KR20160047326A - Antenna device capable of variable e-tilt by service band - Google Patents

Abstract

In feeding signals with shifted phases in two bands to a single input and output port, a first signal and a second signal not only can be transmitted and received through respective devices according to control from the outside but also can be transmitted through a single device, and power is distributed and provided to each of the devices. An antenna device according to the present invention comprises: multiple first devices and a single second device for transmitting and receiving a first signal; multiple third devices and a single fourth device for transmitting and receiving a second signal; a fifth device for transmitting and receiving the first signal or the second signal according to control from the outside; a first phase shifter for varying the vertical beam tilt of the antenna by controlling the phase of the first signal; a second phase shifter for varying the vertical beam tilt of the antenna by controlling the phase of the second signal; a first duplexer for separating a signal, which is transmitted from the outside, into the first signal and the second signal and transmitting the first signal to the first device and the second signal to the third device or combining the first signal and the second signal, of which the phases are controlled, and transmitting the first signal and the second signal to a first input and output port; a second duplexer for separating a signal, which is transmitted from the outside, into the first signal and the second signal and transmitting the first signal to the second device and the second signal to the fourth device or combining the first signal and the second signal, of which the phases are controlled, and transmitting the first signal and the second signal to the first input and output port; a third duplexer for separating a signal transmitted through the fifth device from the outside or a signal to be transmitted through the fifth device, into the first signal and the second signal and transmitting or receiving the first signal and the second signal through the fifth device; and a power distributing part for distributing and providing power to the first to fifth devices.

Description

Antenna device capable of variable e-tilt by service band

The present invention relates to a variable tilt antenna apparatus for each service band.

Generally, a broadband antenna is provided with a dedicated element array for each frequency band to be used. However, there is a problem in that characteristics of each band are not considered in beam tilt because a single displacement device is shared in the antenna system, and beam tilt is formed in a plurality of frequency bands in the same manner.

In order to solve this problem, an antenna device in which two dedicated antenna devices are attached to each other has been implemented. However, the size of the antenna is increased, and manufacturing and installation of the antenna are complicated and economically disadvantageous.

Accordingly, the present invention provides a variable tilt antenna device designed to adjust the electric beam tilt for each 3G / 4G service band.

According to an aspect of the present invention, there is provided an antenna apparatus including:

A plurality of first elements and a second element for transmitting and receiving a first signal for a first band; A plurality of third elements and a fourth element for transmitting and receiving a second signal for the second band; A fifth element for transmitting and receiving a first signal or a second signal according to an external control; A first phase shifter that connects the first element and the second element, respectively, and controls the phase of the first signal to vary the vertical beam tilt of the antenna; A second phase shifter that connects the third and fourth elements, respectively, and controls a phase of a second signal to vary a vertical beam tilt of the antenna; The first signal is divided into a first signal and the second signal is divided into a first signal and a second signal by dividing a signal transmitted from the outside into the first signal and the second signal, A first duplexer for combining the first signal and the second signal and transferring the phase-controlled first signal and the second signal to the first input / output port; Wherein the first signal and the second signal are connected to the first phase shifter and the second phase shifter, respectively, and the first signal and the second signal are divided into a first signal and a second signal, A second duplexer for combining the first signal and the second signal, the phase of which is controlled, and transmitting the combined signal to the first input / output port; A first phase shifter and a second phase shifter for separating a signal transmitted through the fifth element from the outside or a signal to be transmitted through the fifth element into a first signal and a second signal, The third duplexer transmitting or receiving through the fifth device; And a signal power distributor for distributing and providing power to the first to fifth elements.

The signal power dividing section includes: a power supply for supplying power to a plurality of elements and a duplexer; And a power divider dividing the power generated through the power supply in half and providing power distributed to the plurality of devices and the duplexer.

Wherein the power distributor distributes power corresponding to 50% of the power supplied from the power supply to the second device and the fourth device, respectively, and supplies power corresponding to the remaining 50% And the third device, respectively.

The first and second input / output ports may further include a first input / output port for receiving a signal combined with the first signal and the second signal and transferring the signal to the first duplexer or transmitting the signal to the outside.

A sixth element for transmitting and receiving a third signal to the third band; A third phase shifter connected to the sixth element and controlling a phase of a third signal to vary a vertical beam tilt of the antenna; And a second input / output port for transmitting a third signal to the third phase shifter or transmitting a third signal received from the third phase shifter to the outside.

According to the present invention, a compact design of the antenna device is possible.

In addition, since individual tilting can be performed separately for each service band, an optimized beam can be provided for each service band, and the service shadow area can be eliminated.

1 is a structural diagram of a general antenna system.
2 is a structural diagram of an antenna system according to an embodiment of the present invention.
3 is an internal structure diagram including an antenna system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another part in between .

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Hereinafter, a variable tilt antenna apparatus according to an embodiment of the present invention will be described with reference to the drawings. Prior to describing the practice of the present invention, a general antenna system will first be described with reference to FIG.

1 is a structural diagram of a general antenna system.

1, a general antenna system 10 is an apparatus for transmitting and receiving two frequency bands, and includes a first antenna 13 including first to third array elements 13-1 to 13-3, 13-1 to 13-N of the second antenna 14, the first antenna 13 and the second antenna 14 including the array elements 14-1 to 14-3 for the second frequency band, -3, and 14-1 to 14-3, respectively, for phase control of signals in corresponding frequency bands.

In this antenna system 10, the elements 13-1 to 13-3 and 14-1 to 14-3 of the first antenna 13 and the second antenna 14 for each band are arranged in a line, The beam tilt of each of the antennas 13 and 14 can be controlled independently or individually by controlling the phases of signals by the displacers 11 and 12 corresponding to the antennas 13 and 14. [ However, the antenna system 10 must have dedicated antennas 13 and 14 and array elements 13-1 to 13-3 and 14-1 to 14-3 for each frequency band.

That is, in order to provide services in the 900 MHz band and the 1800 MHz band by using the general antenna system 10, the dedicated antenna for the 900 MHz band and the dedicated antenna for the 1800 MHz band are attached to each other, The size of the scale will be significantly increased. This makes the fabrication and installation of the antenna device or the system complicated and economically very disadvantageous.

Therefore, in the embodiment of the present invention, LB (Low Band) (814 to 960 MHz) and HB (High Band) (1710 to 2200 MHz) can be used simultaneously through one antenna, and two HB And 4G) can be separately adjusted by using a separate phase shifter.

2 is a structural diagram of an antenna system according to an embodiment of the present invention.

2, an antenna system 100 according to an embodiment of the present invention includes a frequency-shared antenna 110 for transmitting and receiving signals in a plurality of frequency bands, And a plurality of phase shifters 120-1, 120-2, and 120-3 that vary the vertical beam tilt of the antenna 110 by controlling the phase shifters 120-1, 120-2, and 120-3.

The plurality of phase shifters may include a first phase shifter 120-1 for controlling the phase of a signal transmitted and received in a 4G band (for example, 1.8 GHz) and a second phase shifter 120-1 for controlling a phase of a 3G band (for example, 2.1 GHz) And a second phase shifter 120-2 for controlling the phase of signals transmitted and received in the second phase shifter 120-2. And a third phase shifter 120-3 for controlling the phase of a signal transmitted and received in a low frequency band such as 800 MHz or 900 MHz.

The antenna system 100 includes a signal power distribution unit 160 that provides signal power to each device or distributes the provided signal power according to a device of the antenna system 100. [

The frequency-shared antenna 110 includes a plurality of first array elements 111, 112a, 112b, 112c, 112d, and 112e for transmitting and receiving signals in two different service bands 3G and 4G and a signal in a low- . Here, some of the tandem array elements 112a, 112b, 112c, 112d, and 112e are elements having broadband characteristics, and elements having broadband characteristics are already known and will not be described in detail in the embodiments of the present invention. In the embodiment of the present invention, nine linear array elements for transmitting and receiving high frequency band signals and five linear array elements for transmitting and receiving low frequency band signals are shown as an example, but the present invention is not limited thereto.

A plurality of first linear array elements 112a and one second linear array element 112b among the elements provided in the frequency common antenna 110 are connected to a first phase shifter 120 -1). A plurality of fourth row array elements 112d and one fifth row array element 112e also each connect to a second phase shifter 120-2 which controls the phase of another high frequency band signal.

The plurality of sixth series array elements 111 are connected to the third phase shifter 120-3, which is a low frequency band displacement unit. Finally, one third row array element 112c is connected to the second duplexer 130-2 because it can transmit and receive signals in the 3G band or the 4G band through one array element.

As a result, signals of 2.1 GHz band (3G) and 1.8 GHz band (4G), which are two high frequency bands, are transmitted through one antenna system 100 to the first to seventh linear array elements 112a to 112e And can also transmit and receive signals in the low frequency band through the sixth row array element 111. [ In the embodiment of the present invention, two frequency bands of 2.1 GHz band and 1.8 GHz band are described as examples in the high frequency band, but the present invention is not limited thereto.

In addition, the first and second linear array elements 112a and 112b for the upper four rows of the first row array elements for processing the high-frequency signals are used to transmit and receive 4G signals, and the fourth row array elements 112a and the second row array elements 112b for the fourth The first array element 112d and the fifth array element 112e are used to transmit and receive 3G signals. And the center third row array element 112c is used to transmit and receive both the 3G signal and the 4G signal.

Here, the second linear array elements 112b and the fifth linear array elements 112e transmit / receive signals through a power of 50% of the electric power applied to the antenna system 100. [ The first tandem array element 112a and the fourth tandem array element 112d transmit / receive signals at a power of 20% or 5% of the power applied to the antenna system 100 depending on the position of the element.

The phase shifters 120-1, 120-2, and 120-3 control the phase of signals transmitted and received by the antenna 110 to vary the vertical beam tilt of the antenna 110. [ The first phase shifter 120-1 is dedicated to the 4G band, the second phase shifter 120-2 is dedicated to the 3G band, the third phase The transformer 120-3 is used for the low frequency band only.

That is, the first phase shifter 120-1 and the second phase shifter 120-2 include a second antenna knob 150-2 and a third antenna knob 150-2 for varying the high frequency vertical beam tilt, 3 and tilts the vertical beam so that the second antenna knob 150-2 and the third antenna knob 150-3 are adjusted by the user to adjust the service coverage of the 3G and 4G bands, respectively. Likewise, the third phase shifter 120-3 is connected to the first antenna knob 150-1 for varying the vertical beam tilt of the low frequency signal, and the first antenna knob 150-1) is adjusted, the vertical beam is tilted so that the service coverage of the low frequency is adjusted.

One side of the first phase shifter 120-1 is connected to the first duplexer 130-1 and the signal power distributor 160 and is connected to the antenna input / And is connected to the first input / output port 140-1 side. In addition, the opposite side of the first phase shifter 120-1 is connected in parallel to the first series array element 112a. One side of the first phase shifter 120-1 is connected to the third array element 112c via the third duplexer 130-3.

Similarly, one side of the second phase shifter 120-2 is connected to the first input / output port 140-1 via the first duplexer 130-1 and the signal power distributor 160. [ And the opposite side of the second phase shifter 120-2 is connected in parallel to the fourth tandem array element 112d. Further, one side of the second phase shifter 120-2 is connected to the third series array element 112c via the third duplexer 130-3.

In the case of the third row array element 112c, since signals of the 3G band and the signal of the 4G band can be transmitted and received, the first phase shifter 120-1 and the second phase shifter 120 -2) so that the phase of the transmission / reception signal can be controlled for each band.

One side of the third phase shifter 120-3 is connected to the second input / output port 140-2 and the other side of the third phase shifter 120-3 is connected to the sixth series array element 111 in parallel. Although the sixth row array element 111 is shown as including the first row array element 112a or the second row array element 112b or the like, the first row array element 112a or the second row array element 112b The second row array elements 112b and the like are not included in the sixth row array elements 111 but the two row array elements are physically separated from each other by a certain distance.

The third row array element 112c is connected to the first input / output port 140-1 through the second duplexer 130-2 and the signal power distributor 160. [ Similarly, the fifth row array element 112e is connected to the first input / output port 140-1 through the second duplexer 130-2 and the signal power distribution unit 160. [

As shown in FIG. 2, in the embodiment of the present invention, a single phase shifter of 3G and 4G is constituted by using one existing wideband device, and the tilt is simultaneously driven by one phase shifter, thereby separately operating the service coverage In order to solve the difficulty described below, the 3G phase shifter 120-2 and the 4G phase shifter 120-1 are separately included so that different services can be separately tilted.

The first duplexer 130-1 and the second duplexer 130-2 are connected to the first input / output port 140-1 and the first phase shifter 120-1 through the signal power distributor 160, And is connected to the phase shifter 120-2. That is, one side of the first duplexer 130-1 is connected to the signal power divider 160 and the other side is connected to the first phase shifter 120-1 and the second phase shifter 120-2. In parallel. One side of the second duplexer 130-2 is connected to the signal power distributor 160 and the other side of the second duplexer 130-2 is connected to the second linear array element 112b and the fifth linear array element 112e.

Accordingly, the signal input from the outside is separated into the 3G signal and the 4G signal in the high frequency band, and the signal is transmitted to the 3G second dedicated phase shifter 120-2 or the 4G dedicated first phase shifter 120-1 . Accordingly, it is possible to perform substantially one input and one output at the time of receiving or transmitting a signal, so that it is not necessary to provide a separate port for each frequency band in the antenna apparatus 100, Or transmitted.

The third duplexer 130-3 is arranged to be connected to the third row array element 112c and the first phase shifter 120-1 and the second phase shifter 120-2. That is, one side of the third duplexer 130-3 is connected to the third row array element 112c, and the other side is connected to the first phase shifter 120-1 and the second phase shifter 120-2 ) In parallel. Thus, the third series array device 112c can transmit and receive signals of the 3G band and the 4G band under the control of the first input / output port 140-1.

The first phase shifter 120-1, the second phase shifter 120-2 and the third phase shifter 120-3 are connected to the antenna knobs 150-1, 150-2 and 150-3, respectively. It is connected. The first antenna knob 150-1 adjusts the band for the low frequency signal. The second antenna knob 150-2 adjusts the band for the 3G signal and the third antenna knob 150-3 adjusts the band for the 4G signal. The function of the antenna knob is already known, and a detailed description thereof will be omitted in the embodiment of the present invention.

A method of transmitting and receiving signals through the antenna device 100 according to the embodiment of the present invention is as follows. Here, the signal transmitted / received is a signal of a high frequency band such as 3G or 4G.

In the case of signal transmission, first, when a transmission signal is input from the first input / output port 140-1, the first duplexer 130-1 transmits a signal received by the first input / output port 140-1 Separate into separate signals. And transmits the separated band-specific signals to the respective phase shifters 120-1 and 120-2. In the embodiment of the present invention, it is assumed that the first and second phase shifters 120-1 and 120-2 are separated into a 2.1 GHz band (3G) and a 1.8 GHz band (4G) and transmitted to the first phase shifter 120-1 and the second phase shifter 120-2, respectively Explain.

The signals of the separated bands are phase-controlled in the corresponding phase shifters 120-1 and 120-2. The signals whose phases are controlled in this manner are transmitted to the first to fifth array elements 112a to 112e and are radiated as radio waves. Here, when a signal is transmitted to the third duplexer 130-3, the signal is transmitted to the third row array element 112c and radiated as a radio wave. Since the phases are controlled independently by the dedicated phase shifters 120-1 and 120-2 for each frequency band, desired beam tilt can be obtained for each frequency band.

The case of transmitting a signal has been described above, and in the case of a received signal, the signal is processed in reverse to the transmitted signal. First, signals received by the first array elements 111, 112a, 112b, 112c, 112d, and 112e are transmitted to the phase shifters 120-1, 120-2, and 120-3 connected to the respective elements. The first tandem array element 112a and the second tandem array element 112b receive only the 4G signal and the fourth tandem array element 112d and the fifth tandem array element 112e receive only the 3G signal, Since the tandem array element 111 receives only signals in the low frequency band, it is not necessary to separately separate the received signals according to the bandwidth.

However, the third row array element 112c may receive both the 3G signal and the 4G signal. However, instead of simultaneously receiving the signals of the two bands, the third row array element 112c may receive signals of the 3G band under the control of the first input / output port 140-1 In the case of receiving only the 3G signal and receiving the 4G band signal, only the 4G signal is received. Therefore, it is not necessary to separately separate the received signal according to the bandwidth.

Each of the phase shifters 120-1 and 120-2 controls the phase of the signal received by the antenna element, and the phase-controlled 3G signal and the 4G signal are transmitted to the first duplexer 130-1 or the second duplexer 130-1 130-2, and then is received through the first input / output port 140-1.

As described above, the internal structure including the antenna system 100 for separately adjusting the service coverage of the 3G and 4D bands through the first input / output port 140-1, which is one high frequency reception port, . 3, it is possible to simultaneously transmit and receive a 3G signal and a 4G signal in the case of an intermediate element, that is, a third series array element 112c, which is a portion lacking in gain, while feeding a phase shifted signal of the 3G band and the 4G band to one port. And an antenna system 100 that manages power so as to be able to communicate with each other.

3 is an internal structure diagram including an antenna system according to an embodiment of the present invention.

As shown in FIG. 3, the first array elements 112a, 112b, 112c, 112d, and 112e shown at the top are the first array element 112a to the fifth array element 112e shown in FIG.

The duplexer 130-3 connected to one side of the third array element 112c corresponds to the third duplexer 130-3 of FIG. 2, and the phase shifter 130-3, which is connected to the first array element 112a, The phase shifter 120-1 connected to the first phase shifter 120-1 and the fourth array element 112d shown in FIG. 2 corresponds to the phase shifter 120-2 connected to the second phase shifter 120 -2), respectively.

The duplexer 130-1, to which the first phase shifter 120-1 and the second phase shifter 120-2 are connected, corresponds to the first duplexer 130-1 of FIG. 2, The duplexer to which the first array element 112b and the fifth array element 112e are connected corresponds to the second duplexer 130-2 of FIG.

The signal power divider 160 to which the first duplexer 130-1 and the second duplexer 130-2 are connected includes a power supply 161 and a power divider 162. [

The power supply 161 provides power to all components including the antenna system 100, and the form of the power provider 161 is not limited to any form.

The power divider 162 divides the magnitude of the power provided by the power supply 161 in half. Accordingly, the power applied to the first duplexer 130-1 and the second duplexer 130-2 can be reduced by half. Therefore, when the antenna system 100 is implemented as a PCB type, So that it is possible to reduce the manufacturing cost of the antenna.

For the power applied to each element, three fourth array elements 112d, one fifth array element 112e, and one third array element 112c will be described as an example. In the fifth row array device (1) in which all the 5 row array devices transmitting and receiving signals in the 3G band are shaded, power corresponding to 50% of the total power is distributed, and two row array devices (2 ), Respectively, the power for 20% is distributed. And the power of 5% is distributed to each of the two last array elements (3). By distributing the power in this manner, a desired pattern can be obtained for signal transmission, and a sidelobe that reduces efficiency by dispersing and radiating to a region other than the main radiation direction can be reduced.

For example, assuming that a total of 200 W of power is generated in the power supply 161, 100 W of power corresponding to 50% of the total power is distributed to the middle row array element (1), and two series arrays 40W power for 20% and 10W for 5% are distributed to the device (2), and total power of 200W (100W + 40W + 40W + 10W + 10W) to transmit and receive signals.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (7)

In the antenna device,
A plurality of first elements and a second element for transmitting and receiving a first signal for a first band;
A plurality of third elements and a fourth element for transmitting and receiving a second signal for the second band;
A fifth element for transmitting and receiving a first signal or a second signal according to an external control;
A first phase shifter that connects the first element and the second element, respectively, and controls the phase of the first signal to vary the vertical beam tilt of the antenna;
A second phase shifter that connects the third and fourth elements, respectively, and controls a phase of a second signal to vary a vertical beam tilt of the antenna;
The first signal is divided into a first signal and the second signal is divided into a first signal and a second signal by dividing a signal transmitted from the outside into the first signal and the second signal, A first duplexer for combining the first signal and the second signal and transferring the phase-controlled first signal and the second signal to the first input / output port;
Wherein the first signal and the second signal are connected to the first phase shifter and the second phase shifter and the signal transmitted from the outside is divided into the first signal and the second signal, A second duplexer for combining the first signal and the second signal, the phase of which is controlled, and transmitting the combined signal to the first input / output port;
A first phase shifter and a second phase shifter for separating a signal transmitted through the fifth element from the outside or a signal to be transmitted through the fifth element into a first signal and a second signal, The third duplexer transmitting or receiving through the fifth device; And
A signal power distributing unit for distributing and providing power to the first to fifth elements,
. The method according to claim 1,
Wherein the signal power distributor comprises:
A power supply for supplying power to a plurality of elements and a duplexer; And
A power divider dividing the power generated through the power supply in half and providing power distributed to the plurality of elements and the duplexer,
. 3. The method of claim 2,
The power divider includes:
The power corresponding to 50% of the power supplied from the power supply is distributed to the second device and the fourth device, respectively, and power corresponding to the remaining 50% is supplied to the first device and the third device Respectively. The method of claim 3,
Some of the plurality of first and third devices are supplied with power corresponding to 20% of the power supplied from the power supply, and the remaining devices other than the device receiving 20% Respectively. ≪ RTI ID = 0.0 > The method according to claim 1,
The first and second signals are combined and transmitted to the first duplexer or the first input /
Further comprising: The method according to claim 1,
Wherein the first signal or the second signal is any one of a 2.1 GHz band or a 1.8 GHz band. The method according to claim 1,
A sixth element for transmitting and receiving a third signal to the third band;
A third phase shifter connected to the sixth element and controlling a phase of a third signal to vary a vertical beam tilt of the antenna; And
A second input / output port for transmitting a third signal to the third phase shifter or a third signal received from the third phase shifter to the outside,
Further comprising:
And the third signal is a low frequency reception signal in the 800 MHz or 900 MHz band.

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