the wave for allowing special frequency channel passes through, while shielding other frequency ranges, operates mainly in the prime of signal transmitting terminal
Guarantee the pure of desired signal for inhibiting harmonic wave and noise signal with the rear class of signal receiving end.Therefore, certain specific
Occasion under, the selection characteristic of bandpass filter has become the most important thing, and higher selection characteristic brings lower signal
Interference and stable channel communication quality.There are many kinds of the implementations of plane bandpass filter, has step than more typical
Impedance bandpass filter and parallel coupling line band-pass filter, its selection characteristic is not in the case where no specially treated
Very well.In order to overcome the disadvantages and deficiencies of the prior art, this paper presents a kind of plane bandpass filtering based on parallel coupled line
Device, the length by adjusting coupling line segment form two transmission zeros in passband two sides, have reached and improve bandpass filter selection
The purpose of characteristic.
Utility model content
The shortcomings that the purpose of the utility model is to overcome the prior arts and deficiency propose a kind of based on parallel coupled line
Plane bandpass filter the length for adjusting coupling line segment is passed through using the design method based on parallel coupling line band-pass filter
Degree forms two transmission zeros in passband two sides to realize and improve bandpass filter selection characteristic.Such structure is simple, by several
The resonant element to intercouple is constituted, and brings design is complicated, volume is big etc. without increasing order or additional microstrip line
Problem.
To achieve the above object, a kind of technical solution provided by the utility model are as follows: plane based on parallel coupled line
Bandpass filter is produced in the manner of a printed circuit board on double-sided copper-clad micro-strip plate, wherein one side is micro-strip routing layer, in addition
On one side to cover copper earth plate, centre is dielectric layer;The first feeder line port and its first are respectively arranged on the micro-strip routing layer
Feeder line, the second feeder line port and its second feeder line, the first resonator, the second resonator and third resonator;First feeder line
Port is vertical with the first feeder line, constitutes L-shaped structure, for feed-in or feeds out electromagnetic wave signal;Second feeder line port with
Second feeder line is vertical, constitutes L-shaped structure, for feed-in or feeds out electromagnetic wave signal;First feeder line and the second feeder line are flat
Row, between the first feeder line and the second feeder line, described second is humorous for first resonator, the second resonator and third resonator
Device shake between the first resonator and third resonator, first resonator is close to the first feeder line, the third resonator
Close to the second feeder line;First resonator, the second resonator and third resonator by half wavelength microstrip line structure
At;First resonator is integrally in U-like shape structure, is made of first transmission line, second transmission line and third transmission line, described
First transmission line and third transmission line are parallel to each other, and are respectively perpendicular to the both ends of second transmission line;Second resonator with
First resonator is in mirror image, is made of the 4th transmission line, the 5th transmission line and the 6th transmission line, the 4th transmission
Line and the 6th transmission line are parallel to each other, and are respectively perpendicular to the both ends of the 5th transmission line;The third resonator is integrally in U-like shape
Structure is made of the 7th transmission line, the 8th transmission line and the 9th transmission line, and the 7th transmission line and the 9th transmission line are mutually flat
Row, and it is respectively perpendicular to the both ends of the 8th transmission line;First feeder line port and the first feeder line pass through coupling gap to first
Resonator is fed, and first feeder line is parallel with first transmission line;Second feeder line port and the second feeder line pass through coupling
It closes gap to feed third resonator, second feeder line is parallel with the 9th transmission line;Second resonator passes through the
Four transmission lines are coupled with the first resonator, are coupled by the 6th transmission line with third resonator;First resonator and second
The main coupling unit of resonator is third transmission line and the 4th transmission line, and length is longer than quarter-wave, can be in passband
Downside generates a transmission zero, and second resonator and the main coupling unit of third resonator are the 6th transmission line and the 7th
The part that transmission line is overlapped, this segment length are shorter than quarter-wave, and a transmission zero can be generated on the upside of passband, passes through tune
The length for saving coupling unit at above-mentioned two can adjust the location of two transmission zeros, thus formed one it is highly selective
Bandpass filter.
Further, first feeder line port is identical as the second feeder line port width.
Further, the first transmission line, second transmission line, third transmission line, the 4th transmission line, the 5th transmission line,
Six transmission lines, the 7th transmission line, the 8th transmission line and the 9th transmission line are of same size.
The utility model compared with prior art, have the following advantages that with the utility model has the advantages that
1, the utility model is the single layer structure of plane, designs simple and clear, easy debugging.
2, the utility model is based on parallel coupling structure, does not load additional transmissions line.
3, the utility model rationally utilizes parallel coupled line filter structure to realize highly selective.
4, the utility model is small in size, and the processing is simple, at low cost, is applicable to plurality of communication systems.
Detailed description of the invention
Fig. 1 be the utility model proposes plane bandpass filter structural schematic diagram.
Fig. 2 be the utility model proposes plane bandpass filter scale diagrams.
Fig. 3 be the utility model proposes plane bandpass filter simulation result diagram.
Specific embodiment
To keep the purpose of this utility model, technical solution and advantage clearer, clear, develop simultaneously implementation referring to the drawings
The utility model is further described in example.It should be appreciated that specific embodiment described herein is only used to explain this reality
With novel, it is not used to limit the utility model.
As shown in Figure 1, the plane bandpass filter based on parallel coupled line provided by the present embodiment, with printed circuit board
Mode be produced on double-sided copper-clad micro-strip plate, wherein one side is micro-strip routing layer, in addition to cover copper earth plate, centre is one side
Dielectric layer.Be respectively arranged on the micro-strip routing layer the first feeder line port 1 and its first feeder line 2, the second feeder line port 13 and
Its second feeder line 12, the first resonator R1, the second resonator R2 and third resonator R3;First feeder line port 1 and first
Feeder line 2 is vertical, constitutes L-shaped structure, for feed-in or feeds out electromagnetic wave signal;Second feeder line port 13 and the second feeder line
12 is vertical, constitutes L-shaped structure, for feed-in or feeds out electromagnetic wave signal;First feeder line port 1 and the second feeder line port
13 is of same size;First feeder line 2 is parallel with the second feeder line 12, the first resonator R1, the second resonator R2 and third
For resonator R3 between the first feeder line 2 and the second feeder line 12, the second resonator R2 is located at the first resonator R1 and third
Between resonator R3, the first resonator R1 is close to the first feeder line 2, and the third resonator R3 is close to the second feeder line 12;Institute
The first resonator R1, the second resonator R2 and third resonator R3 is stated to be made of the microstrip line of half wavelength;Described
One resonator R1 is integrally in U-like shape structure, is made of first transmission line 3, second transmission line 4 and third transmission line 5, described first
Transmission line 3 and third transmission line 5 are parallel to each other, and are respectively perpendicular to the both ends of second transmission line 4;The second resonator R2 with
First resonator R1 is in mirror image, is made of the 4th transmission line 6, the 5th transmission line 7 and the 6th transmission line 8, and described the
Four transmission lines 6 and the 6th transmission line 8 are parallel to each other, and are respectively perpendicular to the both ends of the 5th transmission line 7;The third resonator R3
Whole is in U-like shape structure, is made of the 7th transmission line 9, the 8th transmission line 10 and the 9th transmission line 11, the 7th transmission line 9
It is parallel to each other with the 9th transmission line 11, and is respectively perpendicular to the both ends of the 8th transmission line 10;The first transmission line 3, second passes
Defeated line 4, third transmission line 5, the 4th transmission line 6, the 5th transmission line 7, the 6th transmission line 8, the 7th transmission line 9, the 8th transmission line
10 and the 9th transmission line 11 it is of same size;First feeder line port 1 and the first feeder line 2 pass through coupling gap to the first resonator
R1 is fed, and first feeder line 2 is parallel with first transmission line 3;Second feeder line port 13 passes through with the second feeder line 12
Coupling gap feeds third resonator R3, and second feeder line 12 is parallel with the 9th transmission line 11;Second resonance
Device R2 is coupled by the 4th transmission line 6 with the first resonator R1, is coupled by the 6th transmission line 8 with third resonator R3;It is described
The main coupling unit of first resonator R1 and the second resonator R2 are that third transmission line 5 and the 4th transmission line 6, length are slightly longer
In quarter-wave, a transmission zero, the second resonator R2 and third resonator R3 master can be generated on the downside of passband
Wanting coupling unit is the part that the 6th transmission line 8 and the 7th transmission line 9 are overlapped, this segment length is slightly shorter than quarter-wave, meeting
A transmission zero is generated on the upside of passband, by adjustable two transmission zeros of length for adjusting coupling unit at above-mentioned two
Location can thus form a highly selective bandpass filter.
As shown in Fig. 2, printed circuit board used in the utility model with a thickness of 0.8mm, electric medium constant 2.45.The knot
The width of two feeder line ports of structure is W2=1.5mm, and the width of transmission line 2-12 is all W1=1mm, the length ruler of each transmission line
Very little parameter are as follows:
L1=4, L2=14.8, L3=15.3, L4=3.4, L5=18.7, L6=2, L7=13.3, L8=3.9, L9=
16.3, S1=0.45, S2=0.85, S3=0.65, S4=0.7 (unit is equal are as follows: mm).
The utility model is emulated using simulation software Advanced Design System (ADS), and Fig. 3 is that this is practical
The scattering parameter simulation result diagram of the plane bandpass filter of novel proposition.Horizontal axis indicates flat filter in the utility model
Signal frequency, the longitudinal axis indicate amplitude, including return loss S11Amplitude and insertion loss S21Amplitude, wherein S11Indicate feed-in
The return loss of line end mouth, S21Indicate the relationship of filter input signal frequency and output signal frequency in the utility model,
Corresponding mathematical function are as follows: output power/input power (dB)=20*log | S21|.In the signal of the filter of the utility model
In transmission process, the Partial Power of signal is reflected back toward signal source, and the power reflected becomes reflection power.Return loss indicates
Relationship between the input power of the port signal and the reflection power of signal, corresponding mathematical function are as follows: reflection power/
Incident power (dB)=20*log | S11|。
From figure 3, it can be seen that when signal is inputted from the first feeder line port 1, have at centre frequency 3GHz signal from
The output of second feeder line port 13, and the insertion loss in passband is smaller, in 1.5dB or so, return loss is in 16.5dB or less;
Outside passband, it can be seen that the transmission zero positioned at 2.8GHz formed by the first resonator R1 and the second resonator R2, and
The transmission zero positioned at 3.2GHz formed by the second resonator R2 and third resonator R3, at two transmission zero all-
60dB is hereinafter, illustrate that transmission characteristic has very high selectivity.
Above-described embodiment is the preferable embodiment of the utility model, but the embodiments of the present invention is not by above-mentioned
The limitation of embodiment, it is made under other any spiritual essence and principles without departing from the utility model to change, modify, replacing
In generation, simplifies combination, should be equivalent substitute mode, is included within the protection scope of the utility model.
Claims (3)
1. a kind of plane bandpass filter based on parallel coupled line, is produced on double-sided copper-clad micro-strip in the manner of a printed circuit board
On plate, wherein one side is micro-strip routing layer, in addition for one side to cover copper earth plate, centre is dielectric layer;It is characterized by: described micro-
The first feeder line port and its first feeder line, the second feeder line port and its second feeder line, first humorous are respectively arranged on band routing layer
Shake device, the second resonator and third resonator;First feeder line port is vertical with the first feeder line, L-shaped structure is constituted, for presenting
Enter or feed out electromagnetic wave signal;Second feeder line port is vertical with the second feeder line, constitutes L-shaped structure, for feed-in or
Feed out electromagnetic wave signal;First feeder line is parallel with the second feeder line, first resonator, the second resonator and third resonance
Device is between the first feeder line and the second feeder line, and second resonator is between the first resonator and third resonator, institute
The first resonator is stated close to the first feeder line, the third resonator is close to the second feeder line;First resonator, the second resonator
It is made of with third resonator the microstrip line of half wavelength;First resonator is integrally in U-like shape structure, by first
Transmission line, second transmission line and third transmission line composition, the first transmission line and third transmission line are parallel to each other, and hang down respectively
Directly in the both ends of second transmission line;Second resonator and the first resonator are in mirror image, by the 4th transmission line, the
Five transmission lines and the 6th transmission line composition, the 4th transmission line and the 6th transmission line are parallel to each other, and are respectively perpendicular to the 5th
The both ends of transmission line;The third resonator is integrally in U-like shape structure, by the 7th transmission line, the 8th transmission line and the 9th transmission
Line composition, the 7th transmission line and the 9th transmission line are parallel to each other, and are respectively perpendicular to the both ends of the 8th transmission line;Described
One feeder line port feeds the first resonator by coupling gap with the first feeder line, first feeder line and first transmission line
In parallel;Second feeder line port feeds third resonator by coupling gap with the second feeder line, second feeder line
It is parallel with the 9th transmission line;Second resonator is coupled by the 4th transmission line with the first resonator, and the 6th transmission line is passed through
It is coupled with third resonator;The main coupling unit of first resonator and the second resonator is that third transmission line and the 4th pass
Defeated line, length are longer than quarter-wave, and a transmission zero, second resonator and third can be generated on the downside of passband
The main coupling unit of resonator is the part that the 6th transmission line and the 7th transmission line are overlapped, this segment length is shorter than quarter-wave
It is long, a transmission zero can be generated on the upside of passband, the length by adjusting coupling unit at above-mentioned two can adjust two biographies
The location of defeated zero point, to form a highly selective bandpass filter.
2. a kind of plane bandpass filter based on parallel coupled line according to claim 1, it is characterised in that: described
One feeder line port is identical as the second feeder line port width.
3. a kind of plane bandpass filter based on parallel coupled line according to claim 1, it is characterised in that: described
One transmission line, second transmission line, third transmission line, the 4th transmission line, the 5th transmission line, the 6th transmission line, the 7th transmission line,
Eight transmission lines and the 9th transmission line are of same size.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109713408A (en) * | 2019-01-30 | 2019-05-03 | 华南理工大学 | A kind of plane bandpass filter based on parallel coupled line |
CN111900519A (en) * | 2020-07-30 | 2020-11-06 | 武汉博畅通信设备有限责任公司 | Combiner based on microstrip line coupling |
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2019
- 2019-01-30 CN CN201920159105.XU patent/CN209515949U/en not_active Expired - Fee Related
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109713408A (en) * | 2019-01-30 | 2019-05-03 | 华南理工大学 | A kind of plane bandpass filter based on parallel coupled line |
CN111900519A (en) * | 2020-07-30 | 2020-11-06 | 武汉博畅通信设备有限责任公司 | Combiner based on microstrip line coupling |
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Granted publication date: 20191018 |