KR20080047874A - Reconfigurable multi-band antenna - Google Patents

Abstract

A reconfigurable multi-band antenna is provided to obtain a characteristic satisfying Wibro(Wireless Broadband Internet) and DMB(Digital Multimedia Broadcasting) bands according to a switching characteristic of a PIN diode by using the PIN diode in a single-feed single antenna. A reconfigurable multi-band antenna includes a radiation patch(11), a feed line(19), an impedance converter(13), and a plurality of diodes(12). The radiation patch is arranged on a dielectric substrate and has first to third regions to form signal paths by a plurality of symmetrical slits(15). The third region is made of a thin film conductor to form the signal path from the first region to the second region. The feed line is electromagnetically connected to one end of the first region of the radiation patch to feed current to the radiation patch. The impedance converter is arranged between the radiation patch and the feed line to match impedance. The plurality of diodes are arranged at the slit regions respectively and turned on when applying a bias voltage to form the additional signal path from the first region to the second region.

Description

Reconfigurable multi-band antenna

1 is a plan view of a reconfigurable multiband antenna according to the present invention;

2A and 2B are diagrams illustrating current flow in an antenna patch when a diode is turned on and off in a reconfigurable multiband antenna according to the present invention, respectively.

3 is a graph illustrating return loss characteristics of a reconfigurable multi-band antenna according to the present invention, and

4A and 4B illustrate radiation patterns of a reconfigurable multiband antenna according to the present invention measured at the center frequencies of Wibro and DMB services, respectively.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reconfigurable multi-band antenna, and employs a PIN diode as a switching element in a microstrip antenna, depending on the bias characteristics of the diode. For a reconfigurable multiband antenna having a frequency conversion characteristic that operates at.

Recently, with the rapid development of wireless communication technology, there is a growing interest in integrated systems that can provide various communication services. Microstrip patch antennas are easy to manufacture in a compact, lightweight, and thin film structure, and have a number of researches on frequency conversion using such patch antennas because they have advantages of easily integrating devices such as PIN diodes and DC block capacitors. . Frequently used microstrip antennas have the advantages of being small in size, easy to manufacture, and advantageous for mass production, but with the disadvantage of narrow bandwidth.

In order to solve this problem, many researches have been conducted on multi-band antennas in which a plurality of frequency bands can be selected by using a switching element such as a PIN diode in a micro strip antenna to turn on / off the electrical length of a diode. have. A reconfigurable antenna is a new type of antenna that can exhibit various kinds of characteristics such as frequency conversion and pattern conversion. Such reconfigurable antennas are classified into four types: frequency diversity antenna, polarization diversity antenna, radiation pattern diversity antenna, and antennas incorporating the above characteristics. However, the conventional multi-band antenna has a problem of severe fading and interference for each frequency service band. In addition, by designing antennas having two or more different frequency bands for reliable frequency selection, the total number of antennas increases while the number of antennas increases, which in turn leads to high cost of the transmitter / receiver.

The technical problem to be solved by the present invention is to provide a smaller size compared to a wideband antenna, to reduce the frequency phenomena of the frequency selectivity and co-site interference, and to reconfigurable multi-band to minimize the effects of other frequency interference To provide an antenna.

In order to achieve the above technical problem, a reconfigurable multi-band antenna according to the present invention, the first region, the second region is formed on the dielectric substrate, the first region, the second region for forming a signal path by a plurality of slit formed symmetrically And a third region, the third region comprising: a radiation patch made of a thin plate conductor forming a movement path of a signal from the first region to the second region; A power supply line electromagnetically connected to one end of the first region of the radiation patch to supply current to the radiation patch; An impedance converter disposed between the radiation patch and the feed line to match an impedance; And a plurality of diodes disposed in each of the regions in which the slits are formed, the diodes being turned on when the bias voltage is applied to form an additional signal movement path from the first region to the second region.

As a result, it is possible to obtain characteristics that satisfy Wibro and DMB bands according to the switching characteristics of the PIN diode, reduce the size of the transmit / receive end, reduce the price of the antenna, and reduce the effects of fading and interference between different frequencies. have.

Hereinafter, exemplary embodiments of a reconfigurable multi-band antenna according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a plan view of a reconfigurable multi-band antenna according to the present invention manufactured in the form of a microstrip antenna of the single feed type.

Referring to FIG. 1, the overall size of the antenna is width (W ₁ ) = 70 mm, length (L ₁ ) = 47 mm, and the rectangular patch 11 has a width W ₂ and a length L ₂ , respectively. 26 mm. The resonance frequency when there is no slit 15 on the patch 11 surface is 2.75 GHz. The dielectric substrate 14 is a FR4 epoxy substrate having a dielectric constant epsilon _r of 4.4 and a height of 1.6 mm. An impedance converter 13 having a length of 17.1 mm and a width of 0.5 mm is disposed between the patch 11 and the feed line 19 for impedance matching of the antenna and the feed line 19. The impedance converter 13 takes the form of a meander line to reduce the overall size of the antenna.

Two parallel slits 15 are formed in the antenna patch 11 to achieve operating frequency conversion, and a pin diode 12 is disposed in each slit 15 to electrically interrupt the antenna patches 11. . Two frequencies can be selected according to the on / off state of the PIN diode 12. In addition, by using the slit 15 it is possible to increase the electrical length to reduce the overall antenna size. The width and length of the slit 15 are 1.0 mm and 7.7 mm, respectively. Therefore, when the operation state of the two PIN diodes 12 is Off, the length of the slit 15 is 7.7 mm, it is possible to select the Wibro service in the 2300 ~ 2400 MHz band. In addition, since the length of the slit 15 is 2 mm when the operation state of the two PIN diodes 12 is On, it is possible to select a DMB service in the 2605 ~ 2655 MHz band.

DC bias lines 17 located on both sides of the antenna having a length (10 mm) of λ / 4 of the higher frequency DMB band (2.6 GHz) for driving the PIN diode 12 in a reconfigurable multi-band antenna according to the invention. Was adopted. However, the DC bias line 17 is preferably formed slightly smaller than 10 mm in order to flow out the optimized result of the antenna. DC bias line 17 has no effect on the RF signal and is not affected by the flow of surface current of the antenna. The DC bias line 17 is used to stably flow the negative voltage of the PIN diode 12 to the ground plane, thereby reducing the loading effect. DC bias line 17 is connected to a conducting pad 18 having a size of 1.6 x 2.6 mm ² . The conducting pad 18 is located between the top of the slit 15 of the antenna and the antenna patch 11 and electrically couples the two PIN diodes 12 and the capacitor 16. Two capacitors 16 having a value of 30 pF are coupled between the conducting pad 18 and the antenna patch 11, and the capacitors 16 block the DC component for driving the PIN diode 12. Do it. At this time, the two PIN diodes 12 and the capacitor 16 do not affect the return loss of the antenna. In addition, a DC voltage for driving the two PIN diodes 12 is applied together with an AC voltage at the input terminal of the micro strip line.

2A and 2B are diagrams illustrating current flow in an antenna patch when a diode is turned on and off in a reconfigurable multi-band antenna according to the present invention.

2A and 2B, in the case of the antenna illustrated in FIG. 2A, when the PIN diodes 12 are all off, the antenna having the Wibro band is operated. The antenna shown in FIG. 2A has a current flow formed around the slit 15 coupled to the antenna to satisfy a low resonance frequency. The antenna shown in FIG. 2B operates as an antenna having a DMB band when the PIN diodes 12 are all on, and because the current flows directly through the PIN diode 12 coupled to the antenna, the PIN diode 12 When is off, the higher resonance frequency is satisfied.

3 is a graph illustrating return loss characteristics of a reconfigurable multi-band antenna according to the present invention. Referring to FIG. 3, when the characteristic of the PIN diode 12 is turned on or off, the measurement bandwidth is 100 MHz and 2.613 to 2.725 GHz based on the return loss of -10 dB. The DMB of the band is 112 MHz. On the other hand, the radiation pattern of the reconfigurable multi-band antenna according to the present invention measured at the center frequency of the Wibro and DMB service is shown in Figures 4a and 4b. In FIG. 4A, the radiation pattern of an antenna operating in the Wibro band is represented by an E-plane pattern and an H-plane pattern. In FIG. 4B, the radiation pattern of an antenna operating in the DMB band is represented by an E-plane pattern and an H-plane pattern. Expressed by 4A and 4B, the measured radiation pattern shows excellent linear polarization characteristics. In addition, the measured antenna gains were measured at 0.1 dBi and -1.4 dBi for Wibro and DMB, respectively. The following table lists the measured values for the antenna according to the invention.

Service (MHz) Wibro DMB 2300-2400 2605-2655 Diode status All off All On Bandwidth (MHz) simulation Measures simulation Measures 2300-2400 2280-2380 2600-2700 2613-2725 100 100 100 112 Gain (dBi) 0 0.1 2 -1.4

The reconfigurable multi-band antenna according to the present invention has a form of an equilateral triangle microstrip antenna whose resonance frequency is changed by using on / off characteristics of a PIN diode. When the PIN diode is off, the resonance frequency of the antenna is 1.22 GHz because current flows around the spur line under the influence of the T-shaped spur-line. However, when the PIN diode is turned on, the T-shaped spurline is changed into an I-shaped slot line, and the resonance frequency of the antenna is 1.82 GHz because the current is less affected by the I-shaped slot line. . The reconfigurable multi-band antenna according to the present invention having such characteristics has little difference from the resonance frequency of a general equilateral triangular microstrip antenna. In addition, the reconfigurable multi-band antenna according to the present invention exhibits linear polarization characteristics in which both the PIN diodes have a radiation pattern of less than -20 dB in cross polarization.

The reconfigurable multi-band antenna according to the present invention as described above is an antenna using a frequency diversity scheme, in which two parallel slits are added to have a frequency conversion characteristic as a single-feed single antenna instead of a plurality of antennas. A PIN diode, which is a switching element, is used on two parallel slits configured to generate frequency conversion. The antenna is reconfigured according to the bias condition of the diode to have frequency conversion characteristics. As such, by configuring the feed point and the ground point to be switched with each other in the asymmetrical antenna, the capacitance component may be adjusted by differently setting a space in which the mutual coupling phenomenon formed due to the characteristics of the asymmetrical antenna occurs. As a result, the operating frequency of the antenna is changed to be used in both the low frequency band and the high frequency band, so that the DVB-H receiving terminal can receive DVB data using only one antenna. In addition, the reconfigurable multi-band antenna according to the present invention provides a smaller size compared to the conventional broadband antenna, can reduce the inverse of the frequency selectivity and co-site interference, and can reduce the effects of other frequency interference as much as possible Have

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

According to the reconfigurable multi-band antenna according to the present invention, by using a PIN diode as a switching element for a single feed and a single antenna, it is possible to obtain a characteristic satisfying the Wibro and DMB band according to the switching characteristics of the PIN diode, The size of the antenna can be reduced, the cost of the antenna can be reduced, and the effects of fading and interference between different frequencies can be reduced. In addition, the reconfigurable multi-band antenna according to the present invention can be applied to a Wibro communication system and a transmitting / receiving end (mobile, vehicle) antenna for receiving the Korean satellite DMB service, and applied to a multi-band antenna system requiring a plurality of frequency conversions Can be.

Claims (1)

A first area, a second area, and a third area are formed on the dielectric substrate to form a movement path of the signal by a plurality of slit symmetrically formed, wherein the third area is the first area from the first area. A radiation patch consisting of a thin plate conductor forming a movement path of a signal to two regions; A power supply line electromagnetically connected to one end of the first region of the radiation patch to supply current to the radiation patch; An impedance converter disposed between the radiation patch and the feed line to match an impedance; And A plurality of diodes disposed in each of the regions where the slits are formed, the plurality of diodes being turned on when a bias voltage is applied to form an additional signal movement path from the first region to the second region; Multiband Antenna.

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