KR101258034B1 - Microstrip dual-band bandpass filter using stepped impedance resonator - Google Patents

Abstract

PURPOSE: A microstrip dual band bandpass filter using a stepped impedance resonator is provided to prevent resonators from being combined by differently setting a resonant frequency and a harmonic frequency. CONSTITUTION: A first feed line(110) has a stepped impedance resonator structure. One end of the first feed line is opened. One end of a second feed line(120) which is opposite to the first feed line is opened. First and second resonators(130) form a first pass band. Third and fourth resonators(140) form a second pass band.

Description

MICROSTRIP DUAL-BAND BANDPASS FILTER USING STEPPED IMPEDANCE RESONATOR}

The present invention relates to a microstrip dual band bandpass filter for passing two specific frequency band signals.

Mobile communication terminals such as mobile phones and smart phones, which are widely used at present, are provided with a communication module in which various electronic devices are integrated on a substrate.

The communication module is composed of a duplexer stage, an RF transceiver stage, an intermediate frequency processor stage, a baseband processor stage, and the like, and each component stage removes signals of unwanted components such as harmonics and reflected waves, or separates transmission / reception signals or amplifiers. Or a filter is inserted to match the input and output impedance of a circuit such as a mixer.

In addition, according to the trend of miniaturization of mobile communication terminal products, a method of reducing the number of components and the mounting area has been widely used.

Accordingly, a bandpass filter using a stepped impedance resonator (SIR) that functions as a plurality of resonators in a single structure has been proposed. SIR functions as a bandpass filter by generating resonance at a specific frequency using a difference in impedance according to a difference in stripline width.

In order to form a dual band in recent years, the center frequency of each pass band must be adjusted while the bandwidth must be independently adjustable. Starting with a structure that only adjusts the center frequency, dual-band bandpass filters that can adjust the bandwidth of each passband have been studied.However, as the signals of each passband pass through a common input and output path simultaneously, the design procedure becomes complicated. There are limitations in bandwidth control, and filter structures are being studied to overcome these shortcomings.

In a conventional filter where two pairs of uniform line width open ring resonators are formed between two uniform feed lines corresponding to a common input and output, the resonator is coupled to the maximum magnetic field using a uniform feed line. Because of this, the feed line length must be an integer multiple of half the wavelength at the center frequency of each pass band.

Therefore, in the case of the dual band bandpass filter, the length must be the minimum common multiple of the half wavelength length at the two passband center frequencies, so that the length is unnecessarily increased to increase the filter size.

On the other hand, when a half-wave resonator having a uniform line width is used for the first passband resonator, its harmonic content may occur at a frequency between the first passband and the second passband, which is a stopband, and thus, the stopband characteristic is deteriorated. Occurs.

Therefore, in order to solve this problem, the present invention forms a half wavelength at the first passband center frequency through the feed line of the SIR structure and the second passband using the feed line of the SIR structure and the open ring resonator of the SIR structure. At the center frequency, a microstrip dual band bandpass filter using a stepped impedance resonator is proposed to reduce the length of the filter by minimizing unnecessary length increase by forming one wavelength.

In addition, the present invention is to provide a microstrip dual band bandpass filter using SIR to improve the stopband characteristics by moving the harmonic components of the first passband resonator to a frequency other than the filter band through the open ring resonator of the SIR structure do.

According to one aspect of the invention, in a microstrip dual band bandpass filter using SIR, a first feed line at which a predetermined end of the SIR structure is opened, and a predetermined end opposite to the first feed line is opened, First and second resonators, which are positioned at a predetermined distance from the first feed line and are positioned to face each other at a predetermined interval between the first and second feed lines to form a first pass band. And third and fourth resonators having a uniform line width positioned opposite to each other at a predetermined interval between the first and second feed lines to form a second pass band.

The microstrip dual band pass filter using the stepped impedance resonator according to the present invention is applied to the feed line and the first pass band resonator by applying the SIR structure to the first pass band center frequency through the feed line of the SIR structure. By minimizing the size of the filter by forming one wavelength at the passband center frequency, the maximum magnetic field points were coincided at each passband center frequency, and between the first passband and the second passband by a first passband resonator having an SIR structure. The first harmonic component generated by the NSA is shifted to a frequency outside the use band of the microstrip dual band bandpass filter, thereby improving the stopband characteristics.

In addition, by minimizing the coupling between the resonators by varying the resonant frequency and harmonic components of each passband resonator, the effect of the distance of each passband resonance period on the microstrip double band bandpass filter characteristics is minimized.

1 is a view showing the structure of a microstrip dual band bandpass filter using a stepped impedance resonator according to an embodiment of the present invention.
2 is a diagram illustrating an SIR structure applied to first and second feed lines and a pair of first and second resonators in a microstrip dual band bandpass filter using a stepped impedance resonator according to an exemplary embodiment of the present invention. .
3A is a diagram illustrating a current distribution of a line at a center frequency of a first pass band of the first feed line and the second feed line using an SIR structure.
3B is a diagram illustrating a current distribution of a line at a center frequency of a second pass band of the first feed line and the second feed line to which the SIR structure is applied.
4 illustrates a first passband response by a feed line of an SIR structure and a pair of open ring resonators of an SIR structure according to an embodiment of the present invention.
FIG. 5 illustrates a second passband response by a feed line of an SIR structure and a pair of uniformly wide open ring resonators in accordance with one embodiment of the present invention. FIG.
6 is a diagram showing simulation and measurement results for the SIR structure of the microstrip dual band bandpass filter to which the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be appreciated that those skilled in the art will readily observe that certain changes in form and detail may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. To those of ordinary skill in the art.

The present invention relates to a microstrip dual band bandpass filter for passing two specific frequency band signals. More particularly, the present invention applies an SIR structure to a feed line that is used as a common input and output. It combines the feed line and the resonator with the maximum magnetic field to facilitate signal transmission, and it is possible to miniaturize parts by independently changing the center frequency and bandwidth of the two pass bands without separate impedance converters, thereby reducing the number of parts of communication equipment. To provide a technology that facilitates component placement.

In addition, the present invention provides a technique for improving the stopband characteristics between the first passband and the second passband by applying the SIR structure to the first passband resonator to move the first harmonic component to a frequency outside the filter use band. I would like to.

Hereinafter, a microstrip dual band bandpass filter using a stepped impedance resonator according to an embodiment of the present invention will be described in detail with reference to FIG. 1.

1 is a view showing the structure of a microstrip dual band bandpass filter using a stepped impedance resonator according to an embodiment of the present invention.

Referring to FIG. 1, the microstrip dual band bandpass filter to which the present invention is applied includes a pair of first and second resonators 130 and a first feed line 110 and a second feed line 120 having an SIR structure. And a pair of third and fourth resonators 140 having a uniform width.

One end of the first feed line 110 is opened, and the other end of the second feed line 120 is opened at a predetermined distance from the first feed line 110.

The pair of first and second resonators 130 are disposed to face each other at a predetermined interval between the first feed line 110 and the second feed line 120 to form a first pass band.

The pair of third and fourth resonators 140 may be disposed to face each other with a predetermined gap between the first feed line 110 and the second feed line 120 to form the second pass band. Form a uniform track width.

In this case, the first and second resonators 130 and the third and fourth resonators 140 are positioned at the maximum magnetic field points 150 and 160 at each passband center frequency.

2 illustrates an SIR structure applied to the first and second feed lines 110 and 120 and the pair of first and second resonators 130.

Referring to FIG. 2, the pair of first and second resonators 130 are open ring resonators composed of lines having different impedances Z1 and Z2 and electrical lengths ₁ and ₂ having an SIR structure. The harmonic components can be adjusted to the desired frequency by adjusting the characteristic impedances (Z1, Z2) and the electrical lengths ( ₁ , ₂ ).

Accordingly, by applying an SIR structure to the first feed line 110 and the second feed line 120, the first harmonic component formed by the first and second feed lines is adjusted to be equal to the second passband center frequency. do.

In this case, by forming a half wavelength at the first passband center frequency and one wavelength at the second passband center frequency, the maximum magnetic fields of the first feed line 110 and the second feed line 120 at the center frequency of each pass band. The points are matched to minimize the length of the microstrip dual band bandpass filter.

Here, the first and second resonators 130 forming the first pass band are positioned at the maximum magnetic field point 150 at the center frequency of the first pass band, and the third and fourth resonators 140 forming the second pass band. ) Is located at the maximum magnetic field point 160 at the center frequency of the second pass band to facilitate signal transmission.

In addition, the stopband characteristics between the two pass bands by moving the first harmonic component formed by the first and second resonators 130 to a frequency outside the use frequency band of the microstrip dual band bandpass filter rather than between the two pass bands. It can improve deterioration.

Since signals of each band are transmitted through different resonators, the center frequency and the bandwidth of each pass band of the first and second resonators 130 and the third and fourth resonators 140 may be independently changed.

In this way, the SIR structure can adjust the harmonic components to an arbitrary frequency, and the SIR structure is applied to the first and second resonators 130 of the first pass band of the first feed line 110 and the second feed line 120. It was applied and manufactured to see whether the present invention can be applied to the substrate, and the substrate used Rogers RT / Duroid 6010 LM (substrate dielectric constant = 10.2, substrate height = 1.27mm).

3A shows a current distribution of a line at a center frequency (2.45 GHz) of a first pass band of the first feed line 110 and the second feed line 120 to which the SIR structure is applied.

3B illustrates a current distribution of a line at a center frequency (5.8 GHz) of a second pass band of the first feed line 110 and the second feed line 120 to which the SIR structure is applied.

In general, since the magnetic field is also maximized at the point where the current distribution is maximized, the first and second feed lines 110 may be adjusted by adjusting characteristic impedances Z1 and Z2 and electrical lengths ₁ and ₂ of each line in the SIR structure. 120) to make the first harmonic component equal to the center frequency of the second pass band to form a half wavelength at the first pass band center frequency and one wavelength at the second pass band center frequency, thereby minimizing unnecessary length. It can be seen that the maximum magnetic field points of the first feed line 110 and the second feed line 120 can coincide at the center frequency of the pass band.

Accordingly, as shown in FIG. 1, signal transmission can be easily formed in a feed line having a relatively short length by placing each pass band resonator at magnetic field maximum points 150 and 160 at each pass band center frequency.

4 illustrates a response of a feed line of an SIR structure and a pair of open ring resonators of an SIR structure according to an embodiment of the present invention, in which a first passband is formed by the SIR resonator, and thus first harmonics. It can be seen that the stopband characteristics are improved by moving the component to 7 GHz.

FIG. 5 illustrates a response of a feed line having a SIR structure and a pair of uniform width open ring resonators according to an embodiment of the present invention, and it can be seen that a second pass band is formed by the open ring resonator. .

FIG. 6 is a diagram illustrating simulation and measurement results of the SIR structure of the microstrip dual band bandpass filter to which the present invention is applied.

The microstrip dual band bandpass filter according to the present invention has a bandwidth of 336 MHz and 328 MHz at 2.45 GHz and 5.8 GHz, respectively, and an insertion loss of -1.2 and -2.0 dB at 2.45 GHz and 5.8 GHz, respectively, as shown in FIG. It can be seen that a double band is formed, and the stop band is improved as the first harmonic component formed between the first pass band and the second pass band moves out of the microstrip double band band pass filter using band. It can be seen that the level is kept below 30 dB.

As described above, an operation related to a microstrip dual band bandpass filter using a stepped impedance resonator according to the present invention may be performed. Meanwhile, in the above description of the present invention, a specific embodiment has been described. It can be carried out without departing from the scope. Accordingly, the scope of the present invention should not be limited by the illustrated embodiments, but should be determined by equivalents of the claims and the claims.

110: first feed line 120: second feed line
130: first and second resonators 140: third and fourth resonators

Claims (3)

In a microstrip dual band bandpass filter using a stepped impedance resonator (SIR),
A first feed line having an open end at one end having an SIR structure,
One end opposite to the first feed line is opened and includes a second feed line positioned at a predetermined distance from the first feed line,
A first SIR structure that forms the first pass band by forming the maximum magnetic field point of the first pass band and the maximum magnetic field point of the second pass band within the half-wavelength of the first pass band center frequency and making the position different. And a microstrip dual band bandpass filter using a stepped impedance resonator that independently forms a dual band by securing a space in which the third and fourth resonators having a uniform line width forming the second resonator and the second pass band are formed. The method of claim 1,
The first and second resonators constituting the first passband filter have an SIR structure, and the third and fourth resonators constituting the second passband filter have an open ring resonator structure, and the first harmonic component of the first and second resonators is used as a filter. Positioning out of the band improves stopband characteristics and minimizes electromagnetic coupling between the first, second and third resonators by varying the resonant frequency and harmonic frequency of the resonators forming each pass band. A microstrip dual band bandpass filter using a stepped impedance resonator. The method of claim 1,
A step characterized in that each pass band resonator forms a dual band having a bandwidth of 336 MHz and 328 MHz and an insertion loss of -1.2 and -2.0 dB in the first pass band of 2.45 GHz and the second pass band of 5.8 GHz, respectively. Microstrip dual band bandpass filter using type impedance resonator.

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