KR100760295B1 - Microstcrip filter for ultra wideband application - Google Patents

Abstract

A micro strip filter for UWB(Ultra-WideBand) is provided to realize an UWB antenna having the expanded band width by forming two short-circuited stubs on a 50ohm micro strip path. A micro strip filter for UWB includes a substrate(11), a micro strip path(12), two short stubs(13), and two open stubs(14). The substrate(11) has a grounding surface at the rear surface, and consists of a dielectric having a feeding surface at both sides of the upper and lower parts The micro strip path(12) is S-shaped on the upper surface of the substrate(11), and consists of a 50ohm resistor. The short stubs(13) are horizontally formed on the S-shaped micro strip path(12), and have a via hole. The two open stubs(14) are formed on the S-shaped micro strip path on the same line, and has the length of (lambda/root of epsilon)/4, wherein the lambda is the central wavelength of a rejection band and the epsilon is permittivity of the substrate.

Description

Microstrip Filter for Ultra Wide Band Application

The present invention relates to a filter for an ultra-wideband (UWB) communication system, and more particularly to an ultra-wideband filter having a stop characteristic in the 5 GHz band.

Ultra-wideband systems are defined as systems that occupy more than 20% of the bandwidth of the center frequency or wireless transmission technology systems occupying more than 500Mhz. In February 2002, the Federal Communications Commission (FCC) approved the commercial use of UWB (3.1 GHz to 10.6 GHz), opening the door to general telecommunications. This technique copies a pulse-modulated signal into space without using a carrier wave. UWB can be applied to location awareness and radar technology in addition to the conventional wireless communication area.

UWB system is a technology that converts digital code information into an impulse signal having a very short width of less than 10 nanoseconds (10 ^-9 ) and transmits it wirelessly. The battery is expected to be used as a technology that can overcome the limitations of the existing wireless communication as it can use the battery tens of times longer than the conventional wireless communication method, and can also dramatically reduce the size of the transceiver. Since the signals of UWB systems can use a wide frequency band, the power density value in the frequency domain can be set to a very small value, so that even if it is superimposed on a frequency where other communication signals exist, it can give little interference. have. Initially, UWB communication signals have obtained wide frequency bands by using very short signal pulses, but now they use CDMA (Code Division Multiple Access) and OFDM (Orthogonal Frequency Division Multiplexing). There are several variants of UWB.

 UWB system has the advantages of being able to transmit and receive data using the frequency already used by other systems, high speed communication with very low power, and excellent obstacle transmission characteristics. Due to these advantages, the UWB system is expected to be widely applied to the next generation of wireless personal area networks such as wireless home networks.

UWB communication system is a high-speed wireless transmission technology using very wide bandwidth (3.1 GHz to 10.6 GHz), along with WPAN (Wireless Personnel Area Networks) for short-range high-speed data transmission in indoor wireless environments. As a core technology for implementing low speed and low power ubiquitous networks, many interests and active researches are underway.

In order to provide reliable service of the UWB communication system technology, research in the field of communication systems such as antennas, filters, and low noise amplifiers must be preceded. Since the UWB communication system uses a wider frequency band than the conventional communication system, it is essential to develop a small antenna having wideband characteristics.

 IEEE 802.11a, a standard for wireless local area networks (WLANs), allows WLANs to use the 5.15 GHz to 5.825 GHz bands, which are included in the frequency bands that UWB can use. The standard uses high power signals that can interfere with WLAN bands and UWB systems. Therefore, the use of a band overlapping with the WLAN in the UWB system is limited. Therefore, there is a problem in that a band reject filter having a high quality factor is additionally used in a frequency band overlapping with the WLAN band.

One aspect of the stopband filter is a lowpass filter. Such band-stop filters are used to remove unwanted frequencies and harmonics in mixers, oscillators, etc. and are generally implemented with parallel stubs or step impedances. However, such low pass filters are not only difficult to satisfy excellent cutoff characteristics and low cutoff frequencies, but also have difficulty in stopping in specific frequency bands such as WLAN.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an ultra-wide band filter that can be used in a UWB communication system.

It is also an object of the present invention to provide an ultra-wideband filter having band rejection characteristics in a WLAN band.

In addition, an object of the present invention is to provide an ultra-wide band filter that can be manufactured in a small size and mass production.

In order to achieve the above object, the microstrip filter according to the present invention includes a substrate formed of a dielectric having a ground plane formed on its rear surface and a feed surface formed on both upper and lower sides thereof; A microstrip line formed in an S shape on the upper surface of the substrate and composed of a 50Ω resistor; Two short stubs formed in the S-shaped microstrip line in the transverse direction and having via holes formed therein; And two in the same direction on the S-shaped microstrip line, the length of which is an open stub, where λ is the center wavelength of the stop band and ε is the dielectric constant of the substrate.

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Preferably, the via hole has a diameter of 0.3 mm.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

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1 is a top view, side view, and back view of an ultra-wideband filter with band rejection according to one embodiment of the invention.

The filter according to the present embodiment is a microstrip feed ultra-wideband filter, and includes a short circuit stub 13 connected to a substrate 11, a 50 Ω microstrip line 12 formed on an upper surface of the substrate, and a 50 Ω microstrip line 12. And a ground plane 16 formed on the bottom surface of the substrate and feeders 17 and 17 'formed on the top and bottom surfaces of the substrate. In addition, an open stub 14 may be formed in the microstrip line 12.

The microstrip line 12 has an S-shape as shown in the figure, and both ends of both lines are connected to a feeder.

In the present invention, a short circuit stub 13 is formed in the 50Ω microstrip line 12 to obtain broadband characteristics.

2 shows an equivalent transmission model of a high pass filter.

To design a broadband high pass filter, a mixed lumped distributed (L / D) high pass filter method was used. In other words, a distributed capacitor and a resistor are used.

In the high pass filter, the length of the short stub is connected to the line at intervals of 2θc as shown in FIG. Given characteristic impedance is Z0, Z1 and Z2 are the impedances of the short stubs of the transmission line, and Z1 and 2 are the short stub connection line impedances. Given characteristic impedance and each line impedance, Eqs.

Z _i = Z ₀ / y _i

Z _{i , i + 1} = Z ₀ / y _{i , i + 1}

Y _i , y _{i , i + 1} in Equations 1 and 2 are the element values of the optimized distributed high pass filter with 0.1 dB ripple. When the number of stubs is 2, the optimized distribution high pass filter value with 0.1 dB ripple is shown in Table 1 below.

n θc y ₁ y _{1 , 2} y _n y _{n -1, n} 2 25 ° 0.15436 1.13482 30 ° 0.22070 1.11597 35 ° 0.30755 1.08967

The value of θc in Table 1 can be obtained by Equation 3 below.

In Equation 3, fc is a cutoff frequency and fm is a maximum bandwidth. When fc is 2.4 GHz and fm is 9.9 GHz, the electrical length θc of each short stub 13 is 34.94 ⁰ .

When the θc value obtained by Equation 3 is obtained by using the interpolation method using Table 1 above, and substituted into Equation 1 and Equation 2, the impedance Z1 = Z2 = 162.86 Ω, Z1, 2 = 45.87 Ω

 In the filter of the embodiment according to the present invention, the band stop characteristic is represented by two open stubs 14 connected to the 50 Ω microstrip line 12.

3 shows an equivalent transmission line model of a band reject filter. An open stub 14 representing the bandstop filter is connected between the high pass filters. The band reject filter is composed of θ c of spacing between two open stubs 14 having an electrical length of θ ₀ . The characteristic impedance of the open stub 14 is Z01, and the impedance of the connecting line is calculated through equations 3 and 4.

Z _i = Z _{o /} g _i

Z _{i , i + 1} = Z _o / J _{i , i + 1}

In Equations 4 and 5, g _i , J _{i , i + 1} are element values of an optimized bandstop filter having a ripple constant value of 0.1005. The device values according to the fractional bandwidth of the optimized bandstop filter with two stubs and a ripple constant of 0.1005 are shown in Table 2 below.

Specific bandwidth g ₁ = g ₂ J _{1 , 2} 0.3 0.16989 0.98190 0.4 0.23418 0.93880 0.5 0.30386 0.89442 0.6 0.38017 0.84857 0.7 0.46470 0.80106 0.8 0.55955 0.75173 0.9 0.66750 0.70042 1.0 0.79244 0.64700 1.1 0.93992 0.59137 1.2 1011821 0.53346 1.3 1.34030 0.47324 1.4 1.62774 0.41077 1.5 2.01930 0.34615

Calculating by applying the equations 4, 5 and the ripple constant value, the calculated impedance of the open stub is Z01 = 790.86 Ω, Z1,2 = 45.87 Ω, Z2,3 = 43.39 Ω.

 4 is a graph showing a simulation value of the S parameter for each frequency of the high pass filter. In the graph, when only the short stub 13 is formed and there is no open stub 14, it can be seen that the high pass filter is satisfied and the UWB band is satisfied.

Let's take a quick look at the S parameter.

The S parameter is the ratio of input voltage to output voltage in the frequency distribution.

In FIG. 4, S21 denotes a ratio of the voltage input at the port 1 and the voltage output at the port 2, and S11 denotes the ratio of the voltage input at the port 1 and the voltage output at the port 1. Each element of the S parameter can be classified into transmission, reflection, coupling and isolation coefficients.

The transmission coefficient is a coefficient for evaluating how long it reaches the port to which the input signal is to be transmitted. S21 corresponds to this and the reflection coefficient corresponds to its own reflection value of each input / output port. It means the reflected value because it is inputted, outputted and returned.

FIG. 5 is a graph showing the simulation transmission coefficient S21 characteristics according to the length of the open stub 14 connected to the 50 Ω microstrip line 12. FIG. The transmission coefficient characteristic of the filter is shown when the length Ls of the open stub 14 is changed from 7.5 mm to 8.5 mm at 0.5 mm intervals. By changing the length Ls of the open stub 14, it can be seen that the center frequency of the band rejection moves to a low frequency based on the insertion loss -3 dB. That is, the connected open stubs 14 constitute a quarter wave resonator structure so that radiation at that wavelength can be suppressed. At this time, by adjusting the length of the open stub 14, it is possible to determine the wavelength at which the electromagnetic field cancels. In general, electromagnetic waves of wavelength λ in dielectrics Since [epsilon] is transmitted at a wavelength of dielectric constant, the length Ls of an open stub for having band-stopping characteristics at the center wavelength [lambda] is given by the following equation.

 As described above, in the present embodiment, by forming the open stub 14 connected to the 50 Ω microstrip line 12, the bandstop characteristic of the filter can be added, and as predicted by the above formula, the open stub 14 As the length of) increases, the center frequency of the stop band decreases.

The present invention is not limited thereto, and it will be readily appreciated by those skilled in the art that various types of open stubs may be applied without departing from the principles disclosed herein.

 FIG. 6 is a graph illustrating simulation values of frequency-specific S parameters of a UWB filter having a band blocking characteristic. FIG. The dimensions of each part in the microstrip line 12 shown in FIG. 1 are shown in the following table. Each dimension is given in mm.

Wsub 24 Ws2 2.05 Lsub 24 Lf1 5 Wh 0.3 Lf2 3.5 Ls 8.5 Lf3 4 Ws 0.2 Lh 7.35 Ws1 1.65 Wf 2

7 is a graph showing an S parameter measurement value according to the frequency of the filter by manufacturing an actual filter according to Table 3 above. The measured band pass frequency is 2.16 GHz to 10.57 GHz based on return loss (S11) -10 dB and the stop bandwidth is 5.17 GHz to 5.97 GHz based on -3 dB insertion loss.

 8 is a graph showing the frequency versus group delay measurement of the filter of this embodiment. It is less than 0.65 nsec in all bands except the stop band.

According to the present invention, two short-circuited stubs may be formed on a 50 Ω microstrip line to realize an ultra wideband antenna having an extended bandwidth.

 In addition, according to the present invention, by forming two open-circuited stubs on the microstrip line, there is an effect of preventing a specific band.

Further, according to the present invention, it is possible to reduce the weight and size and to be suitable for mass production.

In addition, according to the present invention, there is an effect that can provide a microstrip filter having excellent cutoff characteristics.

1 is a top view, rear view and side view of a filter according to an embodiment of the present invention.

2 is an equivalent transmission line model of a high pass filter according to an embodiment of the present invention.

3 is an equivalent transmission line model of a band reject filter according to an embodiment of the present invention.

4 is a graph showing the frequency versus S parameter of a high pass filter in accordance with an embodiment of the present invention.

5 is a graph showing a frequency vs. transmission coefficient according to the length of an open stub according to an embodiment of the present invention.

6 is a graph showing a simulation result of frequency vs. S parameter of a filter with band rejection according to an embodiment of the present invention.

7 is a graph showing the actual measurement results of the frequency vs. S parameter of the filter having a band stop characteristic according to an embodiment of the present invention

8 is a graph showing measured values of frequency versus group delay of a filter according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

11 substrate 12 microstrip line

13: Short stub 14: Open stub

15: via hole 16: ground plane

17, 17 ': feeding part

Claims (8)

A substrate formed of a dielectric having a ground plane formed on its rear surface and a feed surface formed on both upper and lower sides thereof; A microstrip line formed in an S shape on the upper surface of the substrate and composed of a 50Ω resistor; Two short stubs formed in the S-shaped microstrip line in the transverse direction and having via holes formed therein; And Two are formed in the same direction on the S-shaped microstrip line and the length is an open stub, where? is the center wavelength of the stop band and? is the dielectric constant of the substrate. The method of claim 1, The via hole is ultra-wideband microstrip filter, characterized in that the diameter of 0.3mm. delete delete delete delete delete delete