KR100968973B1 - Patch antenna - Google Patents

Abstract

An embodiment of the present invention includes a patch radiator including a first feeding point and a second feeding point, a feeding line, and a selection unit for selecting the first feeding point or the second feeding point and connecting the feeding line to the feeding line. A patch antenna can be provided.

Antenna, patch, phase

Description

Patch Antenna {PATCH ANTENNA}

The present invention relates to a patch antenna, and more particularly, to a patch antenna capable of phase adjustment in order to increase the transmission efficiency of a transceiver.

In mobile communication and satellite communication, a beam steering technique is applied to increase transmission efficiency of a transceiver. Recently, research is being conducted on the application of short-range wireless communication for large data transmission such as 2.4 / 5 GHz next-generation WLAN or 60 GHz WPAN, which are being developed at home and abroad. The 60 GHz band can be used without a license over a wide bandwidth of several GHz, making it suitable for large transmission system applications that provide voice and video data services.

However, in the 60 GHz band, most countries will apply regulations that limit the output power to less than 10 dBm, so high-gain antennas with reduced beam widths should be used to secure the communication distance. In the case of using a high gain antenna having a small beam width, communication is impossible when the position of the receiver is located at a shadow angle, and thus a beam control system capable of automatically selecting the direction of the beam toward the receiver is required. In the beam control system, a phase shifter is required for phase adjustment of power output for each antenna, and research on this has been continued.

In a conventional beam control system, an array antenna is used to generate a narrow beam and simultaneously adjust the phase of an individual antenna to adjust the beam's radiation direction. The phase adjustment of the individual antennas may be performed using various types of phase shifters connected to the feed ends of the individual antennas. Thus, there is a problem in that the configuration of the system is complicated by using a separate phase shifter separate from the antenna.

In order to solve the above problems, it is an object of the present invention to provide a patch antenna including a phase shifter for the configuration of a simple beam control system to facilitate use at high frequencies.

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One embodiment of the present invention, the patch radiator including the first to fourth feeding point, the first feed line having a predetermined electrical length, the second feed line having an electrical length different from the first feed line and A first selection unit configured to select the first feeding point or the second feeding point to connect to the first feeding line, and a third connecting point to select the third feeding point or the fourth feeding point to connect to the second feeding line. And a second selector, and a third selector that selects the first feed line or the second feed line and connects the external feeder.

The first feeding point and the third feeding point may be feeding positions at which the patch radiator generates output of the same phase when the same power is supplied.

The first feeding point may be formed in one region of the patch radiator, and the third feeding point may be formed in an area that is symmetrical with the first feeding point in the patch radiator.

The first feeding point and the second feeding point may be feeding positions at which the patch radiators generate outputs of different phases when the same power is supplied.

An output phase generated when power is supplied to the first feeding point and an output phase generated when power is supplied to the second feeding point may be 180 degrees.

The first feeding point and the second feeding point may be respectively formed at points that are vertically symmetrical in the patch radiator.

The third feeding point and the fourth feeding point may be feeding positions at which the patch radiators generate outputs of different phases when the same power is supplied.

An output phase generated when power is supplied to the third feeding point and an output phase generated when power is supplied to the fourth feeding point may be 180 degrees.

The third feeding point and the fourth feeding point may be respectively formed at a point that is vertically symmetrical in the patch radiator.

The first feed line and the second feed line may have an electrical length for generating a phase difference of 90 degrees with respect to a feed signal having the same phase.

According to another embodiment of the present invention, there is provided a patch radiator including first to fourth feeding points, a first feed line connected to the first feeding point, and a first feed line connected to the second feeding point. A second feed line having the same electrical length, a third feed line connected to the third feeding point, and having a different electrical length from the first feed line, and connected to the fourth feeding point, and the third feed line And a fourth feed line having an electrical length equal to and a selection unit configured to select one of the first to fourth feed lines to connect to an external feeder.

The first feeding point and the third feeding point may be feeding positions at which the patch radiator generates output of the same phase when the same power is supplied.

The first feeding point may be formed in one region of the patch radiator, and the third feeding point may be formed in an area that is symmetrical with the first feeding point in the patch radiator.

The first feeding point and the second feeding point may be feeding positions at which the patch radiators generate outputs of different phases when the same power is supplied.

An output phase generated when power is supplied to the first feeding point and an output phase generated when power is supplied to the second feeding point may be 180 degrees.

The first feeding point and the second feeding point may be respectively formed at points that are vertically symmetrical in the patch radiator.

The third feeding point and the fourth feeding point may be feeding positions at which the patch radiators generate outputs of different phases when the same power is supplied.

An output phase generated when power is supplied to the third feeding point and an output phase generated when power is supplied to the fourth feeding point may be 180 degrees.

The third feeding point and the fourth feeding point may be respectively formed at a point that is vertically symmetrical in the patch radiator.

The first feed line and the third feed line may have an electrical length for generating a phase difference of 90 degrees with respect to a feed signal having the same phase.

The patch antenna further includes a dielectric layer in which the patch radiator is formed, and other dielectric layers in which the first to fourth feed lines and the selector are formed, and the first to fourth feed lines and the first to fourth feed lines. Feeding points may each be connected by conductive via holes.

According to the present invention, since the antenna includes a function of a phase shifter, an additional phase shifter is not required to construct a beam control system, thereby obtaining a patch antenna capable of simple system configuration.

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

1 is a configuration diagram of a patch antenna according to an embodiment of the present invention.

Referring to FIG. 1, the patch antenna 100 according to the present embodiment includes a patch radiator 110, a first feeding point 111, a second feeding point 112, a power feeding line 150, and a selection unit ( 140).

The patch radiator 110 may be a rectangular conductive plate. The patch emitter may be formed of a metal film on a dielectric substrate.

A first feeding point 111 and a second feeding point 112 may be formed in the patch radiator 110. When the same power is supplied to the first feeding point 111 and the second feeding point 112, the phases of the signals output from the patch radiator 110 may be different from each other. In the present embodiment, when a signal having the same phase is applied to the first feeding point 111 and the second feeding point 112, respectively, a phase difference of 180 degrees may occur in the output of the patch radiator.

In this embodiment, the 1st feeding point 111 and the 2nd feeding point 112 can be formed in the up-down symmetrical area | region in the rectangular patch radiator 110, respectively.

One of the first feeding point 111 and the second feeding point 112 may be connected to the feed line 150 by the selector 140.

The feed line 150 may have a predetermined electrical length.

The selector 140 may select the first feeding point 111 or the second feeding point 112 to connect the power feeding line 150.

The operation of the selection unit 140 may change the characteristics of the patch antenna according to the present embodiment. That is, when the first feeding point 111 is selected by the selector 140, the current transmitted from the feeder is transferred from the feed line 150 to the patch radiator 110 through the first feeding point 111. Will flow. When the second feeding point 112 is selected by the selector 140, the current transmitted from the feeder flows to the mall patch radiator 110 through the feed line 150 and the second feeding point 112. .

In this case, when the patch antenna is operated through the first feeding point 111, a signal having a phase of 180 degrees earlier than the case where the patch antenna is operated through the second feeding point 112 is emitted. . Therefore, the patch antenna may emit a signal having a phase difference of 180 degrees by adjusting the selector 140.

2 is a configuration diagram of a patch antenna according to another embodiment of the present invention.

Referring to FIG. 2, the patch antenna 200 according to the present embodiment includes a patch radiator 210, first to fourth feeding points 211, 212, 213, and 214 formed on the patch radiator, and a first power feed. A line 250, a second feed line 260, a first selector 220, a second selector 230, and a third selector 240 may be included.

The patch radiator 210 may be a rectangular conductive plate. The patch emitter may be formed of a metal film on a dielectric substrate.

A first feeding point 211, a second feeding point 212, a third feeding point 213, and a fourth feeding point 214 may be formed in the patch radiator 210.

When the same power is supplied to the first feeding point 211 and the third feeding point 213, the phase of the signal output from the patch radiator 210 may be the same. In this embodiment, the 1st feeding point 211 and the 3rd feeding point 213 can be formed in the symmetrical area | region in the rectangular patch radiator 210, respectively.

When the same power is supplied to each of the first feeding point 211 and the second feeding point 212, a phase difference of a signal output from the patch radiator 210 may be 180 degrees. In this embodiment, the 1st feeding point 211 and the 2nd feeding point 212 can be formed in the area | region which is vertically symmetrical in the rectangular patch radiator 210, respectively.

When the same power is supplied to the third feeding point 213 and the fourth feeding point 214, the phase of the signal output from the patch radiator 210 may have a phase difference of 180 degrees. In the present embodiment, the third feeding point 213 and the fourth feeding point 214 can be formed in the vertically symmetrical area in the rectangular patch radiator 210.

The first selector 220 may connect the first feeding point 211 or the second feeding point 212 to the first feed line 250. The second selector 230 may connect the third feeding point 213 or the fourth feeding point 214 to the second feed line 260.

The first feed line 250 and the second feed line 260 may have different electrical lengths. In the present embodiment, the first feed line 250 may be formed to have an electrical length λ / 4 longer than that of the second feed line 260. That is, when a signal having the same phase is applied, a phase difference of 90 degrees may occur between a signal output through the first feed line and a signal output through the second feed line.

The third selector 240 may select the first feed line 250 or the second feed line 260 to connect to an external feeder.

In the present embodiment, the characteristics of the patch antenna can be changed by the operation of the first to third selectors.

When the third selector 240 selects the first feed line 250, and the first selector 220 selects the first feeding point 211, the signal of the feed line 270 receives the first signal. It flows to the patch radiator 210 via the first feed line 250 and the first feeding point 211. In this case, the output phase of the patch radiator can be 0 degrees.

When the third selector 240 selects the first feed line 250, and the first selector 220 selects the second feeding point 212, the signal of the feed line 270 receives the first signal. It flows to the patch radiator 210 through the first feed line 250 and the second feeding point 212. In this case, the output phase of the patch radiator may have a phase of 180 degrees.

When the third selector 240 selects the second feed line 260, and the second selector 230 selects the third feeding point 213, the signal of the feed line 270 receives the first signal. It flows to the patch radiator 210 through the second feed line 260 and the third feeding point 213. In this case, the output phase of the patch radiator may have a phase of 90 degrees.

When the third selector 240 selects the second feed line 260, and the second selector 230 selects the fourth feeding point 214, the signal of the feed line 270 receives the first signal. The second feeding line 260 and the fourth feeding point 214 flows to the patch radiator 210. In this case, the output phase of the patch radiator may have a phase of 270 degrees.

The antenna according to the present embodiment uses one patch radiator, but may have different output phases by the operation of the first to third selectors. Therefore, since the phase shifter is not used to adjust the beam output of the antenna, the antenna can be miniaturized.

3 is a configuration diagram of an antenna system in which a plurality of patch antennas is arranged according to an embodiment of the present invention.

Referring to FIG. 3, the patch antenna system according to the present exemplary embodiment may be formed by arranging the patch antennas illustrated in FIG. 2 by 4 × 4.

In the present exemplary embodiment, a power divider may be used to arrange 4 × 4 patch antennas and supply power having the same magnitude and phase to each patch antenna. The spacing between each of the arranged patch antennas may be arranged at λ / 2.

Each of the patch antennas requires four feed lines, but in the array antenna, the feed lines may be arranged in a space between the arranged antennas. Therefore, the physical size of the antenna system can be reduced.

Although the arrangement of 4 × 4 is illustrated in the present embodiment, the arrangement of the antenna may be variously implemented.

4 is a configuration diagram of an antenna system in which a plurality of patch antennas according to another embodiment of the present invention is arranged.

Referring to FIG. 4, in the patch antenna system according to the present embodiment, a plurality of patch antennas may be arranged, and a plurality of feed lines capable of supplying power of different phases to each of the arranged patch antennas may be formed.

In the present embodiment, the first to fourth feed lines for supplying power of different phases to each of the plurality of patch radiators including the first patch radiator 410a and the second patch radiator 410b may be connected. The second feed line 461 and the fourth feed line 462 connected to the first patch radiator 410a may be connected to one selector 440. In addition, the first feed line 453 and the third feed line 454 connected to the second patch radiator 410b may be connected to the selection unit 440. The selector 440 may select one of the plurality of feed lines 461, 462, 453, and 454 to connect to the external feed line 470.

In this embodiment, since one selector is shared to select one of the feed lines connected to different radiators, the antenna system can be miniaturized.

5 is a configuration diagram of a patch antenna 500 according to still another embodiment of the present invention.

Referring to FIG. 5, the patch antenna 500 according to the present embodiment includes a patch radiator 510, first to fourth feeding points 511, 512, 513, and 514, and first to fourth feed lines 551. , 552, 561, 562, selectors 540, and dielectric sheets 501, 502.

The patch antenna according to the present embodiment can be manufactured by the LTCC process.

The patch radiator 510 may be formed on the first dielectric sheet 501, and the first to fourth feed lines 551, 552, 561, and 562 and the selection unit 540 may be formed on the second dielectric sheet 502. Can be formed.

First to fourth feeding points 511, 512, 513, and 514 may be formed in the patch radiator 510.

When the same power is supplied to the first feeding point 511 and the third feeding point 513, the phase of the signal output from the patch radiator 510 may be the same. In this embodiment, the 1st feeding point 511 and the 3rd feeding point 513 can be formed in the symmetrical area | region in the rectangular patch radiator 510, respectively.

When the same power is supplied to the first feeding point 511 and the second feeding point 512, the phase of the signal output from the patch radiator 510 may be 180 degrees out of phase. In this embodiment, the 1st feeding point 511 and the 2nd feeding point 512 can be formed in the area | region which is vertically symmetrical in the rectangular patch radiator 510, respectively.

When the same power is supplied to the third feeding point 513 and the fourth feeding point 514, the phase of the signal output from the patch radiator 510 may have a phase difference of 180 degrees. In the present embodiment, the third feeding point 513 and the fourth feeding point 514 can be formed in the vertically symmetrical area in the rectangular patch radiator 510.

The first to fourth feeding points 511, 512, 513, and 514 may be connected to the first to fourth feed lines 551, 552, 561, and 562 by conductive via holes penetrating through the first dielectric sheet, respectively. Can be.

The first feed line 551 and the second feed line 552 may have the same electrical length. The third feed line 561 and the fourth feed line 562 may have the same electrical length. The first feed line 551 and the third feed line 561 may have different electrical lengths. In the present exemplary embodiment, the first feed line 551 and the second feed line 552 may be formed to have an electrical length λ / 4 longer than that of the third feed line 261 and the fourth feed line 262. . That is, when a signal having the same phase is applied, a phase difference of 90 degrees may occur between a signal output through the first feed line and a signal output through the third feed line.

The selector 540 selects one of the first feed line 551, the second feed line 552, the third feed line 561, and the fourth feed line 562 to select an external feeder. Can connect

The characteristics of the patch antenna are changed by the operation of the selector 540. That is, when the selector 540 selects the first feed line 551, the output phase of the patch radiator 510 may be 0 degrees. When the selector 540 selects the third feed line 561, the output phase of the patch radiator 510 may be 90 degrees. When the selector 540 selects the second feed line 552, the output phase of the patch radiator 510 may be 180 degrees. When the selector 540 selects the fourth feed line 562, the output phase of the patch radiator 510 may be 270 degrees.

As such, beam adjustment of the antenna may be possible by adjusting the feeding position and the length of the feeding line in order to change a phase of a signal applied to one radiator. Since no phase shifter is used, the antenna can be miniaturized.

It is intended that the invention not be limited by the foregoing embodiments and the accompanying drawings, but rather by the claims appended hereto. Accordingly, various forms of substitution, modification, and alteration may be made by those skilled in the art without departing from the technical spirit of the present invention described in the claims, which are also within the scope of the present invention. something to do.

1 is a configuration diagram of a patch antenna according to an embodiment of the present invention.

2 is a configuration diagram of a patch antenna according to another embodiment of the present invention.

3 is a block diagram of an antenna system according to an embodiment of the present invention.

4 is a configuration diagram of an antenna system according to another embodiment of the present invention.

5 is a configuration diagram of a patch antenna according to still another embodiment of the present invention.

<Code Description of Main Parts of Drawing>

110: patch radiator 111: first feeding point

112: second feeding point 140: selection unit

150: feed line

Claims (25)

delete delete delete delete Patch radiators including first to fourth feeding points; A first feed line having a preset electrical length; A second feed line having an electrical length different from that of the first feed line; A first selector which selects the first feeding point or the second feeding point and connects the first feeding line; A second selector which selects the third feeding point or the fourth feeding point and connects the second feeding line; And A third selector which selects the first feed line or the second feed line and connects the external feeder Patch antenna comprising a. The method of claim 5, The first feeding point and the third feeding point, And the patch radiator is a feeding position for generating output of the same phase when the same power is supplied. The method of claim 6, The first feeding point is formed in one region of the patch radiator, The third feeding point is a patch antenna, characterized in that formed in the region symmetrical with the first feeding point in the patch radiator. The method of claim 5, The first feeding point and the second feeding point, And the patch radiator is a feeding position for generating outputs of different phases when the same power is supplied. The method of claim 8, An output phase generated when power is supplied to the first feeding point, The phase difference of the output phase generated when the power is fed to the second feeding point is a patch antenna, characterized in that 180 degrees. 10. The method of claim 9, The first feeding point and the second feeding point, Patch antennas, characterized in that formed in each of the up and down symmetrical points in the patch radiator. The method of claim 5, The third feeding point and the fourth feeding point, And the patch radiator is a feeding position for generating outputs of different phases when the same power is supplied. The method of claim 11, An output phase generated when power is supplied to the third feeding point; The patch antenna, characterized in that the phase difference of the output phase generated when the power supply to the fourth feeding point is 180 degrees. The method of claim 12, The third feeding point and the fourth feeding point, Patch antennas, characterized in that formed in each of the up and down symmetrical points in the patch radiator. The method of claim 5, The first feed line and the second feed line, The patch antenna having an electrical length for generating a phase difference of 90 degrees with respect to the feed signal of the same phase. Patch radiators including first to fourth feeding points; A first feed line connected to the first feeding point; A second feed line connected to the second feeding point and having the same electrical length as the first feed line; A third feed line connected to the third feeding point and different in electrical length from the first feed line; A fourth feed line connected to the fourth feeding point and having the same electrical length as the third feed line; And Selector for selecting one of the first to fourth feed line to connect to the external feeder Patch antenna comprising a. The method of claim 15, The first feeding point and the third feeding point, And the patch radiator is a feeding position for generating output of the same phase when the same power is supplied. The method of claim 16, The first feeding point is formed in one region of the patch radiator, The third feeding point is a patch antenna, characterized in that formed in the region symmetrical with the first feeding point in the patch radiator. The method of claim 15, The first feeding point and the second feeding point, And the patch radiator is a feeding position for generating outputs of different phases when the same power is supplied. The method of claim 18, An output phase generated when power is supplied to the first feeding point, The phase difference of the output phase generated when the power is fed to the second feeding point is a patch antenna, characterized in that 180 degrees. The method of claim 19, The first feeding point and the second feeding point, Patch antennas, characterized in that formed in each of the up and down symmetrical points in the patch radiator. The method of claim 15, The third feeding point and the fourth feeding point, And the patch radiator is a feeding position for generating outputs of different phases when the same power is supplied. The method of claim 21, An output phase generated when power is supplied to the third feeding point; The patch antenna, characterized in that the phase difference of the output phase generated when the power supply to the fourth feeding point is 180 degrees. The method of claim 22, The third feeding point and the fourth feeding point, Patch antennas, characterized in that formed in each of the up and down symmetrical points in the patch radiator. 16. The method of claim 15, The first feed line and the third feed line, The patch antenna having an electrical length for generating a phase difference of 90 degrees with respect to the feed signal of the same phase. 16. The method of claim 15, A dielectric layer in which the patch emitter is formed; And And further comprising another dielectric layer in which the first to fourth feed lines and the selector are formed. And the first to fourth feeding lines and the first to fourth feeding points are connected by conductive via holes, respectively.

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