CN203747009U - Filtering power divider with double passbands - Google Patents

Abstract

The utility model discloses a filtering power divider with double passbands. An upper layer of microstrip structure includes a stepped impedance resonator and four coupling feeder lines, wherein the stepped impedance resonator is realized by two 1/4 wavelength microstrip lines. Through the stepped impedance resonator and a new coupling feed mode, the equal power distribution of the filtering power divider can be perfectly realized; and the double bandpass filtering characteristic with a wide stopband is realized. At the same time, an edge of each passband is provided wtih two transmission zeros, so as to improve frequency selectivity. According to the filtering power divider with the double passbands, the filter and the power divider, which are two important elements at the front end of radio frequency, are integrated together, so that the size is reduced and the integration is facilitated; the total insertion loss is reduced, and the wide range of application is realized; and the filtering power divider with the double passbands is novel, creative and practical.

Description

There is the filtering power splitter of bilateral band

Technical field

The utility model relates to a kind of filtering power splitter with bilateral band, can be applicable to the decile power divider of radio-frequency (RF) front-end circuit band-pass filtering function, in the circuit of a lot of required power deciles and bandpass filtering, all needs this technology.

Background technology

Filter and power splitter are two kinds of very important parts in wireless communication system, and in radio-frequency front-end, these two kinds of devices work in identical frequency mostly, and require to offer the desirable characteristic of signal.If these two kinds of devices are integrated in a device, cumulative volume and insertion loss can together reduce.

In recent years, some scholars are absorbed in integrated multiple functional circuits in a circuit.Integrated for power splitter and band pass filter, is that the input port of Wilkinson power divider coupling feed line is replaced mostly, although obtain so very high isolation, but this needs to sacrifice the also very large volume of needs of frequency selectivity.

Consider that reducing volume is convenient to integrated and demand frequency selective characteristic, the utility model proposes a kind of novel filtering power splitter with bilateral band.This utility model is used Stepped Impedance resonator and the coupling feed line that quarter-wave microstrip line is realized that band pass filter and power divider are integrated together, obtain two pass-band performances by Stepped Impedance resonator, bandwidth can be controlled arbitrarily, simultaneously, can create two transmission zeros in each passband edge, improve frequency selectivity.

Utility model content

In the utility model, a kind of novel filtering power splitter with bilateral band is proposed.In the design, each upper strata microstrip structure with the power division filter of bilateral band comprises Stepped Impedance resonator and four the coupling feed lines that two quarter-wave microstrip lines are realized.The Stepped Impedance resonator that each quarter-wave microstrip line is realized is to be obtained by two sections high low-impedance line cascades.Regulate the total length of the Stepped Impedance resonator of quarter-wave microstrip line realization, can change the centre frequency of lower passband.Regulate the characteristic impedance of low-impedance line, can change the centre frequency of upper passband.Regulate the Stepped Impedance resonator of quarter-wave microstrip line realization and the coupling space being coupled between feed line, can change bandwidth.Than directly, by the device of filter and power splitter cascade, this structure can realize volume miniaturization, and its bandwidth can be controlled arbitrarily, and insertion loss also can obviously reduce.Meanwhile, can create two transmission zeros in each passband edge, improve frequency selectivity.

For realizing the utility model object, the technical scheme that the utility model adopts is as follows:

The filtering power splitter with bilateral band, comprises upper strata microstrip structure, isolated component, and interlayer substrate and lower floor's grounding plate: upper strata microstrip structure is attached to interlayer upper surface of base plate, interlayer base lower surface is lower floor's grounding plate; Upper strata microstrip structure comprises Stepped Impedance resonator and four the coupling feed lines that two quarter-wave microstrip lines are realized; Wherein two coupling feed lines share input port as the input port of filtering power splitter with bilateral band, and the mid portion of two other coupling feed line is connected to respectively two output ports as the first output port and second output port of filtering power splitter with bilateral band; Isolated component is resistance R, isolation resistance R and be connected two coupling feed lines of input port between; Upper strata microstrip structure is symmetrical up and down.

The above-mentioned filtering power splitter with bilateral band, the Stepped Impedance resonator that quarter-wave microstrip line is realized is the transmission line being connected to form in turn by the first microstrip line, the second microstrip line, the 3rd microstrip line, the 4th microstrip line, the 5th microstrip line, wherein the first microstrip line, the second microstrip line and the 3rd microstrip line form a n shape, the 3rd microstrip line and the 4th microstrip line form a L shaped shape, the 4th microstrip line is received a jiao of the 5th microstrip line, the end ground connection of the 5th microstrip line; The first coupling feed line is the one section of transmission line being connected to form in turn by the 6th microstrip line, the 7th microstrip line, the 8th microstrip line, the 9th microstrip line, the tenth microstrip line, the 11 microstrip line; The second coupling feed line is the one section of transmission line being connected to form in turn by the 12 microstrip line, the 13 microstrip line, the 14 microstrip line, the 15 microstrip line; Wherein one end of the 12 microstrip line of the second coupling feed line is connected with input port, between the end of the 15 microstrip line, access an isolation resistance R, the mid portion of the 11 microstrip line of two first coupling feed lines is connected with the first output port, the second output port respectively, forms the filtering power splitter with bilateral band of three ports.

The above-mentioned filtering power splitter with bilateral band, the Stepped Impedance resonator that quarter-wave microstrip line is realized has produced two pass-band performances, article two, the high low-impedance line that electrical length equates, the high impedance line being made up of the first microstrip line, the second microstrip line, the 3rd microstrip line, the 4th microstrip line and the low-impedance line cascade being made up of the 5th microstrip line obtain two pass-band performances; The ratio of the characteristic impedance of two sections of high low-impedance lines has determined the ratio of bilateral mid-band frequency, and the length of the Stepped Impedance resonator that whole piece quarter-wave microstrip line is realized has determined the centre frequency of lower passband; / 4th of a resonance frequency f corresponding wavelength λ that the length L of the Stepped Impedance resonator that above-mentioned quarter-wave microstrip line is realized is lower passband, wherein, L is actual microstrip line length; Isolation resistance R can realize the mutual isolation between two output ports, can use the lumped resistance of about 100-200 ohm.

The above-mentioned filtering power splitter with bilateral band, the side profile that the first coupling feed line is adjacent with the Stepped Impedance resonator of quarter-wave microstrip line realization is parallel, the first microstrip line parallels with the 6th microstrip line, the second microstrip line parallels with the 7th microstrip line, the 3rd microstrip line parallels with the 8th microstrip line, the 4th microstrip line parallels with the 9th microstrip line, and the narrow limit of the 5th microstrip line parallels with the tenth microstrip line, and the broadside of the 5th microstrip line parallels with the 11 microstrip line; The side profile that the second coupling feed line is adjacent with the Stepped Impedance resonator of quarter-wave microstrip line realization is parallel, the first microstrip line parallels with the 12 microstrip line, the second microstrip line parallels with the 13 microstrip line, the 3rd microstrip line parallels with the 14 microstrip line, and the 4th microstrip line, the 5th microstrip line parallel with the 15 microstrip line; And the stiffness of coupling that regulates the Stepped Impedance resonator of above-mentioned quarter-wave microstrip line realization and be coupled between feed line is that the spacing by changing the part that is parallel to each other between the two realizes, and regulates described spacing can obtain desirable bandwidth; Spacing range between the Stepped Impedance resonator that the quarter-wave microstrip line of the above-mentioned filtering power splitter with bilateral band is realized and coupling feed line is between 0.1mm-1mm.

With respect to prior art, the utlity model has following advantage:

(1) application Stepped Impedance resonator and novel coupling feed way, has the realization that the power decile of the filtering power splitter of bilateral band can be desirable, and has the bilateral band filtering characteristic of wide stopband, Out-of-band rejection ideal.

(2) than directly by the device of filter and power splitter cascade, this structure can realize the miniaturization of volume, is convenient to integratedly, and bandwidth can be controlled arbitrarily, insertion loss also can obviously reduce.Meanwhile, can create two transmission zeros in each passband edge, improve frequency selectivity.

Brief description of the drawings

Fig. 1 a and Fig. 1 b are the structure charts with the filtering power splitter of bilateral band;

Fig. 2 is the structure chart with the Stepped Impedance resonator of the quarter-wave microstrip line realization of the filtering power splitter of bilateral band;

Fig. 3 is the first coupling feed line of filtering power splitter and the structure chart of the second coupling feed line with bilateral band;

Fig. 4 a is the transfer curve figure that the filtering power splitter with bilateral band has the filtering power splitter of bilateral band;

Fig. 4 b is output return loss and the isolating coefficient curve chart that the filtering power splitter with bilateral band has the filtering power splitter of bilateral band.

Embodiment

Below in conjunction with accompanying drawing, the utility model is described in further detail, but the claimed scope of the utility model is not limited to the scope of lower example statement.

The filtering power splitter with bilateral band, comprises upper strata microstrip structure, isolated component, and interlayer substrate and lower floor's grounding plate: upper strata microstrip structure is attached to interlayer upper surface of base plate, interlayer base lower surface is lower floor's grounding plate; Upper strata microstrip structure comprises Stepped Impedance resonator and four the coupling feed lines that two quarter-wave microstrip lines are realized; Wherein two coupling feed lines share input port as the input port of filtering power splitter with bilateral band, and the mid portion of two other coupling feed line is connected to respectively two output ports as the first output port and second output port of filtering power splitter with bilateral band; Isolated component is resistance R, isolation resistance R and be connected two coupling feed lines of input port between; Upper strata microstrip structure is symmetrical up and down.

The above-mentioned filtering power splitter with bilateral band, the Stepped Impedance resonator that quarter-wave microstrip line is realized is the transmission line being connected to form in turn by the first microstrip line, the second microstrip line, the 3rd microstrip line, the 4th microstrip line, the 5th microstrip line, wherein the first microstrip line, the second microstrip line and the 3rd microstrip line form a n shape, the 3rd microstrip line and the 4th microstrip line form a L shaped shape, the 4th microstrip line is received a jiao of the 5th microstrip line, the end ground connection of the 5th microstrip line; The first coupling feed line is the one section of transmission line being connected to form in turn by the 6th microstrip line, the 7th microstrip line, the 8th microstrip line, the 9th microstrip line, the tenth microstrip line, the 11 microstrip line; The second coupling feed line is the one section of transmission line being connected to form in turn by the 12 microstrip line, the 13 microstrip line, the 14 microstrip line, the 15 microstrip line; Wherein one end of the 12 microstrip line of the second coupling feed line is connected with input port, between the end of the 15 microstrip line, access an isolation resistance R, the mid portion of the 11 microstrip line of two first coupling feed lines is connected with the first output port, the second output port respectively, forms the filtering power splitter with bilateral band of three ports.

The above-mentioned filtering power splitter with bilateral band, the Stepped Impedance resonator that quarter-wave microstrip line is realized has produced two pass-band performances, article two, the high low-impedance line that electrical length equates, the high impedance line being made up of the first microstrip line, the second microstrip line, the 3rd microstrip line, the 4th microstrip line and the low-impedance line cascade being made up of the 5th microstrip line obtain two pass-band performances; The ratio of the characteristic impedance of two sections of high low-impedance lines has determined the ratio of bilateral mid-band frequency, and the length of the Stepped Impedance resonator that whole piece quarter-wave microstrip line is realized has determined the centre frequency of lower passband; / 4th of a resonance frequency f corresponding wavelength λ that the length L of the Stepped Impedance resonator that above-mentioned quarter-wave microstrip line is realized is lower passband, wherein, L is actual microstrip line length; Isolation resistance R can realize the mutual isolation between two output ports, can use the lumped resistance of about 100-200 ohm.

The above-mentioned filtering power splitter with bilateral band, the side profile that the first coupling feed line is adjacent with the Stepped Impedance resonator of quarter-wave microstrip line realization is parallel, the first microstrip line parallels with the 6th microstrip line, the second microstrip line parallels with the 7th microstrip line, the 3rd microstrip line parallels with the 8th microstrip line, the 4th microstrip line parallels with the 9th microstrip line, and the narrow limit of the 5th microstrip line parallels with the tenth microstrip line, and the broadside of the 5th microstrip line parallels with the 11 microstrip line; The side profile that the second coupling feed line is adjacent with the Stepped Impedance resonator of quarter-wave microstrip line realization is parallel, the first microstrip line parallels with the 12 microstrip line, the second microstrip line parallels with the 13 microstrip line, the 3rd microstrip line parallels with the 14 microstrip line, and the 4th microstrip line, the 5th microstrip line parallel with the 15 microstrip line; And the stiffness of coupling that regulates the Stepped Impedance resonator of above-mentioned quarter-wave microstrip line realization and be coupled between feed line is that the spacing by changing the part that is parallel to each other between the two realizes, and regulates described spacing can obtain desirable bandwidth; Spacing range between the Stepped Impedance resonator that the quarter-wave microstrip line of the above-mentioned filtering power splitter with bilateral band is realized and coupling feed line is between 0.1mm-1mm.

As shown in Fig. 1 a and Fig. 1 b, total line length of Stepped Impedance resonator that quarter-wave microstrip line is realized and the adjusting of the characteristic impedance ratio of high low-impedance line are to realize two pass-band performances of different center frequency, and feed stiffness of coupling can be realized the bandwidth of any control.Than the cascade of general band pass filter and power splitter, this structure can realize miniaturization, and its bandwidth can be controlled arbitrarily, meanwhile, can create two transmission zeros in passband edge, improves frequency selectivity.Exactly because the coupling between the Stepped Impedance resonator that quarter-wave microstrip line is realized and coupling feed line, so it can be used for replacing the cascade of conventional power distributor and filter, realize the performance of more optimizing, and only by the line length of Stepped Impedance resonator and the characteristic impedance of the high low-impedance line ratio that regulate quarter-wave microstrip line to realize, can realize the bilateral band of optional frequency.

As shown in Figure 2, have bilateral band filtering power splitter quarter-wave microstrip line realize Stepped Impedance resonator be laterally zygomorphic; The Stepped Impedance resonator of every quarter-wave microstrip line realization is formed by two sections high low-impedance line cascades, produces two pass-band performances.

As shown in Figure 3, the first coupling feed line in the filtering power splitter with bilateral band and the second coupling feed line are respectively laterally zygomorphic; Between the Stepped Impedance resonator that quarter-wave microstrip line is realized and coupling feed line, stiffness of coupling is to regulate the Stepped Impedance resonator of quarter-wave microstrip line realization and the spacing change that is coupled between feed line by adjustings.

Have bilateral band filtering power splitter embodiment structure as shown in Figure 1a, the thickness of medium substrate is 0.81mm, relative dielectric constant is 3.38, the microstrip line length L of the Stepped Impedance resonator that quarter-wave microstrip line is realized is 25.7mm, isolation resistance R is 180 ohm, and the Stepped Impedance resonator that quarter-wave microstrip line is realized is 0.2mm with the spacing of coupling feed line.

Fig. 4 a is according to simulation result and the measurement result of the transmission characteristic of an embodiment shown in above-mentioned Fig. 1 a.Transverse axis in transfer curve figure represents frequency, and the longitudinal axis represents the amplitude of transmission characteristic, and unit is dB(decibel), wherein S ₁₁represent the return loss of the filtering power splitter with bilateral band, S ₂₁while representing input port coupling, the insertion loss from the first output port to input port, S ₃₁while representing input port coupling, the insertion loss from the second output port to input port.From simulation result and test result, the centre frequency of passband is at 2.4GHz and 5.2GHz, and the insertion loss in bandwidth is respectively 4.4dB and 4.5dB, and input return loss is better than 15dB, bandwidth is respectively 10.9% and 11%, has produced two transmission zeros near each passband edge.

Fig. 4 b is the output port return loss of filtering power splitter and simulation result and the measurement result of isolation according to shown in above-mentioned Fig. 1 a with bilateral band.Transverse axis in isolation curve chart represents frequency, and the longitudinal axis represents the amplitude of transmission characteristic, and unit is dB(decibel).Wherein S ₂₂and S ₃₃represent the return loss of filtering power splitter two output ports with bilateral band, S ₂₃represent the isolation of the filtering power splitter with bilateral band.From emulation and test result, the output port return loss of two passbands and isolation are all good than 15dB.

The foregoing is only preferred embodiments of the present utility model; not in order to limit the utility model; based on embodiment of the present utility model; those of ordinary skill in the art are not making under the prerequisite of creative work; any amendment of doing based on the utility model; be equal to replacement, improve other embodiment that obtain, all belong to the protection range of the utility model embodiment.

Claims (4)

1. there is the filtering power splitter of bilateral band, comprise upper strata microstrip structure, isolated component, interlayer substrate and lower floor's grounding plate: upper strata microstrip structure is attached to interlayer upper surface of base plate, interlayer base lower surface is lower floor's grounding plate; It is characterized in that: upper strata microstrip structure comprises Stepped Impedance resonator and four the coupling feed lines that two quarter-wave microstrip lines are realized; Wherein two coupling feed lines share input port as the input port (I/P) of filtering power splitter with bilateral band, and the mid portion of two other coupling feed line is connected to respectively two output ports as the first output port (O/P1) and second output port (O/P2) of filtering power splitter with bilateral band; Isolated component is resistance R, between two coupling feed lines that isolation resistance R is positioned at and input port (I/P) is connected; Upper strata microstrip structure is symmetrical up and down.

2. the filtering power splitter with bilateral band according to claim 1, it is characterized in that: the Stepped Impedance resonator that described quarter-wave microstrip line is realized is by the first microstrip line (1), the second microstrip line (2), the 3rd microstrip line (3), the 4th microstrip line (4), the transmission line that the 5th microstrip line (5) connects to form in turn, wherein the first microstrip line (1), the second microstrip line (2) and the 3rd microstrip line (3) form a n shape, the 3rd microstrip line (3) and the 4th microstrip line (4) form a L shaped shape, the 4th microstrip line (4) is received a jiao of the 5th microstrip line (5), the end ground connection of the 5th microstrip line (5), the first coupling feed line is the one section of transmission line being connected to form in turn by the 6th microstrip line (6), the 7th microstrip line (7), the 8th microstrip line (8), the 9th microstrip line (9), the tenth microstrip line (10), the 11 microstrip line (11), the second coupling feed line is the one section of transmission line being connected to form in turn by the 12 microstrip line (12), the 13 microstrip line (13), the 14 microstrip line (14), the 15 microstrip line (15), wherein one end of the 12 microstrip line (12) of the second coupling feed line is connected with input port (I/P), between the end of the 15 microstrip line (15), access an isolation resistance R, the mid portion of the 11 microstrip line (11) of two first coupling feed lines is connected with the first output port (O/P1), the second output port (O/P2) respectively, forms the filtering power splitter with bilateral band of three ports.

3. the filtering power splitter with bilateral band according to claim 1, it is characterized in that: the Stepped Impedance resonator that described quarter-wave microstrip line is realized has produced two pass-band performances, the high impedance line being made up of the first microstrip line (1), the second microstrip line (2), the 3rd microstrip line (3), the 4th microstrip line (4) and the low-impedance line cascade being made up of the 5th microstrip line (5) obtain two pass-band performances; / 4th of a resonance frequency f corresponding wavelength λ that the length L of the Stepped Impedance resonator that described quarter-wave microstrip line is realized is lower passband, wherein, L is actual microstrip line length.

4. the filtering power splitter with bilateral band according to claim 1, it is characterized in that: the side profile that described the first coupling feed line is adjacent with the Stepped Impedance resonator of quarter-wave microstrip line realization is parallel, the first microstrip line (1) parallels with the 6th microstrip line (6), the second microstrip line (2) parallels with the 7th microstrip line (7), the 3rd microstrip line (3) parallels with the 8th microstrip line (8), the 4th microstrip line (4) parallels with the 9th microstrip line (9), the narrow limit of the 5th microstrip line (5) parallels with the tenth microstrip line (10), the broadside of the 5th microstrip line (5) parallels with the 11 microstrip line (11), the side profile that described the second coupling feed line is adjacent with the Stepped Impedance resonator of quarter-wave microstrip line realization is parallel, the first microstrip line (1) parallels with the 12 microstrip line (12), the second microstrip line (2) parallels with the 13 microstrip line (13), the 3rd microstrip line (3) parallels with the 14 microstrip line (14), and the 4th microstrip line (4), the 5th microstrip line (5) parallel with the 15 microstrip line (15), spacing between the Stepped Impedance resonator that the quarter-wave microstrip line of the described filtering power splitter with bilateral band is realized and coupling feed line is 0.1mm-1mm.