CN113972456B - Three-order wide stop band 5G microstrip filter - Google Patents

Abstract

The invention discloses a three-order wide stop band 5G microstrip filter, which belongs to the technical field of communication and comprises a dielectric substrate, wherein the upper surface of the dielectric substrate is provided with a first novel composite resonator, a second novel composite resonator, a half-wavelength resonator, an input feeder, an output feeder, a first J converter and a second J converter, the half-wavelength resonator is arranged on a central axis of the dielectric substrate, one end of the first J converter is connected with the input feeder, the other end of the first J converter carries out tap feeding on the first novel composite resonator, the half-wavelength resonator carries out gap coupling feeding with the first J converter and the second J converter respectively, one end of the second J converter carries out tap feeding with the second novel composite resonator, and the other end of the second J converter is connected with the output feeder; the filter of the invention has two different resonators, and the stop band of the filter is widened by staggering the higher harmonics of the two different resonators, and the filter of the invention can cover a mobile low-frequency 5G frequency band.

Description

Three-order wide stop band 5G microstrip filter

Technical Field

The invention relates to the technical field of communication, in particular to a three-order wide stop band 5G microstrip filter.

Background

The filter plays a crucial role in the evolution of the radio communication system over the past generation as an important passive device in the radio frequency part. In recent years, attention has been paid to out-of-band rejection characteristics of filters, miniaturization of filters, wide stop-band rejection, and the like. A filter with good performance can lead signals in an operating frequency band to pass through without loss, and signals outside the operating frequency band are suppressed as much as possible. In the background of the rapid development of wireless communication, how to increase the out-of-band rejection characteristic of the filter to reduce interference to other frequency bands is also one of the important research points of the filter. Microstrip filters also have the advantages of simple fabrication process, short fabrication cycle, and low cost, and are often used as part of discrete devices in radio frequency circuits.

The existing filter mostly adopts several designs of the traditional cascade type band-pass filter as chapter 5 of reference [1] in the design of a coupling structure, namely, the traditional filter is coupled from a source to resonators, the resonators are coupled, and the final-order resonator is coupled with a load. This cascaded coupling structure generally becomes bulky as the order of the resonator increases, and has the disadvantage of lacking a transmission zero. Therefore, the special coupling structure is adopted, so that the size of the filter can be reduced to a certain extent, and the number of transmission zeros of the filter can be increased. Reference [2] proposes a novel coupling structure, which is used to design a filter by connecting the resonators to the terminals of a J-converter and coupling the resonators to the next stage. However, the dual-band resonator is similar to a three-half wavelength ladder impedance resonator, so that the overall size of the filter is large and the stop-band characteristic is not good.

Although the filter composed of the composite resonator in reference [3] has many transmission zeros, the composite resonator is a half-wavelength ladder impedance resonator which resonates to provide a resonance mode, and the high-frequency stop band of the filter is narrow due to the coupling mode of the J-converter cascade.

In addition, reference [2]]And [3]In the volume of the filter, reference [2]]Is 1.16 lambda_g×0.48λ_gReference document [3]Is 0.74 lambda_g×0.52λ_g，（λ_gThe guided wave wavelength corresponding to the central frequency of the filter) is larger in volume; on the stop band of the filter, reference [2]]Stop band 3.27f ₀|_25dBAnd reference document [3]Stop band 0.5f ₀|_20dBAll are relatively narrow. (3.27f ₀|_20dBRepresents: from the operating frequencyf ₀To 3.27 timesf ₀In a frequency range of filters having20dB stop band rejection)

[1] J. S. Hong and M. J. Lancaster, Microwave Filter for RF/Microwave Application [M]. New York, NY, USA: Wiley, 2001.

[2] R. Gómez-García, L. Yang, J.–M. Muñoz-Ferreras and D. Psychogiou, Selectivity-enhancement technique for stepped-impedance-resonator dual-passband filters [J]. IEEE Microwave Wireless Component Letters, 2019, vol. 29(7): 453-455.

[3] Z. Ma and Y. Kobayashi, Design and realization of bandpass filters using composite resonators to obtain transmission zeros [C]. 35th European Microwave Conference Proc., 2005: 1255-1258.

[4] R. J. Cameron, General coupling matrix synthesis methods for Chebyshev filtering functions [J]. IEEE Trans. Microwave Theory Tech., 1999, vol. 47(4): 433-442.

Some specific english explanations will be mentioned here:

a J converter: inverting the converter; frequency: frequency; amplitude: an amplitude;

normalized Frequency: normalizing the frequency; simulation, simulating an S parameter curve;

measurement: testing an S parameter curve; FBW: relative bandwidth;

s: a source; l: a load; r: a resonator is provided.

Disclosure of Invention

In view of the above problems, the present invention has the object of: a high-selectivity wide-stop-band microstrip filter is designed based on a novel composite resonator and a half-wavelength resonator.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows: a three-order wide stop band 5G microstrip filter comprises a dielectric substrate, wherein two novel composite resonators, a half-wavelength resonator, two J converters and a 50 omega feeder line are arranged on the upper surface of the dielectric substrate. The half-wavelength resonator is arranged on an axial line of the dielectric substrate, the first J converter is connected with a 50 omega input feeder line, the first novel composite resonator carries out tap feeding through a terminal of the first J converter, and the first J converter carries out gap coupling feeding with the half-wavelength resonator. And then, the half-wavelength resonator is in gap coupling with the second J converter, the terminal of the second J converter is in tap feed with the second novel composite resonator, and finally the second J converter is connected with a 50 omega output feeder line.

Preferably, the novel composite resonator is formed by connecting a short-circuit branch and an open-circuit branch in parallel, the short-circuit branch and the open-circuit branch are located on one side close to the feeder line, and the short-circuit branch is close to the J converter.

Preferably, the novel composite resonator is coupled with a feeder terminal tap through a J converter, the whole circuit is rotationally and symmetrically arranged along the central point of the dielectric substrate, and a transmission zero point (shown in figure 5) close to a passband is respectively generated at the symmetrical positions of the central frequency pointf _z1Andf _z2）。

preferably, the half-wavelength resonator provides only one resonant mode and does not produce a transmission zero. And the use of two different resonators facilitates achieving a wide stop-band rejection of the filter.

Preferably, a coupling topology of a third-order filter is formed: the input source feeds the novel composite resonator and the half-wavelength resonator respectively in a terminal tapping mode and a gap coupling mode of the J converter, the half-wavelength resonator outputs the load in the gap coupling mode, and meanwhile the load is connected with the other novel composite resonator in a tapping mode through the other J converter.

Preferably, the corresponding normalized coupling matrix is obtained by synthesis according to the coupling topological structure of the third-order filter.

Preferably, the corresponding normalized frequency response is calculated according to the normalized coupling matrix.

Preferably, the operating band of the microstrip filter is set to 2.515GHz-2.675GHz (mobile 5G band).

Preferably, the whole volume of the circuit is 0.53 lambda_g×0.26λ_g（λ_gA guided wavelength corresponding to 2.6 GHz).

Compared with the prior art, the invention has the beneficial effects that:

1. a novel composite resonator is adopted, a normalized coupling matrix of the filter is obtained by constructing a coupling topological structure of the filter, and then normalized frequency response is obtained through calculation. The two novel composite resonators and the half-wavelength resonator are adopted to form the third-order band-pass filter, and the stop band of the filter is effectively widened;

2. on the stop band characteristic, because novel composite resonator belongs to quarter-wave resonator resonance, have natural advantage on the stop band and the filter uses two kinds of different syntonizers, can stagger the higher harmonic of two kinds of filters and make the stop band characteristic of filter 4.6f ₀There is 20dB stop band rejection in the range.

Drawings

Fig. 1 is a schematic circuit diagram of a third-order wide stop-band microstrip filter according to an embodiment.

FIG. 2 is a schematic diagram illustrating the dimensions of a third-order wide stop-band microstrip filter according to an embodiment.

FIG. 3 is a schematic diagram of a third-order wide stop-band microstrip filter coupling topology according to an embodiment.

FIG. 4 is a diagram illustrating a normalized coupling matrix corresponding to the filter coupling topology according to an embodiment.

FIG. 5 is a diagram illustrating a normalized frequency response corresponding to the normalized coupling matrix in the example.

FIG. 6 is a schematic diagram of a third-order wide stop-band microstrip filter according to an embodiment.

FIG. 7 is a schematic diagram of an embodiment of a third-order wide stop-band microstrip filter with a variable short-circuit stub lengthfAnd influence on transmission zero is shown schematically.

FIG. 8 is a schematic diagram of an embodiment of a third-order wide stop-band microstrip filter with varying length of open-circuit brancheshAnd influence on transmission zero is shown schematically.

FIG. 9 is a diagram illustrating simulation and test comparison of the narrow-band frequency response of the third-order wide-stop-band microstrip filter in the embodiment.

FIG. 10 is a diagram illustrating simulation and test comparison of the broadband frequency response of the third-order wide stop-band microstrip filter in the embodiment.

Detailed Description

The invention will be clearly and completely explained below with reference to the drawings and the specific embodiments.

The processing plate of the third-order wide stop band filter is an FR4 plate with the relative dielectric constant of 4.4 and the thickness of 1 mm. The upper surface of the dielectric plate is a microstrip line, the thickness of the copper-clad microstrip line is 0.035mm, and the lower surface of the dielectric plate is a copper-clad metal ground. Fig. 1 is a circuit detail diagram of a third-order wide stop-band microstrip filter. Fig. 1 shows a configuration of a novel composite resonator, a feeding mode of the novel composite resonator, and a coupling mode between a J-converter and a half-wavelength resonator. The method specifically comprises the following steps: the utility model provides a third-order wide stopband 5G microstrip filter, includes the dielectric substrate, the dielectric substrate upper surface is equipped with first novel composite resonator, the novel composite resonator of second, half wavelength resonator, input feeder, output feeder, first J converter and second J converter, half wavelength resonator sets up on the medium substrate axis, first J converter one end with input feeder connects, and the other end carries out the feed of taking a percentage to first novel composite resonator, half wavelength resonator respectively with first J converter and second J converter carry out the gap coupling feed, the one end of second J converter with the novel composite resonator of second carries out the feed of taking a percentage, the other end with output feeder connects.

Fig. 2 is a labeled schematic diagram of a third-order wide stop-band microstrip filter. Radius of grounding hole of short-circuit branchrIs 0.25 mm. The short-circuit branch is closer to the J converter, and the open-circuit branch is bent to realize miniaturization. The whole circuit is rotationally symmetrical about the center of the half-wavelength resonator.

Table 1: the specific dimensioning in fig. 2 is given in units: mm;

fig. 3 shows a coupling topology of a third order wide stop band filter. S denotes a source and L denotes a load. The dotted line frame represents a novel composite resonator having a resonant frequency off ₀Each with R₁And R₃And (4) showing. Wherein the nodes 2 and 5 represent short-circuit branches and have a resonant frequency off _z1. Node 1 and node 4 represent open-circuit branches with a resonant frequency off _z2. Half-wavelength resonator 3 (R)₂) Shows that its resonant frequency isf ₀. The solid line between the two nodes represents the tap feed mode and the dashed line represents the slot coupling mode.

From the coupling topology of fig. 3, the normalized coupling matrix of fig. 4 can be obtained by calculation.

Step 1: setting a target filter index: the return loss is 20dB, two transmission zeros are positioned at the positions of +/-3 j, and the normalized resonant frequency of the half-wavelength resonator and the novel composite resonator is 0;

step 2: obtaining a reflection coefficient polynomial according to the following formula

And transmission coefficient polynomial

：

（2）

Where N =3 represents the filter order, and RL is the predetermined reflection coefficient 20 dB. From the above formula

The position of the transmission zero point is determined,

the position of the reflection zero point is determined. Wherein,

will be provided with

By substitution of the formula

Will be provided with

= 3，

= -3，

Carry in = ∞ and recursively calculate polynomial

And

：

wherein

=

，

Determined by the position of the preset transmission zero point,

by

And

jointly determine that

And

substituted into the following formula and let s =

：

Where m is a coupling matrix, I is a unit matrix (source reference 4), and values in the normalized coupling matrix can be integrated by substituting preset transmission zero positions and return loss into equations (11) and (12), and obtaining:

and step 3: as shown in fig. 4, the matrix is a 7 x 7 matrix, S, L and the numbers 1-5 correspond to nodes in the coupled topology. M at diagonal line₁₁ = m₄₄=3 denotes that the open branch node generates a transmission zero m at the position of the normalized frequency 3 (at the high frequency of the pass band)₂₂ = m₅₅And =3 indicates that the position of the normalized frequency-3 (at the low frequency of the pass band) produces one transmission zero. When the open-circuit branch and the short-circuit branch are in parallel resonance, namely the novel composite resonator is in resonance, a transmission pole is generated at the normalized frequency 0 (passband). m is₃₃= 0 denotes a half-wavelength resonator R₂Operating at the normalized frequency 0 (passband) produces a transmission pole.

After the normalized coupling matrix is obtained, the normalized external quality factor value can be calculated by equations (13) - (17).

After the normalized coupling matrix and the quality factor q are determined, the normalized frequency response of the filter can be obtained according to equations (3) - (5).

Wherein,

is a matrix

Inverse matrix of

The value corresponding to the ith row and the jth column in the matrix

Can be calculated by the following formula:

matrix array

Is a normalized coupling matrix.

Is a 7 × 7 identity matrix except

=

And = 0. Matrix array

Is a 7 x 7 all-zero matrix except

=

=1, Ω is the normalized frequency.

Fig. 5 is a normalized frequency response of a third order wide stop band filter. As can be seen from the response, the filter is a third-order bandpass filter, has three transmission poles, and has a transmission zero at + -3 positions of the passband symmetryf _z1Andf _z2the passband selectivity and out-of-band rejection of the filter are enhanced.

The operating frequency of the filter is set to the shifted 5G low band: 2.515GHz-2.675GHz, 20dB FBW is 6.17%. The actual external Q value can be calculated using the following equation:

FIG. 6 is a diagram of a third order wide stop band filter with an overall size of 0.53 λ_g×0.26λ_g（λ_gA guided wavelength corresponding to 2.6 GHz).

Then two transmission zeros of a filter in an actual microstrip circuit and a circuit structure are exploredThe relationship of the parameters (c). Fig. 7 is a graph for investigating the effect of the short-circuit stub length of the novel composite resonator on the transmission zero. It can be seen from the figure that the transmission zero point at low frequency is located when only the short circuit branch length (2.4 mm-3.4 mm) is changedf _z1Transmission zero point varying from high frequency to low frequency and located at high frequencyf _z2The position remains substantially unchanged. It can be concluded from this that the short-circuit stub length of the novel composite resonator influences the transmission zerof _z1The position of (a).

Fig. 8 is a graph for investigating the effect of the open-circuit stub length of the novel composite resonator on the transmission zero. When the length of the open-circuit branch is changed from 8mm to 9mm and other size parameters are kept unchanged, the transmission zero pointf _z1Remains substantially unchanged at the transmission zero point of high frequencyf _z2Moving towards low frequencies. Thus transmission zero pointf _z2Is mainly determined by the length of the open-circuit branch in the novel composite resonator.

Fig. 9 is a narrow-band frequency response of a third-order wide stop-band filter, where the solid line is the simulation curve and the dashed line is the test curve. From the figure it can be seen that: and the transmission zero points are arranged at the two sides of the passband and are approximately symmetrical relative to the center frequency, so that the out-of-band rejection and the passband selectivity of the filter are improved. The three transmission poles and the two approximately symmetrical transmission zeros of the simulation plot demonstrate the previously normalized frequency response. The test curve is approximately consistent with the simulation curve.

FIG. 10 is a wideband frequency response (1 GHz-12 GHz) for a third order wide stop band filter. Similarly, the solid line is a simulation curve, the dotted line is a test curve, and the simulation curve is well matched with the test curve. Because the filter adopts two different resonators and coupling modes, the stop band of the filter is expanded. As can be seen from FIG. 10, the simulation curve is at 4.6f ₀There is 15dB stop band rejection in the range. Test curve at 4.6f ₀There is a 20dB stop band rejection in the range.

The above is a detailed description of the preferred embodiments of the invention, but the invention is not limited to the examples. Those skilled in the art can make various equivalent changes or substitutions without departing from the spirit of the present invention, and such equivalent changes or substitutions are included in the scope defined by the claims of the present application.

Claims (10)

1. The utility model provides a three-order wide stop band 5G microstrip filter which characterized in that: the medium-frequency-domain resonant cavity comprises a medium substrate, wherein a first composite resonator, a second composite resonator, a half-wavelength resonator, an input feeder line, an output feeder line, a first J converter and a second J converter are arranged on the upper surface of the medium substrate, the half-wavelength resonator is arranged on an axial line of the medium substrate, one end of the first J converter is connected with the input feeder line, the other end of the first J converter carries out tap feeding on the first composite resonator, the half-wavelength resonator carries out gap coupling feeding on the first J converter and the second J converter respectively, one end of the second J converter carries out tap feeding on the second composite resonator, and the other end of the second J converter is connected with the output feeder line;

the composite resonator is formed by connecting a short-circuit branch knot and an open-circuit branch knot in parallel, the short-circuit branch knot and the open-circuit branch knot are located on one side close to the feeder line, the short-circuit branch knot is close to the J converter, and the open-circuit branch knot is bent, so that the miniaturization of the filter is realized.

2. The three-order wide stop band 5G microstrip filter of claim 1, wherein: the first composite resonator, the first J converter, the second composite resonator and the second J converter are arranged in a rotational symmetry mode according to the center point of the dielectric substrate.

3. The three-order wide stop band 5G microstrip filter of claim 1, wherein: the composite resonator belongs to quarter-wave resonator resonance, the filter uses two different resonators to stagger higher harmonics of the two filters, and the actual measurement stop band characteristic of the filter is 4.6f₀There is 20dB stop band rejection in the range.

4. The three-order wide stop band 5G microstrip filter of claim 1, wherein: forming a coupling topological structure of the microstrip filter according to the coupling relation between the composite resonator and the half-wavelength resonator, and obtaining a corresponding normalized coupling matrix and a normalized frequency response according to the coupling topological structure; the topological structure is as follows: the input source respectively feeds power to the composite resonator and the half-wavelength resonator in a terminal tapping mode and a gap coupling mode of the J converter, the half-wavelength resonator outputs power to a load in the gap coupling mode, and meanwhile the load is connected with the other composite resonator in a tapping mode through the other J converter.

5. The three-order wide stop band 5G microstrip filter of claim 4, wherein: the calculation method of the normalized coupling matrix comprises the following steps:

step 1: setting the return loss and two transmission zero positions of a target filter;

step 2: obtaining a reflection coefficient polynomial S according to the following formula₁₁(omega) and transmission coefficient polynomial S₂₁(ω)：

Wherein, N represents the order of the filter, and RL is a preset reflection coefficient; from the above formula, P is_N(omega) determining the position of the transmission zero, F_N(ω) determining the position of the reflection zero; wherein,

g is to be_N(ω) replacement by the formula

G_N(ω)＝U_N(ω)+V_N(ω)

Will omega₁、ω₂And ω₃Is substituted into the above formula and a polynomial U is recursively calculated₃(omega) and V₃(ω) value; polynomial U₃(ω)＝F₃(omega) and V₃(omega) is converted into a complex plane corresponding value, and a corresponding reflection polynomial and a corresponding transmission polynomial can be calculated;

and step 3: constructing an all-zero 7 x 7 normalized coupling matrix, and using m as the value with coupling relation in the matrix according to the coupling relation between resonators in the coupling topological structure_ijRepresentation, where i, j refers to the ith row and jth column in the matrix, S, L represents the source and load, respectively:

among them, because of the reciprocal matrix, there are:

because the coupling topology is symmetrical about the half-wavelength resonator, there are:

m_iS＝m_S(6-i)i＝1,2,3

the composite resonator is fed by a terminal tap of the J converter, and normalized transmission zero points generated by the open-circuit branch and the short-circuit branch are symmetrical about a Y axis, so that the composite resonator has the following characteristics:

m_S1＝m_S2

m_L4＝m_L5

and (4) calculating to obtain a complete normalized coupling matrix according to the polynomial obtained by calculation in the step (2) and the preset transmission zero position.

6. The three-order wide stop band 5G microstrip filter of claim 4, wherein: the calculation method of the normalized frequency response comprises the following steps:

wherein,

is a matrix [ A]Inverse matrix of [ A ]]^-1The matrix [ A ] is the value corresponding to the ith row and the jth column]Can be calculated by the following formula:

[A]＝[m]+Ω[U]-j[q]

matrix [ m ]]Is a normalized coupling matrix; matrix [ U ]]Is a 7 × 7 identity matrix except for [ U]₁₁＝[U]₇₇0; matrix [ q ]]Is a 7 x 7 all-zero matrix except for [ q]₁₁＝[q]₇₇1, Ω is the normalized frequency.

7. The three-order wide stop band 5G microstrip filter of claim 1, wherein: when the short-circuit branch and the open-circuit branch in the composite resonator are independently resonated, a transmission zero is generated at the low frequency and the high frequency of the passband of the filter respectively; when the short-circuit branch and the open-circuit branch in the composite resonator are in parallel resonance, a transmission pole can be generated in the pass band of the filter.

8. The three-order wide stop band 5G microstrip filter of claim 1, wherein: the dielectric substrate is an FR4 board with the relative dielectric constant of 4.4 and the thickness of 1 mm; the input feeder line and the output feeder line are 50 omega feeder lines.

9. The three-order wide stop band 5G microstrip filter of claim 1, wherein: the upper surface of the dielectric substrate is provided with microstrip line wiring, the thickness of copper coated by the microstrip line is 0.035mm, and the lower surface of the dielectric substrate is provided with a copper-coated metal ground.

10. The third-order wide stop-band 5G microstrip filter according to any of claims 1-9, wherein: the filter works at 2.515GHz-2.675GHz covering mobile 5G low frequency band.

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