KR100892235B1 - Quadruple polarization antenna and feeding circuitry for the same - Google Patents

Abstract

The present invention has been made to solve the problem of a circularly polarized wave having a relatively short recognition distance and a dual polarized antenna having a short recognition distance in each direction between both polarizations. The present invention relates to a quadrature polarization antenna and a polarization implementation method capable of obtaining a range expansion effect.

To this end, the quadrature polarization antenna according to the present invention has a four-feeding point, a radiation plane radiating electromagnetic waves, and a quadrature-polarization antenna including a feeding circuit unit for supplying feeding signals to the four feeding points, The power supply circuit unit generates linear polarizations in four different directions.

Linear polarization, phase, feed, radiation, feed circuit

Description

Quadruple polarization antenna and feeding circuitry for it {Quadruple polarization antenna and feeding circuitry for the same}

The present invention has been made to solve the problem of a circularly polarized wave having a relatively short recognition distance and a dual polarized antenna having a short recognition distance in each direction between both polarizations. The present invention relates to a quadrature polarization antenna and a polarization implementation method capable of obtaining a range expansion effect.

The present invention relates to a direct feed patch antenna, and more particularly, to a patch antenna with high gain, small size and improved axial ratio bandwidth.

A patch antenna is an antenna using a patch-shaped radiator. The patch antenna is small, lightweight, and easily arranged, integrated, and polarized.

Hereinafter, a conventional patch antenna will be described with reference to FIGS. 1 and 2.

FIG. 1 is a perspective view of a general patch antenna, and FIG. 2 is a perspective view of a patch antenna for implementing a circular polarization.

As shown in FIG. 1, a generally-used linear patch antenna 20 has an opening surface formed on the ground plate 21 to position the feed line 22 in the center of the slot 23. At the same time, by protruding further from the slot 23 by a length of about [lambda] / 4, only linear polarization is generated. The linear patch antenna 20 has a problem that the size of the antenna is increased to match the resonant frequency as a single slot antenna.

In addition, the conventional linear polarized antenna has a maximum recognition distance when the tag and the polarization is the same, but if not, the recognition distance is reduced, and the recognition distance is sharply reduced as the polarization direction of the antenna and the polarization direction of the tag is shifted. This is the same for the vertical / horizontal dual polarized antennas, so there was a problem in that it was not easy to recognize in the direction of the intersecting angle of the polarization.

In order to solve this problem, a circularly polarized patch antenna 30 having two slots 31 and 32 as shown in FIG. 2 has been proposed. A feed line 34 having a delay line 33 of λ / 4 is formed on one side of the circularly polarized patch antenna 30 to implement circular polarization. Such a circular polarized patch antenna 30 is suitable for broadcasting / communication due to its excellent transmission characteristics and low multiple reflection interference. However, since the circularly polarized patch antenna 30 for dual feeding has to design the double delay line 33 and two opening surfaces, that is, the slots 31 and 32, the structure is complicated and thus the miniaturization of the entire circuit when the microwave circuit is mounted is required. There is a problem that does not plan to increase the manufacturing cost due to the decrease in productivity.

In addition, in the case of circular polarization, there is a problem that the recognition distance is short while the irrespective of the polarization.

This problem is described in more detail with reference to FIG. 3 below.

3 is a diagram illustrating a recognition distance for each polarized wave.

In general, parameters representing the performance or characteristics of an antenna include radiation pattern (meaning directionality), directivity (ratio of power density and average power density in the maximum radiation direction), and gain (directivity reduced by the resistive loss of the antenna). , Polarization (shape due to the trajectory of the electric field vector during transmission), impedance (input impedance at the antenna terminal), and bandwidth (frequency range for which the main performance parameter values are available) are used.

Among these, antenna polarization is "the nature of electromagnetic waves that show the variation of the magnitude and relative magnitude of the field vector, especially the fixed end of the vector as a function of time and the observed direction along the propagation direction of the propagation" Is defined. That is, it means the shape of a curve consisting of a trajectory drawn in time on the X-axis and the Y-axis when the radio wave propagates in the Z-axis direction.

The polarization is divided into linear polarization (vertical or horizontal) and circular polarization (right or left). In general, these antenna polarization characteristics dominate performance in communication or sensor systems.

Referring to FIG. 3, the recognition distance of the circular polarization is the shortest, and in the case of the double polarization, the recognition distance increases in the vertical and horizontal directions, but in the angle direction between the angles of the vertical and horizontal polarizations. It can be seen that the recognition distance is not significantly different from the circular polarization. On the other hand, in the case of quadrature polarization, the recognition distance can be extended to an area not covered by the dual polarization, thereby obtaining an effect of extending the pan-orientation recognition distance.

Accordingly, there is a need for the development of a quadrature polarization antenna capable of providing a wide recognition distance for solving the problem of the narrow recognition distance of the conventional circularly polarized or double polarized antenna.

In order to solve the above problem, the present invention provides a quadrature linear polarization to solve a problem in a circular linear polarization antenna having a relatively short recognition distance and a double linear polarization antenna having a short recognition distance in each direction formed by both polarizations. The present invention relates to a quadrature polarization antenna and a polarization implementation method capable of generating a recognition distance enhancement effect.

Quadruple polarization antenna according to the present invention for achieving the above object has a four feed points, including a radiation surface for radiating electromagnetic waves, and a feed circuit unit for supplying a feed signal to the four feed parts, The power supply circuit unit generates linear polarizations in four different directions.

Here, the radiation surface may be directly fed through the feed circuit unit or coupled feed.

In addition, the feed point may be formed radially in a direction perpendicular to each other from the center of the feed circuit portion.

In addition, by inserting a dielectric between the radiation surface and the power supply circuit portion it is possible to shorten the electrical length.

In addition, the present invention can provide a wireless communication device including the quadrature polarization antenna.

In addition, the feed circuit of the quadrature polarization antenna according to the present invention, the SP4T switch is connected to the input port to switch one of the input signal to any one of the four transmission lines, among the four transmission lines output from the SP4T switch A coupler connected to two and outputting signals input from any one of the two transmission lines as two signals having a predetermined phase difference, and outputted from the coupler, and a phase difference opposite to the phase difference by the coupler It includes two transmission lines having a.

The apparatus may further include a pair of SPDT switches for switching any one of two input terminals connected to one of the outputs from the SP4T switch not connected to the coupler and one of the outputs from the coupler to the output terminal. Can be. In addition, the pair of SPDT switches can be controlled to operate according to a single or synthetic polarization selection.

In addition, the feed circuit unit may be fed using a Wilkinson divider.

As described above, the present invention can increase the recognition distance and increase the recognition range by generating the quadrature polarization by using the quadrature polarization antenna and the polarization implementation method.

Hereinafter, with reference to the accompanying drawings, it will be described the most preferred embodiment of the quadrupole polarization antenna according to the present invention.

4 is a diagram illustrating a quadrature polarization antenna according to an embodiment of the present invention.

Referring to FIG. 4, a radiating surface 100 having four feeding points, a feeding circuit unit 200 controlling the four feeding points, four feeding points formed on the radiating surface 100 and the feeding circuit unit ( A feeder 300 for electrically connecting one surface of the 200, and a ground plane 400 formed adjacent to the other surface of the feeder circuit unit 200.

The radiation surface 100 may be formed of a plate made of a conductive material, and may be directly fed through the power supply unit 300. In this case, a distance between the power supply circuit unit and the radiation surface is required when power is supplied by the coupling. Not required, the antenna can be miniaturized as a whole. The radiation surface 100 may be implemented in various forms such as a circle, a triangle, a rectangle, or a polygon, and may satisfy the registration required when generating the polarization by adjusting only the position of the feed point according to each structure.

Meanwhile, although the radiation surface 100 and the power supply circuit unit 200 are directly exemplified through the power supply unit 300 through FIG. 4, the present invention is not limited thereto. However, the radiation surface 100 and the power supply circuit unit 200 are not limited thereto. In addition, a coupling feeding method using a coupling with the feeding circuit unit 200 may be used.

In addition, a dielectric may be inserted between the radiation surface 100 and the power supply circuit part 200 to shorten an electrical length, thereby reducing the height of the power supply part 300. The feeding part 300 may be formed in a columnar shape such as a cylinder, a square pillar, a hexagonal function, and may support the radiation surface 100 in addition to the feeding function to the radiation surface 100. In addition, the feed unit 300 may be formed using a conductive wire such as a coaxial cable.

Meanwhile, the radiation surface 100 and the power feeding circuit unit 200 may be implemented in the form of a micro strip patch antenna using a printed circuit board, which will be easily understood by those skilled in the art.

Meanwhile, the quadrature polarization antenna of the present invention can be applied to an RFID related field.

5 is a diagram illustrating in detail a power supply circuit unit according to an embodiment of the present invention.

Referring to FIG. 5, the power supply circuit unit 200 includes a substrate 210 as a part for receiving an external wireless signal, and a pattern unit 220 having a micro strip pattern formed on one surface of the substrate 210. Four feed points (A, B, C, D) using a Wilkinson divider are formed in the pattern unit 220 to increase the axial ratio bandwidth. The feed points A, B, C, and D are radially formed in a direction perpendicular to each other from the center of the pattern portion 220. The feed points A, B, C, and D are preferably formed at the same distance from the center of the pattern portion 220, but are not particularly limited thereto, and the substrate 210 and the pattern portion 220 may be It can be formed in one module.

Looking at the configuration of the power supply circuit portion 200 in more detail, a power distribution circuit is formed on the power supply circuit portion 200. Preferably, the power supply circuit unit 200 is formed of a printed circuit board, it is possible to more easily form the power distribution circuit. The power distribution circuit is implemented with several transmission lines having a predetermined length and width. Referring to the illustrated example, first, an input port to which a signal is input and a Singler-Pole 4-Throw (SP4T) switch 221 are connected. do. The SP4T switch 221 switches and outputs one input signal to any one of four transmission lines. In the present embodiment, the signal input from the input port is switched to one of four transmission lines 223a, 223b, 223c, and 223d and output. The polarization of the signal radiated through the radiation surface 100 is determined by the switching of the SP4T switch 221. This will be described later with reference to FIGS. 6 to 9.

The other end of the 223b and 223c transmission lines, one end of which is connected to the SP4T switch 221, is connected to the coupler 222. The coupler 222 outputs one input in two and simultaneously adjusts the phase difference between the two outputs by a predetermined phase difference, for example, 90 degrees. For example, a signal input through the 223b transmission line is output to the 223e and 223f transmission lines via the coupler 222, and the signal output to the 223e transmission line is 90 compared to the signal output through the 223f transmission line. The phase is also advanced. On the contrary, the signal input through the 223c transmission line is 90 degrees out of phase with the signal output through the 223f transmission line than the signal output through the 223e transmission line.

On the other hand, the 223f transmission line has a length that gives a phase difference opposite to the phase difference by the coupler compared to the 223e transmission line, for example, has an extended length of 1/4 wavelength (that is, λ / 4) in this embodiment. . Therefore, when a signal having the same phase is input to the 223e and the 223f transmission line, the signal passing through the 223e transmission line is 90 degrees ahead of the signal passing through the 223f transmission line.

The 223a and 223e transmission lines are connected to a first single-pole double-throw (SPDT) switch 224a, and the 223f and 223d transmission lines are connected to a second SPDT switch 224b. The first and second SPDT switches 224a and 224b switch one of two input terminals and connect them to the output terminal. The quadrature polarization antenna controls the operation of the first and second SPDT switches 224a and 224b to generate a single or composite linear polarization.

The output terminal of the first SPDT switch 224a is connected to the 225a transmission line, and the 225a transmission line is connected to the 225b and 225c transmission lines through the first Wilkinson distributor 226a. The first Wilkinson distributor 226a distributes power in half and transmits the power to the 225b and 225c transmission lines. The 225b and 255c transmission lines are formed to have a length difference of 1/2 wavelength.

Similarly, the output terminal of the second SPDT switch 224b is connected to the 225d transmission line, and the 225d transmission line is connected to the 225e and 225f transmission lines via the second Wilkins distributor 226b. The second Wilkinson distributor 226b divides the power by half and transmits the power to the 225e and 225f transmission lines. The 225e and 255f transmission lines are formed to have a length difference of 1/2 wavelength.

Here, the Wilkinson divider is merely an example, and those skilled in the art may use any power distribution circuit. In addition, in order to achieve the phase delay, a phase shifter may be used in addition to adjusting the length of the transmission line. Therefore, even if the transmission line for phase delay is replaced with the phase shifter, it is within the scope of the present invention.

Hereinafter, a polarization selection and an operation process of the quadrature polarization antenna will be described with reference to FIGS. 6 to 10.

FIG. 6 is a diagram illustrating a linear polarization generation process in a horizontal direction using a quadrature polarization antenna according to an exemplary embodiment of the present invention.

Referring to FIG. 6, when a signal is input through an input port, the input signal is switched to the 223a transmission line through the SP4T switch 221. The signal transmitted through the 223a transmission line is transmitted to the first SPDT switch 224a. The signal passing through the first SPDT switch 224a is transmitted to the first Wilkinson distributor 226a via a 225a transmission line. The first Wilkinson splitter 226a divides the power of the input signal into 1/2 and then divides the signal into 225b and 225c transmission lines. Since the 225b and 255c transmission lines have a length difference of 1/2 wavelength, the signal output through the A feed point to which the 225b transmission line is connected and the B feed point to which the 225c transmission line is connected have a 180 degree phase difference. Therefore, in the radial plane 100, horizontal linear polarization is generated from the A feed point to the B feed point.

7 is a diagram illustrating a linear polarization generation process in a vertical direction using a quadrature polarization antenna according to an embodiment of the present invention.

Referring to FIG. 7, when a signal is input through the input port, the input signal is switched to the 223d transmission line through the SP4T switch 221. The signal transmitted through the 223d transmission line is transmitted to the second SPDT switch 224b. The signal passing through the second SPDT switch 224b is transmitted to the second Wilkinson distributor 226b via a 225d transmission line. The second Wilkinson divider 226b divides the power of the input signal into 1/2 and then divides the signal into 225e and 225f transmission lines. Since the 225e and 255f transmission lines have a length difference of 1/2 wavelength, the signal output through the C feed point to which the 225e transmission line is connected and the D feed point to which the 225f transmission line is connected have a 180 degree phase difference. Therefore, in the radial plane 100, vertical linear polarization is generated from the C feed point to the D feed point.

8 is a diagram illustrating a linear polarization generation process in a ↗ (+45 degree) direction using a quadrature polarization antenna according to an embodiment of the present invention.

Referring to FIG. 8, when a signal is input through an input port, the input signal is switched to the 223c transmission line through the SP4T switch 221. The signal passing through the 223c transmission line is transmitted to the coupler 222 connected to the 223c transmission line. The input signal is output to the 223e and the 223f transmission line through the coupler 222, and the signal output to the 223f transmission line is 90 degrees ahead of the signal output through the 223e transmission line. The signal output through the 223e transmission line is transmitted to the first Wilkinson distributor 226a through the 225a transmission line via the first SPDT switch 224a. On the other hand, the signal output through the 223f transmission line is transmitted to the second Wilkinson distributor 226b through the second 225d transmission line via the second SPDT switch 224b. Since the 223f transmission line is longer by a quarter wavelength than the 223e transmission line, the phase of the input signal lags 90 degrees during the passage. In general, the signal output from the coupler 222 to the 223f transmission line which is 90 degrees out of phase with respect to the signal output to the 223e transmission line is delayed by 90 degrees in the passage of the 223f transmission line. The signal immediately after passing through the switch 224a and the second SPDT switch 224b is in phase.

On the other hand, the first Wilkinson distributor 226a divides the power of the input signal by 1/2, and then transmits the signal divided into 225b and 225c transmission lines. Since the 225b and 255c transmission lines have a length difference of 1/2 wavelength, the signal output through the A feed point to which the 225b transmission line is connected and the B feed point to which the 225c transmission line is connected have a 180 degree phase difference. Therefore, in the radiation surface 100, linear polarization is generated from the A feed point to the B feed point.

Similarly, the second Wilkinson divider 226b divides the power of the input signal into 1/2 and then divides the signal into 225e and 225f transmission lines. Since the 225e and 255f transmission lines have a length difference of 1/2 wavelength, the signal output through the C feed point to which the 225e transmission line is connected and the D feed point to which the 225f transmission line is connected have a 180 degree phase difference. Therefore, in the radial plane 100, linear polarization is generated from the C feed point to the D feed point.

By combining the linear polarization generated from the A feed point in the direction of the B feed point and the linear polarization generated from the C feed point in the D feed point direction, a linear polarization in the ↗ direction can be obtained as shown in FIG.

FIG. 9 is a diagram illustrating a linear polarization generation process in a ↘ (-45 degree) direction using a quadrature polarization antenna according to an embodiment of the present invention.

9, when a signal is input through an input port, the input signal is switched to the 223b transmission line through the SP4T switch 221. The signal passing through the 223b transmission line is transmitted to the coupler 222 connected to the 223b transmission line. The input signal is output to the 223e and the 223f transmission line through the coupler 222, and the signal output to the 223e transmission line is 90 degrees out of phase with the signal output through the 223f transmission line. The signal output through the 223e transmission line is transmitted to the first Wilkinson distributor 226a through the 225a transmission line via the first SPDT switch 224a. On the other hand, the signal output through the 223f transmission line is transmitted to the second Wilkinson distributor 226b through the 225d transmission line via the second SPDT switch 224b. Since the 223f transmission line is longer by a quarter wavelength than the 223e transmission line, the phase of the input signal lags 90 degrees during the passage. In general, the signal output from the coupler 222 to the 223f transmission line which is 90 degrees out of phase with respect to the signal output to the 223e transmission line is further delayed by 90 degrees in the process of passing through the 223f transmission line. Immediately after passing through the first SPDT switch 224a, the phase is 180 degrees behind the signal passing through the second SPDT switch 224b.

On the other hand, the first Wilkinson distributor 226a divides the power of the input signal by 1/2, and then transmits the signal divided into 225b and 225c transmission lines. Since the 225b and 255c transmission lines have a length difference of 1/2 wavelength, the signal output through the A feed point to which the 225b transmission line is connected and the B feed point to which the 225c transmission line is connected have a 180 degree phase difference. Therefore, in the radiation surface 100, linear polarization is generated from the A feed point to the B feed point.

Similarly, the second Wilkinson divider 226b divides the power of the input signal into 1/2 and then divides the power into 225e and 225f transmission lines. Since the 225e and 255f transmission lines have a length difference of 1/2 wavelength, the signal output through the C feed point to which the 225e transmission line is connected and the D feed point to which the 225f transmission line is connected have a 180 degree phase difference. However, since the reverse phase occurs while the phase is 180 degrees behind the signal passing through the first SPDT switch 224a in the process of passing through the second SPDT switch 224b, the D-feed on the radiation surface 100 is performed. Linear polarization is generated from the point toward the C feed point.

By combining the linear polarization generated from the A feed point in the direction of the B feed point and the linear polarization generated from the D feed point in the direction of the C feed point, a linear polarization in the X direction can be obtained as shown in FIG.

FIG. 10 is a view illustrating a polarization direction that can be implemented through the quadrature polarization antenna of the present invention.

Referring to FIG. 10, reference numeral 300 denotes a linear polarization direction in the horizontal direction described with reference to FIG. 6, and reference numeral 310 denotes a linear polarization direction in the vertical direction described with reference to FIG. 7. Also, reference numeral 320 denotes a linear polarization direction in the ↗ direction described with reference to FIG. 8, and reference numeral 330 denotes a linear polarization direction in the k-direction described with reference to FIG. 9.

The quadrature polarization antenna of the present invention controls the SP4T switch 221 and the first and second SPDT switches 224a and 224b to switch the movement paths of the feed signals, thereby generating linear polarization in four different directions. have. By using the linear polarization of the four directions, it is possible to detect the whole direction similar to the circular polarization, and has the advantage of maintaining a wide recognition distance unique to the linear polarization.

In the above, the quadrature polarization antenna and the polarization implementation method according to the present invention have been described. Such a technical configuration of the present invention will be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the following claims rather than the foregoing detailed description. All changes or modifications derived from the meaning and scope and equivalent concept thereof should be construed as being included in the scope of the present invention.

1 is a perspective view of a general patch antenna.

2 is a perspective view of a patch antenna for implementing a circular polarization.

3 is a diagram illustrating a recognition distance for each polarized wave.

4 is a diagram illustrating a quadrature polarization antenna according to an embodiment of the present invention.

5 is a diagram illustrating in detail a power supply circuit unit according to an embodiment of the present invention.

FIG. 6 is a diagram illustrating a linear polarization generation process in a horizontal direction using a quadrature polarization antenna according to an exemplary embodiment of the present invention.

7 is a diagram illustrating a linear polarization generation process in a vertical direction using a quadrature polarization antenna according to an embodiment of the present invention.

8 is a diagram illustrating a linear polarization generation process in a ↗ direction using a quadrature polarization antenna according to an embodiment of the present invention.

FIG. 9 is a diagram illustrating a linear polarization generation process in a ↘ direction using a quadrature polarization antenna according to an embodiment of the present invention. FIG.

FIG. 10 is a view illustrating a polarization direction that can be implemented through the quadrature polarization antenna of the present invention.

<Description of the symbols for the main parts of the drawings>

100: radiation surface 200: feed circuit unit

210: substrate 220: pattern portion

221: SP4T switch 222: coupler

223, 225: Transmission line 224: SPDT switch

226 Wilkins Splitter 300 Feeder

400: ground plane

Claims (9)

A radiation surface having four feed points and emitting electromagnetic waves; And In the quadrupole polarization antenna including a feed circuit unit for supplying a feed signal to the four feed points, The power supply circuit unit, An SP4T switch connected to the input port to switch one input signal to one of four transmission lines and output the switch; It is connected to two of four transmission lines connected to the output terminal of the SP4T switch, and outputs the signal input from any one of the two transmission lines as two coupler output signals having a predetermined phase difference, the other one A coupler for outputting two coupler output signals having a phase difference opposite to that of the two coupler output signals when a signal is input from the transmission line of the second coupler output signal; And A feeder circuit unit connected to an output of the coupler and including two transmission lines having a phase difference opposite to that of the coupler and supplying a feed signal to generate linear polarizations in four different directions; Of polarized antennas. The method of claim 1, The radiation plane is a quadrature polarized antenna which is directly fed through the feed circuit portion or coupled feed. The method of claim 1, And the feed point is radially formed in a direction perpendicular to each other from a center of the feed circuit portion. The method of claim 1, And a dielectric inserted between the radiating surface and the feeder circuit portion. A wireless communication device comprising the quadrature polarization antenna of any one of claims 1 to 4. An SP4T switch connected to the input port to switch one input signal to one of four transmission lines and output the switch; It is connected to two of four transmission lines connected to the output terminal of the SP4T switch, and outputs the signal input from any one of the two transmission lines as two coupler output signals having a predetermined phase difference, the other one A coupler for outputting two coupler output signals having a phase difference opposite to that of the two coupler output signals when a signal is input from the transmission line of the second coupler output signal; And And a power supply circuit portion of the quadrature polarizing antenna connected to an output of the coupler and including two transmission lines having a phase difference opposite to that of the coupler. The method of claim 6, And a pair of SPDT switches configured to switch any one of an input terminal connected to one of the output terminals from the SP4T switch not connected to the coupler and an input terminal connected to one of the output terminals from the coupler to an output terminal. Feeding circuit section of quadrupole The method of claim 7, wherein The pair of SPDT switches are feed circuit portion of the quadrupole polarization antenna whose operation is controlled according to a single or composite polarization selection. The method of claim 7, wherein A Wilkinson splitter connected to each of the output terminals of the pair of SPDT switches, two transmission lines are connected to the output terminals of each of the Wilkinson splitters, and a quadrupole polarization antenna that feeds by using a power distribution function of the Wilkinson splitter. Feed circuit part.

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