KR100994554B1 - Omni variable antenna - Google Patents

Abstract

The present invention relates to an omni-variable antenna, the omni antenna of a circular pole type for outputting electromagnetic waves of a predetermined radiation pattern, and at least two or more support members installed in the omni antenna to be rotatable about the longitudinal direction of the omni antenna And at least two reflecting plates connected to the supporting member and reflecting the electromagnetic wave output through the omni antenna as the supporting member rotates so that the radiation pattern of the electromagnetic wave is changed. According to the present invention, the shape of the electromagnetic radiation pattern can be variously changed by one omni antenna, and thus the optimum radiation pattern according to the region can be output.

Omni antenna, radiation pattern

Description

Omni variable antenna {OMNI VARIABLE ANTENNA}

The present invention relates to an antenna used in a mobile communication system, and more particularly, to an omni antenna having a constant directional variable characteristic.

In other words, the omni-directional antenna is also called an omni-directional antenna, and refers to an antenna in which electromagnetic waves are evenly radiated 360 degrees in the horizontal direction. In "Omni-directional", the word "Omni" is a prefix that means "everything." In other words, 'directional' means that the antenna has a directivity in a specific direction, it is prefixed with 'omni' means that electromagnetic waves are radiated in all directions.

That is, the term omnidirectional is used because electromagnetic waves are radiated in all directions without directivity. The most common ones are antennas for automobile radio reception or antennas for mobile communication terminals. Because it is impossible to predict which direction to move due to the characteristics of an automobile or a mobile terminal, electromagnetic waves are radiated in a horizontal omnidirectional direction by standing a vertical mono-pole antenna vertically.

Antennas are largely classified into omnidirectional antennas and directional antennas. Yagi antennas and patch antennas are used as directional antennas, and omni antennas are widely used as omnidirectional antennas.

As described above, the omni antenna is a circular pole type antenna in which electromagnetic waves are uniformly output in all directions, and isotropic in which electromagnetic waves are spread in a sphere shape up, down, left, and right. Unlike an isotropic antenna, it has an antenna characteristic in which electromagnetic waves are spread evenly to the side rather than up and down. That is, the omni antenna forms a so-called donut pattern, which is the most efficient beam pattern when used on the ground near the plane (electric pole installation and in an apartment complex).

However, the conventional omni antenna has a problem that the electromagnetic radiation pattern is fixed in a donut shape, so that one omni antenna cannot be adaptively applied to various types of electromagnetic radiation patterns. In other words, the omni antenna using the monopole element is structurally symmetrical, but the gain flatness may be good, but since it uses a single monopole element of 1/4 lambda (λ), the electromagnetic radiation pattern is changed according to the transmission service environment of the mobile communication system. There are technical limitations.

Accordingly, an object of the present invention is to provide an omni-variable antenna capable of outputting a variable radiation pattern corresponding to a transmission service environment for each region by variously changing the shape of the electromagnetic radiation pattern with one omni antenna.

According to a preferred embodiment of the present invention, a circular pole-shaped omni antenna for outputting electromagnetic waves of a predetermined radiation pattern, and at least installed in the omni antenna to be rotatable about the longitudinal direction of the omni antenna An omni-variable antenna comprising at least two supporting members and at least two reflecting plates connected to the supporting member and reflecting electromagnetic waves output through the omni antenna as the supporting member rotates to change the radiation pattern of the electromagnetic waves. to provide.

According to the present invention, it is possible to variously change the shape of the electromagnetic radiation pattern with one omni antenna, so that the optimum radiation pattern for each region can be variously implemented at low cost.

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

1A illustrates an omni-variable antenna according to an embodiment of the present invention, and includes an omni antenna 100, an upper support member 102a, a lower support member 102b, a first reflector 104a, and a second reflector 104b. Include. In this case, the omni variable antenna of FIG. 1a is a horizontal beam variable omni antenna, and the radiation pattern output through the omni antenna is a horizontal beam pattern.

As shown in FIG. 1A, the omni antenna 100 has a circular monopole shape, and resonates a high frequency signal input through a power supply connector (not shown) connected to an external cable to generate a predetermined radiation pattern. Outputs an electromagnetic wave having

The upper and lower support members 102a and 102b are installed in parallel with the upper and lower portions of the omni antenna 100 so as to be rotatable about the longitudinal direction of the omni antenna 100. In addition, the upper and lower support members 102a and 102b connect upper and lower portions of the first reflecting plate 104a and the second reflecting plate 104b, which will be described later.

The first reflecting plate 104a and the second reflecting plate 104b according to the present embodiment are connected to the upper supporting member 102a and the lower supporting member 102b and the upper supporting member 102a and the lower supporting member 102b. As it rotates to reflect the electromagnetic wave output through the omni antenna 100 serves to change the radiation pattern of the electromagnetic wave. That is, as can be seen in Figure 1a, the upper support member (102a) and the lower support member (102b) is characterized in that it is rotatable in the longitudinal direction of the omni antenna 100 in the axis.

At this time, in the present embodiment, the upper and lower support members 102a and 102b and the omni antenna 100 fit so that a user can easily grasp the rotation angles of the upper support member 102a and the lower support member 102b. A tick (e.g., in degrees) may be engraved on the bite to indicate the angle of rotation.

In addition, the first reflecting plate 104a and the second reflecting plate 104b are connected to the upper support member 102a and the lower support member 102b in parallel with the omni antenna 100 so that the upper support member 102a. ) And the distance can be moved along the lower support member (102b). That is, as can be seen in Figure 1a, on the inner surface of the upper support member 102a and the lower support member 102b, the first and second reflecting plates 104a and 104b are formed around the omni antenna 100. Rail-shaped grooves may be formed to move along the 102a and the lower support member 102b. In addition, the connection points of the first and second reflecting plates 104a and 104b of the upper and lower supporting members 102a and 102b to allow the user to know the moving distance of the first reflecting plate 104a and the second reflecting plate 104b. There may be engraved a scale (eg, mm) indicating the distance movement.

For example, as shown in FIG. 1B, the omni-variable antenna in FIG. 1A is a case where the rotation angle of the support member is set to 180 ° and the distance between the omni antenna 100 and the reflector plates 104a and 104b is set to 70 mm. . The shape of the horizontal beam pattern at this time is as illustrated in FIG. 1C, and the standing wave ratio at this time is as illustrated in FIG. 1D.

As shown in FIG. 1D, assuming that the entire frequency band of the omni variable antenna of the present embodiment is 1,885 MHz to 2,170 MHz, and based on the standing wave ratio 1: 1.4, the bandwidth in a specific frequency band among all frequency bands To satisfy.

Figure 2a is another embodiment of the omni variable antenna according to the present invention, each configuration is the same as Figure 1a.

For example, as shown in FIG. 2B, the omni-variable antenna in FIG. 2A is a case where the rotation angle of the support member is set to 60 ° and the distance between the omni antenna 100 and the reflector plates 104a and 104b is set to 70 mm. . The shape of the horizontal beam pattern at this time is as shown in Figure 2c, the standing wave ratio at this time is as shown in Figure 2d.

As can be seen from FIG. 2D, assuming that the entire frequency band of the omni-variable antenna in this embodiment is 1,885 MHz to 2,170 MHz, and based on the standing wave ratio 1: 1.4, the bandwidth in a specific frequency band among all frequency bands To satisfy.

FIG. 3A is another embodiment of the omni variable antenna according to the present invention, and each configuration is the same as that of FIG. 1A.

For example, as shown in FIG. 3B, the omni-variable antenna in FIG. 3A is a case where the rotation angle of the support member is set to 180 ° and the distance between the omni antenna 100 and the reflector plates 104a and 104b is set to 100 mm. . The shape of the horizontal beam pattern at this time is as illustrated in FIG. 3C, and the standing wave ratio at this time is as illustrated in FIG. 3D.

As can be seen in FIG. 3D, assuming that the entire frequency band of the omni variable antenna of the present embodiment is 1,885 MHz to 2,170 MHz, and based on the standing wave ratio 1: 1.25, the bandwidth in a specific frequency band among all frequency bands To satisfy.

4A illustrates another embodiment of the omni-variable antenna according to the present invention, and each configuration is the same as that of FIG. 1A.

For example, as shown in FIG. 4B, the omni-variable antenna in FIG. 4A is a case where the rotation angle of the support member is set to 60 ° and the distance between the omni antenna 100 and the reflector plates 104a and 104b is set to 100 mm. . The shape of the horizontal beam pattern at this time is as illustrated in FIG. 4C, and the standing wave ratio at this time is as illustrated in FIG. 4D.

As can be seen in FIG. 4D, assuming that the entire frequency band of the omni variable antenna of the present embodiment is 1,885 MHz to 2,170 MHz, and based on the standing wave ratio 1: 1.16, the bandwidth in a specific frequency band among all frequency bands To satisfy.

As described above, the present invention is implemented so that the optimum radiation pattern according to the region can be output by variously changing the shape of the electromagnetic radiation pattern using one omni antenna.

On the other hand, the embodiments of the present invention have been described in detail, but the present invention is not limited to these embodiments, and various types of embodiments, for example, rotation angles and intervals are set under different conditions to form different types of radiation patterns. It is of course possible to implement an omni variable antenna that can be carried. This will become clearer from the claims which follow.

The present invention is expected to contribute to the improvement of the quality of mobile communication service by reducing the cost and power loss and radio wave radiation efficiency by making the effect of changing the existing omni antenna to two sector antenna in the mobile communication service. .

1A to 1D illustrate an exemplary omni-variable antenna according to an embodiment of the present invention, in which a rotation angle of a support member is 180 ° and an interval of 70 mm between an omni antenna and a reflector is shown.

2a to 2d is an exemplary embodiment of the omni-variable antenna according to the present invention, the rotation angle of the support member 60 °, the distance between the omni antenna and the reflector 70mm,

3a to 3d is another embodiment of the omni-variable antenna according to the present invention, an example of the case of the rotation angle of the support member 180 °, the spacing between the omni antenna and the reflector 100mm,

Figures 4a to 4d is another embodiment of the omni-variable antenna according to the present invention, an exemplary view in the case of a rotation angle of 60 ° of the support member, 100mm spacing between the omni antenna and the reflector.

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

100: omni antenna

102a: upper support member 102b: lower support member

104a: first reflector 104b: second reflector

Claims (6)

Omni antenna of a circular pole type to output electromagnetic waves of a certain radiation pattern, At least two or more support members installed on the omni antenna to be rotatable about the omni-directional antenna; And at least two reflecting plates connected to the supporting member and reflecting the electromagnetic waves output through the omni antenna as the supporting member rotates to change the radiation pattern of the electromagnetic waves. The support member is formed of an upper support member and a lower support member respectively installed in parallel to the upper and lower portions of the omni antenna to connect the upper and lower portions of the reflecting plate, respectively. Omni adjustable antenna. The method of claim 1, The reflector is an omni-variable antenna, characterized in that connected to the support member in parallel with the omni antenna and the distance can be moved along the support member. delete The method according to claim 1 or 2, The omni variable antenna is an omni variable antenna, characterized in that the horizontal beam omni variable antenna. The method of claim 1, The omni variable antenna, characterized in that the upper support member is rotatable by a predetermined angle unit. The method of claim 1, An omni variable antenna, characterized in that the inner surface of the support member is formed with a rail-shaped groove so that the reflecting plate can move in the distance scale unit along the support member with respect to the omni antenna.

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