KR101780072B1 - Method and apparatus for adjusting horizontal beam of omni-dorectional antenna - Google Patents

Abstract

A horizontal beam correction method and apparatus for correcting a horizontal beam of an omnidirectional antenna is provided. The horizontal beam correction apparatus can generate a switch control signal based on the slope of the antenna. Then, the radiation direction of the antenna can be corrected according to the generated switch control signal. Then, the radiation direction of the calibrated antenna may have an omnidirectionality in the horizontal direction with respect to the horizontal plane.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a horizontal beam correcting method and a horizontal beam correcting method for an omni-directional antenna,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for controlling the radial direction of an omnidirectional antenna attached to a terminal forming a mobile communication, a wireless communication, or a sensor network.

2. Description of the Related Art In general, a terminal used in mobile communication, small-power wireless communication, sensor network, etc. performs communication using an omni-directional small antenna. An omni-directional antenna can radiate radio waves with the same intensity in all directions along a horizontal plane. At this time, when the omnidirectional antenna is installed perpendicularly to the horizontal plane, the omnidirectional antenna has a characteristic capable of radiating radio waves within a specific beam width. Accordingly, when the antenna or the terminal to which the antenna is attached is not installed vertically with respect to the horizontal plane, the radiation direction of the antenna may not have an omni-directional characteristic.

1 is a view showing a radiation pattern of an omnidirectional antenna vertically installed on a horizontal plane.

According to Fig. 1, an omni-directional antenna 102 may be attached to the terminal 101. Fig. Then, the terminal 101 can be installed on the ground plane 103. At this time, the omnidirectional antenna 102 may be perpendicular to the ground plane 103. Then, the radial direction 104 of the omnidirectional antenna may be formed horizontally with the ground plane 103. As such, when the radial direction 104 is formed horizontally with the horizontal plane 103, the omnidirectional antenna 102 can have an omnidirectional characteristic by radiating radio waves at the same intensity along the horizontal plane 103.

2 is a view showing a radiation pattern of an antenna provided on an inclined plane.

2, the terminal 201 to which the omnidirectional antenna 202 is attached may be installed on the sloping surface 201. The radial direction 203 of the omni-directional antenna can then be tilted relative to the ground plane 204.

As described above, when the radiation direction of the omni-directional antenna is inclined, the gain of the radio wave in the horizontal direction decreases, and the reflected wave due to the horizontal plane can increase. Accordingly, the omnidirectional characteristic of the omnidirectional antenna decreases, and performance deterioration may occur.

Therefore, even if the omnidirectional antenna is installed on the sloped surface, there is a need for a technique capable of reducing the performance deterioration of the omnidirectional antenna.

The present invention provides a technique for reducing the performance deterioration of the antenna by correcting the radiation direction of the antenna based on the slope of the antenna calculated on the basis of the horizon plane.

In addition, the present invention provides a technique for improving the communication performance by making the radial direction of the antenna have an omnidirectionality in the horizontal direction with respect to the horizontal plane.

The horizontal beam correction method according to an embodiment of the present invention may include generating a switch control signal based on the slope of the antenna, and correcting the radiation direction of the antenna in accordance with the switch control signal.

The step of correcting the radial direction of the antenna further comprises the steps of shorting or opening at least one switch in accordance with the switch control signal and adjusting the radial direction of the antenna so that the at least one switch is tilted in the short- .

The step of generating the switch control signal may include the steps of determining whether the switch is short-circuited or open using the slope of the antenna and a predetermined threshold value, and determining whether at least one of the short- And generating the switch control signal including the switch control signal.

The step of generating the switch control signal may include obtaining a gravity value of each axis by using a tilt sensor, and calculating a slope of the antenna using the obtained gravity value of each axis .

A horizontal beam correcting apparatus according to an embodiment of the present invention includes a control signal generating unit for generating a switch control signal based on an inclination of an antenna and a correcting unit for correcting a radiation direction of the antenna in accordance with the switch control signal .

The correction unit may include a parasitic element for correcting the radiation direction of the antenna through coupling with the radiator, a switch for connecting the parasitic element to the ground unit in accordance with the switch control signal, and a switch for connecting the parasitic element and the ground unit And an impedance matching unit for adjusting the impedance value.

The switch may be located between the parasitic element and the ground.

The impedance matching portion may be located between the parasitic element and the grounding portion.

Further, the impedance matching section may be located between the switch and the grounding section. At this time, one end of the switch is connected to the impedance matching part, and the other end of the switch can be connected to the parasitic element.

The switch may be located between the impedance matching portion and the grounding portion. At this time, one end of the switch may be connected to the impedance matching portion, and the other end of the switch may be connected to the grounding portion.

The apparatus may further include a tilt sensor for calculating the slope of the antenna with respect to the horizontal plane.

According to the present invention, performance degradation of the antenna can be reduced by correcting the radial direction of the antenna based on the inclination of the antenna calculated on the basis of the horizontal plane.

Further, the present invention can improve the communication performance by making the radiating direction of the antenna have the omnidirectionality in the horizontal direction with respect to the horizontal plane.

1 is a view showing a radiation pattern of an omnidirectional antenna vertically installed on a horizontal plane.
2 is a view showing a radiation pattern of an antenna provided on an inclined plane.
3 is a flowchart illustrating a method of correcting a horizontal beam of an omnidirectional antenna according to an exemplary embodiment of the present invention.
4 is a view for explaining a method of correcting a radial direction of an antenna provided on an inclined surface inclined to the right according to an embodiment of the present invention.
5 is a view for explaining a method of correcting a radial direction of an antenna provided on an inclined surface inclined to the left according to an embodiment of the present invention.
FIG. 6 is a view for explaining a method of correcting the radiation direction of an antenna installed on a horizontal plane according to an embodiment of the present invention.
FIG. 7 is a block diagram illustrating a detailed configuration of a horizontal beam correction apparatus according to an exemplary embodiment of the present invention. Referring to FIG.
FIG. 8 is a diagram illustrating a first embodiment of a horizontal beam correction apparatus including a plurality of pairs of correction units according to an embodiment of the present invention.
FIG. 9 is a diagram illustrating a second embodiment of a horizontal beam correction apparatus including a plurality of pairs of correction units according to an embodiment of the present invention.
10 is a diagram illustrating a structure in which parasitic elements are arranged in a circular shape in a horizontal beam correcting apparatus according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible. In addition, the same reference numerals shown in the drawings denote the same members.

3 is a flowchart illustrating a method of correcting a horizontal beam of an omnidirectional antenna according to an exemplary embodiment of the present invention. In Fig. 3, the horizontal beam correction method can be performed by the horizontal beam correction apparatus. For example, as the horizontal beam correcting apparatus, a mobile communication terminal, a sensor node, a wireless terminal of small power, and the like can be used.

First, when the installation of the horizontal beam correcting apparatus having an antenna on the inclined plane or the horizontal plane is completed, the horizontal beam correction apparatus can initialize the tilt sensor and the like. At this time, the parameters used for calculating the slope of the antenna can also be initialized.

Then, in step 301, the tilt sensor can acquire the gravity value of each axis. Here, the tilt sensor is attached to the omni-directional antenna, and the omni-directional antenna can be attached to the horizontal beam correction device. At this time, a tilt sensor of two or more axes may be attached to the omni-directional antenna. For example, the tilt sensor may include at least one of an acceleration sensor of two or more axes, and a gravity sensor of two or more axes.

Then, in step 302, the tilt sensor can calculate the tilt of the antenna using the gravity value of each axis.

For example, when a horizontal beam correction device with an antenna is installed on an inclined plane, the tilt sensor can calculate the degree of tilting of the antenna with respect to the horizontal plane using the gravity value of each axis.

Then, in step 303, the horizontal beam correction apparatus can generate a switch control signal based on the slope of the antenna. At this time, the horizontal beam correcting apparatus can determine whether the switch is short-circuited or not by using the slope of the antenna and a preset threshold value. Then, the horizontal beam correcting apparatus can generate a switch control signal including at least one of a short-circuit signal and an open signal based on the determination.

Next, in step 304, the horizontal beam correcting device can correct the radiation direction of the antenna by shorting or opening at least one switch according to the switch control signal. At this time, the radiation direction of the antenna can be corrected so that the switch is inclined in the short-circuit direction.

4 is a view for explaining a method of correcting a radial direction of an antenna provided on an inclined surface inclined to the right according to an embodiment of the present invention.

4, when the horizontal beam correction device 451 with the omnidirectional antenna 450 is installed on the inclined surface 452 inclined to the right, the tilt sensor installed on the omnidirectional antenna 450 calculates the inclination of the antenna .

The omnidirectional antenna 450 includes a pair of parasitic elements 403 and 407 around the radiator 401, a pair of impedance matching portions 404 and 409, a pair of switches 405 and 408, And may include a pair of grounding portions 406 and 410. Then, the horizontal beam correcting apparatus can determine whether each switch is short-circuited or open by using the slope and the threshold value of the antenna.

For example, if the slope of the antenna is greater than or equal to the threshold value, the horizontal beam correction apparatus can confirm that the omnidirectional antenna is installed at an inclined plane. In other words, since the radiation direction of the antenna is inclined in the horizontal beam correcting device, it can be confirmed that correction is necessary in the radiation direction. Then, when the inclined surface is inclined to the right, the horizontal beam correcting device short-circuits the switch 1 (405) located on the left side of the radiator 401 and opens the switch 2 (409) located on the right side of the radiator 401 You can decide.

Then, the horizontal beam correction apparatus can generate a switch control signal including a short-circuit signal for switch 1 (405) and an open signal for switch 2 (409). Then, the horizontal beam correcting device can short-circuit the switch 1 (405) in accordance with the switch control signal to connect the parasitic element 1 (403) and the impedance matching part 1 (404) to the ground part 1 (406). At this time, as the switch 1 405 is short-circuited, the coupling between the radiator 401 and the parasitic element 1 403 can be strengthened. Thus, the horizontal beam correcting device corrects the radiation direction so that the radiation direction 411 of the antenna is tilted in the direction in which the switch 1 405 and the switch 2 409 out of the switch 2 409 are short- can do. In other words, the horizontal beam correcting device can correct the radial direction 453 of the antenna to be inclined toward the inclined surface 452. Thus, the radiated direction 453 of the calibrated antenna may have an omnidirectional propagation characteristic in the horizontal direction with respect to the horizon plane 454.

5 is a view for explaining a method of correcting a radial direction of an antenna provided on an inclined surface inclined to the left according to an embodiment of the present invention.

5, when the horizontal beam correction device 551 with the omnidirectional antenna 550 is installed on the sloped surface 552 tilted to the left, the tilt sensor installed on the omnidirectional antenna 550 calculates the tilt of the antenna .

The omnidirectional antenna 550 includes a pair of parasitic elements 502 and 506 around the radiator 501, a pair of impedance matching portions 503 and 507, a pair of switches 504 and 508, And may include a pair of ground portions 505 and 509. Then, the horizontal beam correcting apparatus can determine whether each switch is short-circuited or open by using the slope and the threshold value of the antenna.

For example, if the slope of the antenna is greater than or equal to the threshold value, the horizontal beam correction apparatus can confirm that the omnidirectional antenna is installed at an inclined plane. As a result, it can be confirmed that the horizontal beam correcting apparatus requires correction in the radiation direction. Then, when the inclined surface is inclined to the left, the horizontal beam correcting device short-circuits the switch 2 508 located on the right side of the radiator 501 and opens the switch 1 504 located on the left side of the radiator 501 You can decide.

The horizontal beam correcting device can then generate a switch control signal including a short signal for switch 2 508, an open signal for switch 1 508, Then, the horizontal beam correcting device can short-circuit the switch 2 508 in accordance with the switch control signal to connect the parasitic element 2 506 and the impedance matching portion 2 507 to the grounding portion 2 509. At this time, as the switch 2 508 is short-circuited, the coupling between the radiator 501 and the parasitic element 2 506 can be strengthened. As such, the horizontal beam correction apparatus can correct the radiation direction so that the radiation direction 510 of the antenna is tilted in the direction in which the switch 1 504 and the switch 2 508 out of the switch 2 508 are short- can do. In other words, the horizontal beam correcting device can correct the radial direction 553 of the antenna to be inclined toward the inclined surface 552. Accordingly, the radiation direction 553 of the corrected antenna can have the omnidirectional propagation characteristic in the horizontal direction with respect to the ground plane 554. [

FIG. 6 is a view for explaining a method of correcting the radiation direction of an antenna installed on a horizontal plane according to an embodiment of the present invention.

6, when the horizontal beam correction device 651 with the omnidirectional antenna 650 is mounted on the horizontal plane 652, the tilt sensor installed on the omnidirectional antenna 650 can calculate the tilt of the antenna. In other words, the omnidirectional antenna 650 may be perpendicular to the ground plane 652.

At this time, the omni-directional antenna 650 includes a pair of parasitic elements 602 and 606, a pair of impedance matching portions 603 and 607, a pair of switches 604 and 608, And may include a pair of ground portions 605 and 609. Then, the horizontal beam correcting apparatus can determine whether each of the paired switches is short-circuited or open by using the slope and the threshold value of the antenna.

For example, if the slope of the antenna is less than a threshold as the omnidirectional antenna is perpendicular to the horizontal plane 652, the horizontal beam correction device can confirm that the omni-directional antenna is installed on a non-tilted plane. Then, the horizontal beam correcting apparatus can decide to open both the switch 1 604 located on the left side of the radiator 601 and the switch 2 608 located on the right side.

The horizontal beam correction apparatus may then generate a switch control signal comprising an open signal for switch 1 604 and an open signal for switch 2 608. Then, the horizontal beam correcting apparatus can open both switch 1 604 and switch 2 608 in accordance with the switch control signal. Thus, the horizontal beam correcting apparatus can not correct the radiation direction of the antenna. In other words, when the omnidirectional antenna 650 and the horizontal plane 652 are perpendicular to each other, since the radiation direction 653 of the antenna has an omnidirectional propagation characteristic in the horizontal direction with respect to the horizontal plane 652, May not correct the radiation direction of the antenna.

4 to 6, the switch and the impedance matching section are located between the parasitic element and the ground section, one end of the switch is connected to the impedance matching section, the other end of the switch is connected to the ground section, and one end of the impedance matching section is connected to the parasitic element And the other end of the impedance matching portion is connected to the switch. In other words, the parasitic element, the impedance matching portion, the switch, and the ground portion are connected in this order.

At this time, the connection positions of the switch and the impedance matching portion can be changed to each other. In other words, the parasitic element, the switch, the impedance matching portion, and the ground portion may be connected in this order. One end of the switch is connected to the parasitic element, the other end of the switch is connected to the impedance matching part, one end of the impedance matching part is connected to the switch, and the other end of the impedance matching part is connected to the grounding part. As such, since the switch and the impedance matching portion are located between the parasitic element and the ground portion, the horizontal beam correcting device can correct the radiation direction of the antenna by shorting or opening the switch.

FIG. 7 is a block diagram illustrating a detailed configuration of a horizontal beam correction apparatus according to an exemplary embodiment of the present invention. Referring to FIG.

7, the horizontal beam correcting apparatus 700 may include a tilt sensor 701, a control signal generating unit 702, and a correcting unit 703.

First, the tilt sensor 701 can calculate the slope of the antenna by acquiring the gravity value of each axis. At this time, the tilt sensor 701 can calculate the tilt of the antenna with respect to the horizontal plane. For example, as the tilt sensor 701, an acceleration sensor of two or more axes and a gravity sensor of more than two axes may be used.

The control signal generator 702 can generate a switch control signal based on the slope of the antenna. At this time, the control signal generator 702 can determine whether each switch is short-circuited or open by using a preset threshold value of the slope of the antenna. The control signal generator 702 can generate a switch control signal including at least one of a short-circuit signal and an open signal based on the determination.

For example, when the antenna is disposed on an inclined sloped surface to the left, the switch 1 is located on the left side of the radiator and the switch 2 is located on the right side of the radiator, and the slope of the antenna is greater than a predetermined threshold value, May generate a switch control signal comprising an open signal for switch 1, and a shorting signal for switch 2.

Then, the corrector 703 can correct the radiation direction of the antenna according to the switch control signal. At this time, the correcting unit 703 can correct the radial direction of the antenna so that at least one switch is tilted in the short-circuit direction. Accordingly, the radiation direction of the corrected antenna can have an omnidirectionality in the horizontal direction with respect to the horizontal plane.

In one example, the corrector 703 can short-circuit the switch 705 in accordance with the switch control signal. Then, as the switch 705 is short-circuited, the impedance matching portion 706 and the parasitic element 704 can be connected to the grounding portion 707. Accordingly, the coupling between the parasitic element 704 and the radiator can be strengthened. Then, the radiation direction of the antenna can be corrected so that the switch tilts in the short-circuited direction. In other words, the corrector 703 can correct the radiation direction so that the radiation direction of the antenna is inclined toward the inclined plane. Accordingly, the radiation direction of the corrected antenna can have an omnidirectionality in the horizontal direction with respect to the horizontal plane.

As described above, the switch 705 can be turned on according to the switch control signal to connect the parasitic element 704 to the grounding unit 707. [ The parasitic element 704 can then couple with the radiator to correct the radial direction of the antenna. At this time, the impedance matching unit 706 can adjust the impedance value between the parasitic element 704 and the grounding unit 707.

FIG. 8 is a diagram illustrating a first embodiment of a horizontal beam correction apparatus including a plurality of pairs of correction units according to an embodiment of the present invention.

8, the horizontal beam correcting apparatus 800 may include a plurality of correction units forming a pair with the radiator 901 as a center. For example, the horizontal beam correcting apparatus 800 may include a pair of the corrector 1 (805), and a pair of the corrector 2 (806). At this time, each of the correction units may include a parasitic element, a switch, an impedance matching unit, and a ground unit. For example, the correction unit 4 may include a parasitic element 4 807, a switch 4 808, an impedance matching unit 4 809, and a ground unit 4 810. Here, the operation of the correcting unit is the same as that of the correcting unit of FIG. 8, and a duplicate description will be omitted.

The control signal generation unit 804 may generate a switch control signal including a short or an open signal for each of the switches by the time of the slope of the antenna calculated by the tilt sensor 803. [

For example, when the antenna is provided on an inclined slant to the left, the control signal generator 804 short-circuits both the switch 1 811 and the switch 2 812 on the basis of the inclination of the antenna, And switch 2 (812). At this time, when it is determined to short-circuit the switch 1 811, the control signal generator 804 generates a short-circuit signal for the switch 1 811, an open signal for the switch 2 812, Signal, and an open signal to switch 4 (808). Then, as the coupling between the parasitic element 1 (814) and the radiator 810 is strengthened, the radiation direction of the radiator can be corrected to be inclined in the direction in which the shorted switch 1 (811) is located.

FIG. 9 is a diagram illustrating a second embodiment of a horizontal beam correction apparatus including a plurality of pairs of correction units according to an embodiment of the present invention.

The horizontal beam correcting apparatus of FIG. 9 is a diagram showing a case where the positions of the switch and the impedance matching unit are changed from each other in the horizontal beam correcting apparatus of FIG. In Fig. 9, the switch and the impedance matching portion may be located between the parasitic element and the grounding portion, as in Fig. Accordingly, when the switch is short-circuited in the structure in which the positions of the switch and the impedance matching unit are changed from each other, the parasitic element can enhance the radiator and the coupling to correct the radiation direction of the antenna. Accordingly, the radiation direction of the corrected antenna can have an omnidirectionality in the horizontal direction with respect to the horizontal plane.

10 is a diagram illustrating a structure in which parasitic elements are arranged in a circular shape in a horizontal beam correcting apparatus according to an embodiment of the present invention.

According to Fig. 10, the parasitic elements can be arranged in a circle around the radiator 1001. [ In this way, when the parasitic elements are arranged in a circle, the horizontal beam correction apparatus can determine whether or not each switch is short-circuited or open according to the slope of the antenna. At this time, when it is determined that the switch 1 1004 and the switch 2 1005 are to be short-circuited, the horizontal beam correcting device short-circuits the switch 1 1004 and the switch 2 1005 to form the parasitic element 1 1002 and the parasitic element 2 The coupling between the radiator 1003 and the radiator 1001 can be enhanced. Accordingly, the horizontal beam correction apparatus can correct the radiation direction so that the radiation direction of the antenna is inclined in the direction in which the switch 1 1004 and the switch 2 1005 are short-circuited. In other words, the horizontal beam correction apparatus can correct the radiation direction of the antenna to be inclined between the parasitic element 1 (1002) and the parasitic element 2 (1003).

Up to now, correction of the radiation direction of the antenna based on the tilt of the antenna has been described. At this time, the horizontal beam correction apparatus may continuously monitor the tilt sensor to correct the radiation direction of the corrected antenna according to the tilt of the updated antenna.

For example, when the horizontal beam correction device with the directional antenna is moved or rearranged, the external environment in which the antenna is installed may be changed to change the tilt of the antenna. Accordingly, the horizontal beam correction apparatus can monitor the tilt sensor to confirm that the antenna tilt has changed. Then, the horizontal beam correcting device can regenerate the switch control signal based on the slope of the changed antenna. Next, the horizontal beam correcting device can correct the radial direction of the antenna by controlling the opening and shorting of each switch in accordance with the regenerated switch control signal.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

Claims (19)

Generating a switch control signal based on the slope of the antenna; And
And correcting the radiation direction of the antenna according to the switch control signal,
The step of correcting the radiation direction of the antenna comprises:
Wherein the radiation direction of the antenna is corrected using a coupling between a radiator and a parasitic element generated according to the switch control signal. The method according to claim 1,
The step of correcting the radiation direction of the antenna comprises:
Shorting or opening at least one switch according to the switch control signal; And
Correcting the radiation direction of the antenna such that the at least one switch is tilted in a shorted direction
And correcting the horizontal beam. The method according to claim 1,
Wherein the step of generating the switch control signal comprises:
Determining whether a switch is short-circuited or open using a slope of the antenna and a preset threshold value; And
Generating the switch control signal including at least one of a short signal and an open signal based on the determination
And correcting the horizontal beam. delete The method according to claim 1,
Wherein the step of generating the switch control signal comprises:
Wherein the slope of the antenna is calculated based on the horizontal plane. Generating a switch control signal based on the slope of the antenna; And
And correcting the radiation direction of the antenna according to the switch control signal,
Wherein the step of generating the switch control signal comprises:
Obtaining a gravity value of each axis by using a tilt sensor; And
Calculating the slope of the antenna using the obtained gravity values of the respective axes
And correcting the horizontal beam. The method according to claim 1,
The step of correcting the radiation direction of the antenna comprises:
Wherein the correction is performed such that the radiation direction of the antenna is inclined toward an inclined surface in which the antenna is installed. 8. The method of claim 7,
The antenna includes:
Directional antenna. A control signal generator for generating a switch control signal based on the slope of the antenna; And
And a correcting unit for correcting a radiation direction of the antenna according to the switch control signal,
Lt; / RTI >
Wherein,
And corrects the radiation direction of the antenna by coupling between the radiator and the parasitic element generated according to the switch control signal. 10. The method of claim 9,
Wherein,
And corrects the radiation direction of the antenna so that at least one of the switches is tilted in a short-circuited direction. 10. The method of claim 9,
Wherein the control signal generator comprises:
And a switch control signal generating circuit for generating a switch control signal including at least one of a short-circuit signal and an open signal based on the determination, based on a slope of the antenna and a preset threshold value, Beam correction device. delete A control signal generator for generating a switch control signal based on the slope of the antenna; And
And a correcting unit for correcting a radiation direction of the antenna according to the switch control signal,
Lt; / RTI >
Wherein,
A parasitic element for correcting the radiation direction of the antenna through coupling with the radiator;
A switch for connecting the parasitic element to a ground unit according to the switch control signal; And
An impedance matching unit for adjusting an impedance value between the parasitic element and the ground unit,
Wherein the horizontal beam correcting device comprises: 14. The method of claim 13,
Wherein the switch comprises:
A parasitic element disposed between the parasitic element and the ground,
The impedance matching unit includes:
Wherein the parasitic element is located between the parasitic element and the ground. 14. The method of claim 13,
The impedance matching unit includes:
And a grounding portion located between the switch and the grounding portion,
Wherein one end of the switch is connected to the impedance matching unit, and the other end of the switch is connected to the parasitic element. 14. The method of claim 13,
Wherein the switch comprises:
And an impedance matching portion located between the impedance matching portion and the ground portion,
Wherein one end of the switch is connected to the impedance matching unit, and the other end of the switch is connected to the grounding unit. 10. The method of claim 9,
A tilt sensor for calculating the tilt of the antenna with respect to the horizontal plane;
Further comprising: A control signal generator for generating a switch control signal based on the slope of the antenna;
A correcting unit correcting the radiation direction of the antenna according to the switch control signal; And
A tilt sensor for calculating the tilt of the antenna with respect to the horizontal plane;
Lt; / RTI >
Wherein the tilt sensor comprises:
An acceleration sensor of two or more axes, and a gravity sensor of two or more axes. 10. The method of claim 9,
Wherein,
And corrects the radiation direction of the antenna so as to be inclined toward an inclined surface in which the antenna is installed.

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