CN204205007U - Based on the double-frequency broadband band stop filter of many step impedance resonator loading structure - Google Patents

Abstract

The utility model discloses a kind of double-frequency broadband band stop filter based on many step impedance resonator loading structure, comprise the first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator, the first transmission line, the second transmission line, the first input/output port I/O, the second input/output port I/O, first transmission line one end is connected with the first input/output port I/O, the other end is connected with second transmission line one end, and the second transmission line other end is connected with the second input/output port I/O; First step impedance resonator is connected with the first input/output port I/O and first transmission line one end respectively, second step impedance resonator is connected with the first transmission line other end and second transmission line one end respectively, and the 3rd step impedance resonator is connected with the second transmission line other end and the second input/output port I/O respectively.The utility model can obtain the stopband of two wide bandwidths, and stopband has excellent skirt selectivity.

Description

Based on the double-frequency broadband band stop filter of many step impedance resonator loading structure

Technical field

The utility model relates to the technical field of high frequency assembly, refers in particular to a kind of double-frequency broadband band stop filter based on many step impedance resonator loading structure.

Background technology

Due to wireless communication technology develop rapidly and people to radio communication need day by day increase, current market 2G, 3G, 4G network is also deposited, many wireless terminals, such as mobile phone, panel computer etc., all wishing when designing can compatible multiple communication standard, this service that terminal use just can be allowed simultaneously to enjoy different operators provide.Multiband filter realizes multiple passband or stopband on a circuit simultaneously, can significantly reduce circuit size and reduce costs, and is therefore the focus of a research.

Flourish along with wireless messages industry in recent years, microwave spectrum resource is more and more deficienter, the division of frequency band is more and more meticulousr, utilance is more and more higher, in order to adapt to rational spectrum application and improve the performance of wireless communication system, band stop filter becomes one of part important in Circuits System, and the quality of its performance also largely determines the work quality of system.Band stop filter refers to and decays to extremely low-level filter by most of frequency component but by the frequency component of some scope, relative with the concept of band pass filter.Band stop filter is widely used in wireless communication system, is used for suppressing the spuious output of high power transmitter and the parasitic passband etc. of nonlinear power amplifier or band pass filter generation.

Spread bandwidth is for lifting communication speed important in inhibiting.Due to the development of broadband connections, wireless communication industry gets more and more to the demand of broadband device.But, but seldom there is now the design of the Broadband bandstop filter about double frequency.

Summary of the invention

The purpose of this utility model is to overcome the deficiencies in the prior art, a kind of double-frequency broadband band stop filter based on many step impedance resonator loading structure is provided, by using three step impedance resonator, the stopband of two wide bandwidths can be obtained, and stopband has excellent skirt selectivity, greatly can improve filter effect.

For achieving the above object, technical scheme provided by the utility model is: based on the double-frequency broadband band stop filter of many step impedance resonator loading structure, include the first step impedance resonator, second step impedance resonator, 3rd step impedance resonator, first transmission line, second transmission line, first input/output port I/O, second input/output port I/O, wherein, one end of described first transmission line is connected with the first input/output port I/O, its other end is connected with one end of the second transmission line, the other end of described second transmission line is connected with the second input/output port I/O, signal is from one of them input/output port I/O feed-in, export from another input/output port I/O, described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator interval are side by side, described first step impedance resonator is connected with one end of the first input/output port I/O and the first transmission line respectively, described second step impedance resonator is connected with the other end of the first transmission line and one end of the second transmission line respectively, and described 3rd step impedance resonator is connected with the other end of the second transmission line and the second input/output port I/O respectively, the transmission line serial connection that described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator differ by two articles of width forms.

The input impedance Z of described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator _inby formulae discovery below out:

$Z_{\mathrm{in}}=j{Z}_A\frac{Z_A\tan {\mathrm{\θ}}_A-Z_B\cot {\mathrm{\θ}}_B}{Z_A+Z_B\tan {\mathrm{\θ}}_A\cot {\mathrm{\θ}}_B}---\left(1\right)$

In formula, j is imaginary unit, Z _a, Z _bbe respectively the impedance of two transmission lines of step impedance resonator, θ _a, θ _bbe respectively the electrical length of two transmission lines of step impedance resonator;

By making Z _in=0 condition of resonance can trying to achieve step impedance resonator is:

$\frac{Z_A}{Z_B}=\frac{\cot {\mathrm{\θ}}_B}{\tan {\mathrm{\θ}}_A}---\left(2\right)$

The step impedance resonator be made up of two transmission lines can produce two controlled transmission zeros when resonance, therefore, described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator can produce six transmission zeros altogether, the frequency of transmission zero can by formula (1), (2) are tried to achieve above, that is, the position of two transmission zeros all can by the impedance (Z of step impedance resonator _a, Z _b) and electrical length (θ _a, θ _b) control completely.

Wider that transmission lines of described first Stepped Impedance resonance is connected with one end of the first input/output port I/O and the first transmission line respectively.

Narrower that transmission lines of described second step impedance resonance is connected with the other end of the first transmission line and one end of the second transmission line respectively.

Narrower that transmission lines of described 3rd Stepped Impedance resonance is connected with the other end of the second transmission line and the second input/output port I/O respectively.

Compared with prior art, tool has the following advantages and beneficial effect the utility model:

1, the band stop filter of technology generally only can realize broadband belt resistance now, or realizes Double-frequency band elimination, is but difficult to realize broadband and double frequency simultaneously, and the filter construction that the utility model proposes, double-frequency broadband band resistance response can be realized easily;

2, the filter construction that the utility model proposes is simple, is convenient to design and layout, by adjusting impedance ratio and the length of step impedance resonator, can control frequency ratio and the bandwidth ratio of two stopbands well;

3, the double-frequency broadband band stop filter that the utility model proposes, two stopbands have excellent skirt selectivity, greatly can improve filter effect;

4, the double-frequency broadband band stop filter that the utility model proposes can be used for, in the multifrequency communication system of many standards, effectively reducing communication system volume and reducing costs.

Accompanying drawing explanation

Fig. 1 is the structural representation of double-frequency broadband band stop filter described in the utility model.

Fig. 2 is the schematic diagram of a step impedance resonator.

Fig. 3 is the simulation result figure of double-frequency broadband band stop filter described in the utility model.

Embodiment

Below in conjunction with specific embodiment, the utility model is described in further detail.

As shown in Figure 1, the double-frequency broadband band stop filter based on many step impedance resonator loading structure described in the present embodiment, include the first step impedance resonator, second step impedance resonator, 3rd step impedance resonator, first transmission line 7, second transmission line 8, first input/output port I/O9, second input/output port I/O10, wherein, one end of described first transmission line 7 is connected with the first input/output port I/O9, its other end is connected with one end of the second transmission line 8, the other end of described second transmission line 8 is connected with the second input/output port I/O10, signal is from one of them input/output port I/O feed-in, export from another input/output port I/O.Described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator interval are side by side, described first step impedance resonator is connected with one end of the first input/output port I/O9 and the first transmission line 7 respectively, described second step impedance resonator is connected with the other end of the first transmission line 7 and one end of the second transmission line 8 respectively, and described 3rd step impedance resonator is connected with the other end of the second transmission line 8 and the second input/output port I/O10 respectively.

Two transmission lines 1,4 that described first step impedance resonator is differed by width are connected in series and form, and wherein, transmission line 1 is narrower, and transmission line 4 is wider, and this transmission line 4 is connected with one end of the first input/output port I/O9 and the first transmission line 7 respectively.

Two transmission lines 2,5 that described second step impedance resonator is differed by width are connected in series and form, and wherein, transmission line 2 is wider, and transmission line 5 is narrower, and this transmission line 5 is connected with the other end of the first transmission line 7 and one end of the second transmission line 8 respectively.

Two transmission lines 3,6 that described 3rd step impedance resonator is differed by width are connected in series and form, and wherein, transmission line 3 is wider, and transmission line 6 is narrower, and this transmission line 6 is connected with the other end of the second transmission line 8 and the second input/output port I/O10 respectively.

In the present embodiment, all transmission lines can use the common technology such as microstrip line, strip line to realize in industrial practical application.

As shown in Figure 2, the input impedance Z of described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator _incan by formulae discovery below out:

$Z_{\mathrm{in}}=j{Z}_A\frac{Z_A\tan {\mathrm{\θ}}_A-Z_B\cot {\mathrm{\θ}}_B}{Z_A+Z_B\tan {\mathrm{\θ}}_A\cot {\mathrm{\θ}}_B}---\left(1\right)$

In formula, j is imaginary unit, Z _a, Z _bbe respectively the impedance of two transmission lines of step impedance resonator, θ _a, θ _bbe respectively the electrical length of two transmission lines of step impedance resonator;

By making Z _in=0 condition of resonance can trying to achieve step impedance resonator is:

$\frac{Z_A}{Z_B}=\frac{\cot {\mathrm{\θ}}_B}{\tan {\mathrm{\θ}}_A}---\left(2\right)$

The step impedance resonator be made up of two transmission lines can produce two controlled transmission zeros when resonance, therefore, described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator can produce six transmission zeros altogether, the frequency of transmission zero can by formula (1), (2) are tried to achieve above, that is, the position of two transmission zeros all can by the impedance (Z of step impedance resonator _a, Z _b) and electrical length (θ _a, θ _b) control completely.The position at these six zero points is set according to index demand, then can realizes the double-frequency broadband band stop filter of excellent performance.

In the present embodiment, given first stopband three dB bandwidth is 450MHz ~ 1941MHz (1491MHz, 124%), and the second stopband three dB bandwidth is 2095MHz ~ 3550MHz (1255MHz, 51.6%).By formula (1), (2) and software emulation fine setting, optimized the Distribution of Zeros can be obtained.After optimizing, the design parameter of Fig. 1 median filter is: Z ₁=23 Ω, θ ₁=90 °, Z ₂=450.8 Ω, θ ₂=90 °, Z ₃=151.2 Ω, θ ₃=90 °, Z ₄=27 Ω, θ ₄=90 °, Z ₅=62 Ω, θ ₅=90 °, Z ₆=31 Ω, θ ₆=90 °, Z ₇=163 Ω, θ ₇=90 °.

Use the simulation result of circuit simulating software AWR-Microwave Office as shown in Figure 3.Wherein, transverse axis represents the signal frequency of double-frequency broadband band stop filter of the present utility model, and the longitudinal axis represents amplitude, comprises insertion loss (S ₂₁) amplitude and return loss (S ₁₁) amplitude.S ₂₁represent that its corresponding mathematical function is: power output/input power (dB)=20 × log|S by the relation between the input power of the signal of double-frequency broadband band stop filter of the present utility model and the power output of signal ₂₁|.In the signals transmission of double-frequency broadband band stop filter of the present utility model, the Partial Power of signal is reflected back toward signal source, is become reflection power by the power reflected.S ₁₁represent that its corresponding mathematical function is as follows: reflection power/incident power=20 × log|S by the relation between the input power of the signal of double-frequency broadband band stop filter of the present utility model and the reflection power of signal ₁₁|.

The utility model comprises and is not limited in the above-mentioned embodiment provided; those skilled in the art are under design of the present utility model; under the prerequisite not departing from the utility model principle; different distortion and replacement can be made, such as use different technique to realize the utility model proposes filter construction (as microstrip line, strip line; the line of rabbet joint etc.); change the value of design parameter, increase the exponent number etc. of filter, these distortion and replacement also belong to this patent protection range.

Claims (5)

1. based on the double-frequency broadband band stop filter of many step impedance resonator loading structure, it is characterized in that: include the first step impedance resonator, second step impedance resonator, 3rd step impedance resonator, first transmission line (7), second transmission line (8), first input/output port I/O (9), second input/output port I/O (10), wherein, one end of described first transmission line (7) is connected with the first input/output port I/O (9), its other end is connected with the one end of the second transmission line (8), the other end of described second transmission line (8) is connected with the second input/output port I/O (10), signal is from one of them input/output port I/O feed-in, export from another input/output port I/O, described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator interval are side by side, described first step impedance resonator is connected with one end of the first input/output port I/O (9) and the first transmission line (7) respectively, described second step impedance resonator is connected with the other end of the first transmission line (7) and one end of the second transmission line (8) respectively, and described 3rd step impedance resonator is connected with the other end of the second transmission line (8) and the second input/output port I/O (10) respectively, the transmission line serial connection that described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator differ by two articles of width forms.

2. the double-frequency broadband band stop filter based on many step impedance resonator loading structure according to claim 1, is characterized in that: the input impedance Z of described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator _inby formulae discovery below out:

$Z_{\mathrm{in}}={\mathrm{jZ}}_A\frac{Z_A\tan {\mathrm{\θ}}_A-Z_B\cot {\mathrm{\θ}}_B}{Z_A+Z_B\tan {\mathrm{\θ}}_A\cot {\mathrm{\θ}}_B}---\left(1\right)$

In formula, j is imaginary unit, Z _a, Z _bbe respectively the impedance of two transmission lines of step impedance resonator, θ _a, θ _bbe respectively the electrical length of two transmission lines of step impedance resonator;

By making Z _in=0 condition of resonance can trying to achieve step impedance resonator is:

$\frac{Z_A}{Z_B}=\frac{\cot {\mathrm{\θ}}_B}{\tan {\mathrm{\θ}}_A}---\left(2\right)$

The step impedance resonator be made up of two transmission lines can produce two controlled transmission zeros when resonance, therefore, described first step impedance resonator, the second step impedance resonator, the 3rd step impedance resonator can produce six transmission zeros altogether, the frequency of transmission zero can by formula (1), (2) are tried to achieve above, that is, the position of two transmission zeros all can by the impedance (Z of step impedance resonator _a, Z _b) and electrical length (θ _a, θ _b) control completely.

3. the double-frequency broadband band stop filter based on many step impedance resonator loading structure according to claim 1, is characterized in that: wider that transmission lines of described first Stepped Impedance resonance is connected with one end of the first input/output port I/O (9) and the first transmission line (7) respectively.

4. the double-frequency broadband band stop filter based on many step impedance resonator loading structure according to claim 1, is characterized in that: narrower that transmission lines of described second step impedance resonance is connected with the other end of the first transmission line (7) and one end of the second transmission line (8) respectively.

5. the double-frequency broadband band stop filter based on many step impedance resonator loading structure according to claim 1, is characterized in that: narrower that transmission lines of described 3rd Stepped Impedance resonance is connected with the other end of the second transmission line (8) and the second input/output port I/O (10) respectively.