KR20190014357A - Compensator of communication signal - Google Patents

Abstract

A communication signal compensator according to an embodiment of the present invention is a communication signal compensator for enhancing transmission / reception sensitivity of a communication signal, including a transmission / reception unit for transmitting / receiving a communication signal, a detection unit for detecting a power level of a communication signal received from the transmission / reception unit, An output setting unit for determining an output band based on the determined frequency band and the waveform of the communication signal, and an output setting unit for determining an output band based on the determined frequency band using a TDD (Time Division Duplex) A peak detector for detecting a link signal, and a controller for connecting the uplink signal line or connecting the downlink signal line according to the detection result of the uplink signal.

Description

[0001] COMPENSATOR OF COMMUNICATION SIGNAL [0002]

The present invention relates to a communication signal compensator for improving signal sensitivity of a wireless communication device located inside a vehicle.

In recent years, as high-rise buildings have been developed and indoor spaces have become ever more complicated, shaded areas with poor propagation environment in wireless communication systems have been generated all over the buildings. In addition, since a vehicle, an elevator, and the like are generally made of metal, the transmission / reception ratio of the radio wave is lowered when the vehicle or an elevator must pass through.

As a technique to solve such a problem, a radio propagation environment is improved by using a communication signal compensator. For example, it is possible to improve the propagation environment of a shaded area by installing an antenna in a building or a vehicle exterior, and connecting the antenna to a building or an antenna installed inside the vehicle. At this time, there may be at least one antenna inside the vehicle. When there are a plurality of antennas in the vehicle, the communication signal compensator is connected to any one of the plurality of antennas to improve the sensitivity of signals transmitted and received in the wireless communication apparatus.

However, if the communication signal compensator is connected to any one of the plurality of antennas, there is a limit that can not reflect the changed propagation environment even if the propagation environment is changed thereafter.

An object of the present invention is to provide a communication signal compensator including a connection device and a connection device for detecting the size of a signal in real time to receive a communication signal through an antenna having an optimal signal sensitivity.

A connection device for connecting a plurality of antennas and a communication signal compensator according to an embodiment of the present invention includes a plurality of antenna switches connected to each of a plurality of antennas, an antenna switch connected to any one of the plurality of antennas through an antenna switch, A connection switch for transmitting the communication signal to the communication signal compensator so that the signal is amplified, and a connection switch connected to each of the plurality of antennas at predetermined intervals to receive a communication signal received by the antenna connected to each period, And a detection switch for transmitting the signal to the communication signal compensator.

The connection switch may be connected to an antenna switch which transmits the communication signal having the largest signal among the plurality of antenna switches.

And a selection switch connected to any one of the coupler and the detection switch connected to the connection switch.

The selection switch may be connected to a detector for detecting the magnitude of the signal included in the communication signal compensator.

A communication signal compensator according to an exemplary embodiment of the present invention includes a plurality of antenna switches connected to a plurality of antennas, a connection switch connected to a first antenna among a plurality of antennas through an antenna switch, A detection switch which is sequentially connected to the antenna and receives a communication signal received through each of the connected antennas and transmits the communication signal to the detection unit, a selection switch connected to one of a coupler and a detection switch connected to the connection switch, And a controller for controlling one of the plurality of antennas to be connected to the connection switch based on the size of the detected signal through the detection unit and the detection unit.

The control unit may acquire a communication signal having the largest signal size through the detection unit and control the plurality of antenna switches and the connection switch so that the connection switch is connected to the antenna corresponding to the obtained communication signal.

The control unit may control the connection switch to be connected to the second antenna if the size of the communication signal received through the second antenna among the plurality of antennas is larger than the size of the communication signal received through the first antenna.

The selection switch is connected to the coupler when detecting the size of the communication signal received through the first antenna and connected to the detection switch when detecting the size of the communication signal received through the remaining antennas except for the first antenna among the plurality of antennas .

The detection unit includes a plurality of bandpass filters, a switch for passing the communication signal transmitted to the detection unit through one of the plurality of bandpass filters, and a power detection element for detecting the size of the communication signal passing through any of the bandpass filters can do.

A band setting unit for determining a frequency band of the communication signal based on the magnitude of the signal detected by the detection unit, and an output setting unit for determining the output band based on the determined frequency band and the waveform of the communication signal.

According to the embodiment of the present invention, it is possible to detect a change of the communication state in real time by selecting one of the multi-port antenna or the plurality of antennas and receiving a communication signal and simultaneously checking another antenna in real time, It is possible to receive an optimal communication signal according to the present invention.

Accordingly, there is an advantage that an antenna for receiving a communication signal in an optimal manner can be detected and responded in real time, such as when a user equipment is handed over or when a position of a user equipment is changed.

1 and 2 are views for explaining an example in which a communication signal compensator according to an embodiment of the present invention is used.
3 is an exemplary view showing positions of a shark antenna, a communication signal compensator, and a coupling antenna according to an embodiment of the present invention.
4 is a block diagram illustrating a configuration of a communication signal compensator according to an embodiment of the present invention.
5 is a circuit diagram of a communication signal compensator according to an embodiment of the present invention.
FIG. 6 is a circuit diagram of a communication signal compensator supporting a Frequency Division Duplex (FDD) scheme and a Time Division Duplex (TDD) scheme according to an embodiment of the present invention.
7 is a view for explaining a coupling antenna according to the first embodiment of the present invention.
8 is a view for explaining a coupling antenna according to a second embodiment of the present invention.
9 is a circuit diagram showing a communication signal compensator according to the first embodiment of the present invention.
10 is an enlarged view of the connecting device shown in FIG.
11 is a flowchart showing a method of operating the communication signal compensator according to the first embodiment of the present invention.
12 is a circuit diagram showing a communication signal compensator according to a second embodiment of the present invention.
13 is a flowchart showing a method of operating a communication signal compensator according to a second embodiment of the present invention.

Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the accompanying drawings. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It should be understood that it includes water and alternatives.

In addition, 'connected' mentioned below should be construed to mean not only that each element is directly connected but also indirectly connected with another element interposed therebetween.

1 and 2 are views for explaining an example in which a communication signal compensator according to an embodiment of the present invention is used.

As shown in FIG. 1, a communication signal compensator may be located inside the automobile 1, and may amplify a communication signal transmitted / received by a communication device located inside the automobile 1. When the communication signal compensator is located inside the automobile 1, the transmission / reception strength of the communication signal may be higher than the transmission / reception strength of the communication signal if the communication signal compensator is not located inside the automobile 1.

Here, the communication device may include a mobile terminal such as a smart phone. An MS (Mobile Subscriber Station), an SS (Subscriber Station), an AMS (Advanced Mobile Station), a WT (Wireless Terminal), an MTC (Machine- Type Communication device, a Machine-to-Machine (M2M) device, and a Device-to-Device (D2D) device. However, since this is merely an example, it should be construed as a concept including all the devices that are currently developed, commercialized, or developed in the future or capable of signal transmission, in addition to the above-mentioned examples.

The communication signal means a signal transmitted / received by a communication device from / to another communication device, and includes an uplink signal transmitted from a communication device located inside the automobile 1 to another device, And a downlink signal received by the communication device located in the mobile communication terminal.

1 is merely an example, and the communication signal compensator is located at a place where the transmission / reception strength of a signal such as an elevator or the like in a high-rise building is low, so that the strength of a communication signal transmitted / . That is, the communication signal compensator can be installed in a place where transmission / reception strength is low due to an obstacle.

The radio wave transmitted from the base station may collide with the building or the metal forming the appearance of the car 1 may be shielded by the communication device located in the car 1 or the inside of the building, The area where the radio wave is not partially transmitted is referred to as a shaded area, and at least one antenna for increasing the radio wave transmission / reception ratio may be provided in the shaded area.

For example, a shark antenna may be provided outside the automobile 1, and a coupling antenna may be provided inside the automobile 1.

If the communication signal compensator is located inside the vehicle 1, the communication signal compensator is positioned between the shark antenna mounted outside the automobile 1 and the coupling antenna mounted inside the automobile 1, And can be connected to a ring antenna.

The communication signal compensator can amplify a communication signal received from the outside such as a downlink signal from the shark antenna, and then transmit the signal to the communication device through the coupling antenna. Also, the communication signal compensator may receive a signal generated by a communication device such as an uplink signal from a coupling antenna, amplify the signal, and then transmit the amplified signal to the base station through a shark antenna. At this time, the communication signal compensator can compensate the line loss from the shark antenna and the coupling loss between the coupling antenna and the communication device, and serves as a bidirectional amplifier for simultaneously amplifying the uplink signal and the downlink signal .

On the other hand, since the coupling antenna transmits and receives signals using electromagnetic waves, it may be highly affected by peripheral devices. Therefore, a coupling antenna may be provided at a position where the influence of other devices is less influenced by the relationship with other peripheral devices. Further, if the coupling antenna is located too far from the communication device, there is a problem that the performance of the coupling antenna deteriorates. Thus, a position that can minimize the influence of the peripheral device while narrowing the distance to the communication device may be required.

For example, the coupling antenna may be located in a wireless charging device provided inside the vehicle 1. [ However, this is merely an example, and the position of the coupling antenna is not limited.

Also, according to one embodiment, the communication signal compensator may be located in a wireless charging device.

The wireless charging device may be a device that powers the communication device in a wireless charging fashion. The wireless charging method is a method of charging the communication device located adjacent to the wireless charging device without connecting the wireless charging device and the communication device with a physical medium such as a cable. Accordingly, when the communication device is to be charged while using the communication device, it is difficult to completely insert and remove the cable, and the difficulty of using the communication device while being inserted into the cable can be solved.

As shown in FIG. 2, the wireless charging device 11 may be provided inside the vehicle 1. The communication device 10 within the automobile 1 can be mostly used while being mounted on the wireless charging device 11. [ Therefore, the strength of the antenna signal is very important in a state where the communication device 10 is seated in the wireless charging device 11.

The distance between the communication signal compensator and the communication device 10 can be minimized when the communication signal compensator is provided in the wireless charging device 11 itself. In addition, when the coupling antenna is provided in the wireless charging device 11, the efficiency of the coupling antenna inside the automobile 1 can be maximized. Therefore, there is an effect that the communication device 10 is charged through the wireless charging device 11 and the transmission / reception intensity of signals transmitted / received from the communication device 10 can be increased.

As described above, the communication signal compensator according to the embodiment of the present invention can be provided inside the wireless charging device 11.

On the other hand, the positions of the shark antenna, the communication signal compensator, and the coupling antenna may vary.

3 is an exemplary view showing positions of a shark antenna, a communication signal compensator, and a coupling antenna according to an embodiment of the present invention.

3, the shark antenna 12 may be located outside the automobile 1, and the communication signal compensator 100 and the coupling antenna may be located inside the wireless charging device 11. As shown in Fig. However, this is merely an example, and it is appropriate that the positions of the shark antenna, the communication signal compensator, and the coupling antenna are not limited.

Next, a communication signal compensator and a coupling antenna according to an embodiment of the present invention will be described in detail.

First, with reference to Figs. 4 to 5, a communication signal compensator will be described. FIG. 4 is a block diagram illustrating a configuration of a communication signal compensator according to an embodiment of the present invention, and FIG. 5 is a circuit diagram of a communication signal compensator according to an embodiment of the present invention.

4, the communication signal compensator 100 includes a transmission and reception unit 110 for transmitting and receiving a communication signal, a detection unit 120 for detecting a power level of a communication signal transmitted and received through the transmission and reception unit 110, The output setting unit 140 for setting the communication output band, and the control unit 150 for controlling the operation of the communication signal compensator 100. The control unit 150 controls the operation of the communication signal compensator 100,

The transceiver 110 may include an uplink signal antenna 111 for receiving an uplink signal generated in a communication device and a downlink signal antenna 112 for receiving a downlink signal transmitted to the communication device.

The detection unit 120 includes a coupler 121, a first switch 122, a second switch 123, a first band pass filter 124, a second band pass filter 125, a third band pass filter 126, A fourth band-pass filter 127, a fifth band-pass filter 128, and a power detection element 129, as shown in FIG.

The detection unit 120 may transmit the communication signal received through the uplink signal antenna 111 to the power detection element 129 through the coupler 121. Specifically, the first switch 122 and the second switch 123 may be connected to any one of the first through fifth band-pass filters 124 through 128 at predetermined intervals. The power detection element 129 may receive the communication signal that has passed through each of the first through fifth band-pass filters 124 through 128, and may determine whether the power level exceeds a predetermined power level. As a result of detection of the power detection element 129, the controller 150 can sense that the uplink signal is received when a communication signal exceeding a preset power level is detected.

When the uplink signal is detected, the first switch 122 and the second switch 123 are again connected to any one of the first through fifth band-pass filters 124 through 128 at predetermined intervals, 129 can receive the communication signal passed through each of the first through fifth band-pass filters 124 through 128 and measure the power level. The control unit 150 can determine the frequency band corresponding to the highest power level among the measured power levels as the frequency band of the communication signal. This is to accurately determine the frequency band corresponding to the received uplink signal. For example, the uplink signal antenna 111 can receive the uplink signal having the highest power level in the fifth frequency band. At this time, since the power level of the communication signal is very large, the power level when passing through any one of the first to fourth band-pass filters may be equal to or higher than a predetermined power level, 4 bands can be mistaken. Therefore, after detecting that the uplink has been received, the power level corresponding to the power angular frequency band is measured again, and the frequency band of the uplink signal can be accurately determined by acquiring the band-pass filter when the power level is the largest.

The band setting unit 130 can set the communication frequency band to the frequency band of the determined communication signal. The band setting unit 130 includes a third switch 131, a fourth switch 132, a first band pass filter 134, a second band pass filter 135, a third band pass filter 136, The control unit 150 may include a bandpass filter 137 and a fifth band pass filter 138. The control unit 150 may include a third switch 131 in the band pass filter corresponding to the frequency band of the communication signal determined by the detection unit 120, And the fourth switch 132 are connected to each other.

The uplink signal that has passed through any one of the first through fifth band pass filters 134 through 138 through the third switch 131 and the fourth switch 132 passes through an attenuator and a low noise amplifier To the output setting unit 140 through the output unit 140. [

The control unit 150 can determine the output band of the communication signal by analyzing the communication frequency band and the waveform of the communication signal. The output setting unit 140 can control to set the communication output band to the output band of the determined communication signal.

The output setting unit 140 may include a fifth switch 141, a sixth switch 142, and an amplifier module 143. The control unit 150 may control the fifth switch 141 and the sixth switch 142 so that the output setting unit 140 sets the communication output band to the output band of the determined communication signal. The output band may include Band 1, Band 3, Band 7, Band 8, Band 20, GSM900 and GSM1800, but this is merely exemplary.

The control unit 150 may analyze the frequency band and the signal waveform of the communication signal to divide the output band and control the signal to be transmitted. When the fifth switch 141 and the sixth switch 142 are connected according to the determined output band, the communication signal can be transmitted through the duplexer and the downlink signal antenna 112.

As described above, the communication signal compensator 100 according to the embodiment of the present invention can detect the frequency band of the communication signal and amplify the signal size.

Meanwhile, the communication signal compensator according to an embodiment of the present invention may amplify the size of the communication signal according to the TDD scheme.

Next, a communication signal compensator supporting a frequency division duplex (FDD) scheme and a time division duplex (TDD) scheme according to an embodiment of the present invention will be described.

The communication signal compensator for supporting the TDD scheme may include a peak detector and a signal switcher in the communication signal compensator shown in FIG.

FIG. 6 is a circuit diagram of a communication signal compensator supporting a Frequency Division Duplex (FDD) scheme and a Time Division Duplex (TDD) scheme according to an embodiment of the present invention.

The communication signal compensator 200 according to an embodiment of the present invention can support both the FDD scheme and the TDD scheme.

The communication signal compensator 200 includes a detecting section 220 for detecting the power level of the communication signal received from the transmitting and receiving sections 211 and 212 and the transmitting and receiving sections 211 and 212, An output setting unit 240 for setting a communication output band according to a communication frequency band, a peak detecting unit 260 for detecting an uplink signal when the communication signal is a TDD system, Signal switching units 270 and 280 for determining a signal to be amplified based on the result, and a control unit 250 for controlling operations of the communication signal compensator 200.

The transceiver units 211 and 212 may include an uplink signal antenna 211 and a downlink signal antenna 212. The uplink signal antenna 211 is an antenna for receiving a signal transmitted to the outside from a communication device and the downlink signal antenna 212 is an antenna for receiving a signal received from the outside to a communication device.

The detection unit 220 can use a switch to pass a communication signal through a plurality of bandpass filters and detect the power level of a communication signal that has passed through each bandpass filter.

The detection unit 1120 includes a first switch 222, a second switch 223, a first bandpass filter 224, a second bandpass filter 225, a third bandpass filter 226, A filter 227, a fifth band-pass filter 228, and a power detection element 229.

The coupler 221 can be communicated to the first switch 222 through the communication signal received via the uplink signal antenna 211.

The first switch 222 and the second switch 223 are connected to the first band-pass filter 224, the second band-pass filter 225, the third band-pass filter 226, the fourth band-pass filter 227, and the fifth band-pass filter 228. At this time, the power detection element 229 detects the power level of the first band signal when the first switch 222 and the second switch 223 are connected to the first band-pass filter 224, The first switch 222 and the second switch 223 detect the power level of the second band signal when the first switch 222 and the second switch 223 are connected to the second band pass filter 225, When the first switch 222 and the second switch 223 are connected to the fourth band-pass filter 227, the fourth band-pass filter 227 detects the power level of the third band signal when it is connected to the band-pass filter 226, The power level of the signal can be detected and the power level of the fifth band signal can be detected when the first switch 222 and the second switch 223 are connected to the fifth bandpass filter 228. [

The power detection element 229 receives a communication signal that has passed through each of the first through fifth band-pass filters 224 through 228, and can determine whether the power level exceeds a predetermined power level. As a result of detection of the power detection element 229, the controller 250 can detect that the uplink signal is received when a communication signal exceeding a predetermined power level is detected.

The control unit 250 controls the first switch 222 and the second switch 223 to be connected to the first through fifth bandpass filters 224 through 228 again when an uplink signal is detected, The first to fifth band-pass filters 224 to 228 can receive the communication signal and measure the power level. The control unit 250 may determine the frequency band corresponding to the highest power level among the measured power levels as the frequency band of the communication signal. This is to accurately determine the frequency band corresponding to the received uplink signal.

Here, the frequency band of the communication signal may include FDD Band 1, FDD Band 2, FDD Band 3, TDD Band 1, and TDD Band 2, and the respective frequency bands may be different. However, this is merely an example, and the frequency band of the communication signal that can be determined by the communication signal compensator 200 may include a larger number of frequency bands than the frequency bands listed above, or may include a smaller number of frequency bands. In addition, the frequency band of the communication signal determinable by the communication signal compensator 200 may include only the frequency band corresponding to the FDD scheme, or may include only the frequency band corresponding to the TDD scheme.

The band setting unit 230 may connect a switch to a band-pass filter corresponding to the frequency band determined by the detecting unit 220. [ Accordingly, the uplink signal received by the uplink signal antenna 211 can pass through the band-pass filter corresponding to the determined frequency band.

The band setting unit 230 includes a first switch 231, a second switch 232, a first band pass filter 234, a second band pass filter 235, a third band pass filter 236, A band pass filter 237 and a fifth band pass filter 238. In this case, the first to third band-pass filters 234, 235 and 236 are band-pass filters corresponding to the FDD scheme, and the fourth to fifth band-pass filters 237 and 238 are band- Filter.

The control unit 250 may control the first switch 231 and the second switch 232 to be connected to the band-pass filter corresponding to the frequency band of the communication signal detected by the detecting unit 220.

When the first switch 231 and the second switch 232 are connected to the fourth band-pass filter 237 or the fifth band-pass filter 238, which is a frequency band according to the TDD scheme, the controller 250 controls the peak detector 260 to detect the uplink signal.

The peak detection unit 260 can detect the uplink signal. More specifically, the peak detector 260 detects a peak value of a signal transmitted through the signal transmitter 270, and recognizes that the uplink signal is received when the detected peak value is greater than a predetermined value. In this manner, the peak detector 260 can detect whether or not the uplink signal is received.

The signal switching units 270 and 280 may include a first signal switching unit 270 connected to the band setting unit 230 and a second signal switching unit 280 connected to the output setting unit 240.

The first signal switching unit 270 includes a first coupler 271 for transmitting a communication signal having passed through the fourth band pass filter 237 or the fifth band pass filter 238 to the peak detecting unit 260, A first changeover switch 272, a first changeover switch 273 and a second changeover switch 274. The first signal switching unit 270 controls the first switch 273 or the second switch 274 based on the detection result of the peak detector 260 to connect the uplink line or the downlink line have.

The second signal switching unit 280 may include a fourth band pass filter 281 and a fifth band pass filter 282 and a third changeover switch 283 and a fourth changeover switch 284.

When the first switch 231 is connected to the fourth bandpass filter 237 and the uplink signal is detected by the peak detector 260, the first switch 273 and the third switch 283 are connected to the uplink And if the uplink signal is not detected by the peak detection unit 260, the first changeover switch 273 and the third changeover switch 283 can be connected to the downlink line.

Alternatively, when the first switch 231 is connected to the fifth band-pass filter 238, if the uplink signal is detected by the peak detector 260, the second selector switch 274 and the fourth selector switch 284 are turned off The second changeover switch 274 and the fourth changeover switch 284 can be connected to the downlink line if the uplink signal is not detected by the peak detecting unit 260. [

The output setting unit 240 can set the output band according to the determined frequency band. The output setting unit 240 may connect a switch to a band-pass filter corresponding to the output band.

On the other hand, the control unit 250 can determine whether the communication signal is the FDD scheme or the TDD scheme based on the determined frequency band. The control unit 250 can control the peak detector 260 to detect the uplink signal as described above when the communication signal is the TDD scheme. That is, the peak detecting unit 260 detects an uplink signal when the communication signal has a frequency according to the TDD scheme, and the signal switching units 270 and 280 detect the uplink line according to the detection result of the peak detecting unit 260 You can connect or connect downlink lines.

In this way, the communication signal compensator according to an embodiment of the present invention can improve the uplink signal and the downlink signal both in the technical effect of amplifying both the uplink signal and the downlink signal even when the communication signal according to the TDD scheme, .

Next, a coupling antenna according to an embodiment of the present invention will be described in detail with reference to FIGS. 7 to 8. FIG.

The coupling antenna described below can receive the uplink signal generated by the communication device and transmit it to the communication signal compensator 100. [ In Figs. 7 to 8, the communication signal compensator 100 only shows the configuration necessary for explaining the coupling antenna, and may further include other configurations in addition to the configurations shown in Figs. 7 to 8. Fig.

FIG. 7 is a view for explaining a coupling antenna according to a first embodiment of the present invention, and FIG. 8 is a view for explaining a coupling antenna according to a second embodiment of the present invention.

The coupling antenna 300 according to the first embodiment of the present invention may include a plurality of antennas, and one of the plurality of antennas may be connected to the communication signal compensator 100 to transmit a communication signal.

The coupling antenna 300 according to the first embodiment of the present invention may include an antenna PCB 310 and a switch 320.

The antenna PCB 310 may be provided with a plurality of antennas. Specifically, the antenna PCB 310 includes a first antenna 311, a second antenna 312, a third antenna 313, a fourth antenna 314, a fifth antenna 315, and a sixth antenna 316, . ≪ / RTI >

The positions of the first to sixth antennas 311 to 316 may be different from each other. Also, the types of the first to sixth antennas 311 to 316 may be different. For example, the first and sixth antennas 311 and 316 may be low-frequency antennas of less than 1 GHz, and the second to fifth antennas 312 to 315 may be high-frequency antennas of 1 GHz or more. Therefore, any one of the first to sixth antennas 311 to 316 having a high signal strength is selected and connected to the communication signal compensator 100 according to the position or frequency of the communication apparatus, thereby enabling the communication signal to be efficiently amplified There is an advantage.

However, this is merely an example, and it is appropriate that the position, type, and number of the first to sixth antennas 311 to 316 are not limited.

Any one of the first to sixth antennas 311 to 316 may be connected to the communication signal compensator 100 by the switch 320. The switch 320 may be an RF switch. The switch 320 may include first to sixth ports 321 to 326 corresponding to the first to sixth antennas 311 to 316, respectively. The switch 320 may connect the communication signal compensator 100 with any one of the first to sixth ports 321 to 326 to receive communication signals from the first to sixth antennas 311 to 316.

The communication signal received through any one of the first to sixth antennas 311 to 316 may be transmitted to the communication signal compensator 100. When the switch 320 is connected to the first port 321, the communication signal received by the first antenna 311 is transmitted to the communication signal compensator 100, and when the switch 320 is connected to the second port 322, The communication signal received by the second antenna 312 is transmitted to the communication signal compensator 100. When the switch 320 is connected to the third port 323, The communication signal received by the fourth antenna 314 is transmitted to the communication signal compensator 100. When the switch 320 is connected to the fourth port 324, Is connected to the fifth port 325, the communication signal received by the fifth antenna 315 is transmitted to the communication signal compensator 100. When the switch 320 is connected to the sixth port 326, The communication signal received by the communication signal compensator 100 may be transmitted to the communication signal compensator 100.

Accordingly, the controller 150 may control the coupling antenna 300 to select the antenna of the first to sixth antennas 311 to 316 that has the largest signal size and transmit the selected antenna to the communication signal compensator 100 have.

The coupler 121 of the communication signal compensator 100 may transmit the communication signal transmitted from the coupling antenna 300 to the power detection element 129. [ The power detection element 129 can detect the magnitudes of the communication signals received through the first to sixth antennas 311 to 316, respectively. The control unit 150 may control the switch 320 to be connected to the antenna that transmits the communication signal having the largest detected size.

The size of the uplink signal detected by the coupling antenna 300 varies depending on the positional relationship between the communication device and the coupling antenna. The coupling antenna 300 according to the present invention includes a plurality of antennas, detects the size of the uplink signal received through each antenna, and receives the uplink signal through the antenna having the largest signal size, The uplink signal can be received optimally regardless of the position of the uplink signal. That is, the reception rate of the uplink signal can be minimized according to the position of the communication device.

The coupling antenna 400 according to the second embodiment of the present invention includes one antenna but can receive the uplink signal optimally by changing the shape of the antenna.

The coupling antenna 400 according to the second embodiment of the present invention may include an antenna PCB 410 and a switch 420. The switch 420 may be an RF switch.

The antenna PCB 410 may include one antenna port 411 and at least one switch 420.

One antenna port 411 is connected to the switch 420 and may form an antenna pattern having a different reception range and reception direction depending on the connection state of the switch 420. For example, when the first switch 420a is connected to the first port P1, an antenna pattern such as a P1 loop may be formed. An antenna pattern such as a P2-1 loop may be formed when the first switch 420a is connected to the second port P2 and the second switch 420b is connected to the 2-1 port P2-1 . An antenna pattern such as a P2-2 loop may be formed when the first switch 420a is connected to the second port P2 and the second switch 420b is connected to the second port -2-2 . When the first switch 420a is connected to the third port P3, an antenna pattern such as a P3 loop may be formed.

In FIG. 8, the antenna PCB 410 includes two switches 420a and 420b. However, the present invention is not limited thereto. That is, the number of switches may be varied, and as the number of switches increases, an antenna pattern that can be formed may increase. Further, the antenna loop shown in Fig. 8 is merely an example, so that it is not limited thereto.

If the antenna pattern is changed according to the operation of the switch 420, the reception size of the uplink signal may be changed. The uplink signal antenna 111 of the communication signal compensator 100 receives the communication signal received in the antenna pattern formed by the connection state of the switch 420 and transmits the received uplink signal to the power detection element 129 And the power detection element 129 can detect the magnitude of the uplink signal. The control unit 150 may compare the size of the uplink signal and control the switch 420 so that the uplink signal having the largest size is transmitted to the communication signal compensator 100.

Therefore, the coupling antenna 400 according to the second embodiment of the present invention controls the switch 420 to form an optimal antenna pattern according to the position of the communication device, and receives the uplink signal according to the position of the communication device There is an advantage that the strength can be maximized. According to the second embodiment of the present invention, various types of antenna patterns can be formed using a small number of elements.

According to the coupling antenna described with reference to Figs. 7 to 8, any one of the plurality of antennas may be connected to a communication signal compensator, or may be connected to a communication signal compensator in any one of a plurality of antenna patterns, Signal can be received.

Meanwhile, if any one of the plurality of antennas is connected to the communication signal compensator, or if any one of the plurality of antenna patterns is connected to the communication signal compensator, the current connection state is maintained even if the communication environment is changed thereafter. There is a difficult problem.

Accordingly, the present invention provides a connection device and a communication signal compensator for detecting the size of a communication signal received through each of a plurality of antennas or a plurality of antenna patterns in real time and controlling to receive a communication signal with an optimal antenna or antenna pattern do.

Here, the connection device may be an apparatus for connecting a plurality of antennas and a communication signal compensator. Specifically, the coupling antenna may include a plurality of antennas or may form a plurality of antenna patterns. The coupling device may be a device that receives a communication signal to any one of a plurality of antennas included in a coupling antenna and transfers the communication signal to a communication signal compensator, or receives a communication signal through any one of a plurality of antenna patterns and transmits the communication signal to a communication signal compensator .

Meanwhile, the connection device may be provided in the communication signal compensator. That is, the communication signal compensator according to an embodiment of the present invention includes a connection device, and the communication signal compensator can receive a communication signal through any one of the plurality of antennas or a plurality of antenna patterns.

Hereinafter, a communication signal compensator including a connection device and a connection device according to an embodiment of the present invention will be described.

FIG. 9 is a circuit diagram showing a communication signal compensator according to the first embodiment of the present invention, and FIG. 10 is an enlarged view of the connection device shown in FIG.

The plurality of antennas 341 to 346 shown in FIG. 9 may be antennas included in the coupling antenna 300 described in FIG. For convenience of explanation, it is exemplified that any one of the six antennas is connected to the communication signal compensator through a connection device in FIG. 9. However, the number of antennas is only an example, so that the number is not limited thereto.

That is, the connection device may be connected to two or more antennas to transmit a communication signal to the communication signal compensator.

The connection device is connected to one of a plurality of antenna switches 511 to 516 connected to each of the plurality of antennas 311 to 316 and a plurality of antenna switches 511 to 516, A connection switch 520 for transmitting the communication signal to the communication signal compensator 100 so that the transmitted communication signal is amplified when the communication signal is transmitted to the communication signal compensator 100 and the communication signal is transmitted through the connected antenna switch to the plurality of antennas 511 to 516 A detection switch 530 for transmitting the communication signal to the communication signal compensator 100 so that the size of the transmitted communication signal is detected and a communication signal transmitted through the detection switch 530, And a selection switch 540 for controlling the magnitude of the signal to be detected at all.

First, a plurality of antenna switches 511 to 516 will be described.

The number of the antenna switches 511 to 516 may be the same as the number of the antennas 311 to 316. In FIG. 9, the case where there are six antenna switches 511 to 516 and antennas 311 to 316 will be described as an example.

Each of the plurality of antenna switches 511 to 516 may include three ports, the first port is connected to the antenna, the second port is connected to the connection switch 520, and the third port is connected to the detection switch 530 .

The first port of each of the plurality of antenna switches 511 to 516 may be connected to different antennas 311 to 316. That is, the first port of the first antenna switch 511 is connected to the first antenna 311, the first port of the second antenna switch 512 is connected to the second antenna 312, The first port of the fifth antenna switch 515 is connected to the third antenna 313 and the first port of the fourth antenna switch 514 is connected to the fourth antenna 314, The port may be connected to the fifth antenna 315 and the first port of the sixth antenna switch 516 may be connected to the sixth antenna 316. [

The second port of each of the plurality of antenna switches 511 to 516 is connected to the same connection switch 520 and the third port of each of the plurality of antenna switches 511 to 516 can be connected to the same detection switch 530 have.

Next, the connection switch 520 will be described.

The connection switch 520 may include one port connected to the coupler 121 and a plurality of ports connected to the plurality of antenna switches 511 through 516, respectively. The connection switch 520 may be connected to any one of the plurality of antenna switches 511 to 516. The connection switch 520 may connect any one of the plurality of antenna switches 511 to 516 to the coupler 121.

The connection switch 520 is connected to any one of the plurality of antenna switches 511 to 516 and can transmit a communication signal received through the plurality of antennas 311 to 316 to the coupler 121.

The coupler 121 may transmit the communication signal transmitted through the connection switch 520 to the band setting unit 130 so that the communication signal is amplified and transmitted to the outside. Alternatively, the coupler 121 may control the communication signal transmitted through the connection switch 520 to pass through each of the plurality of band-pass filters 124 to 128 and detect the magnitude of the signal at the power detection element 129 .

Next, the detection switch 530 will be described.

The detection switch 530 may include one port connected to the selection switch 540 and a plurality of ports connected to the plurality of antenna switches 511 through 516, respectively. The detection switch 530 may be sequentially connected to the plurality of antenna switches 511 to 516.

The detection switch 530 is sequentially connected to the plurality of antenna switches 511 to 516 and receives a communication signal received through each of the plurality of antennas 311 to 316 to detect the size of each communication signal. ). ≪ / RTI > Specifically, the detection switch 530 transmits a communication signal received through each of the plurality of antennas 311 to 316 to the selection switch 540, and the selection switch 540 is connected to the plurality of band-pass filters 124 to 128, And the power detection element 129 to detect the magnitude of each signal.

Next, the selection switch 540 will be described.

The selection switch 540 may be coupled to the coupler 121 or to the detection switch 530.

When the selection switch 540 is connected to the coupler 121, the magnitude of the communication signal received by the antenna connected to the connection switch 520 can be detected.

When the selection switch 540 is connected to the detection switch 530, the size of the communication signal received by each of the plurality of antennas 311 to 316 can be detected. More specifically, the selection switch 540 can detect the magnitude of the communication signal received through the remaining antennas except for the antenna connected to the connection switch 520.

The selection switch 540 may include three ports, a first port connected to the coupler 121, a second port connected to the detection switch 530, and a third port connected to the plurality of bandpass filters 124-128). ≪ / RTI >

The selection switch 540 is connected to the first port and may be connected to the second port after a predetermined period. When the selection switch 540 is connected to the second port, it may be connected to the remaining antennas except the antenna connected to the connection switch 520 at predetermined intervals. The selection switch 540 may be connected to the first port once connected to the remaining antennas.

For example, the first antenna 311 of the plurality of antennas 311 to 316 may be connected to the connection switch 520. In this case, the selection switch 540 may be connected to the first port to control the magnitude of the communication signal received by the first antenna 311 to be detected. Thereafter, the selection switch 540 is connected to the second port, the detection switch 530 may be connected to the second antenna 312, and the magnitude of the communication signal received by the second antenna 312 is detected . Thereafter, the selection switch 540 is continuously connected to the second port, and the detection switch 530 is connected to the third antenna 313 so that the magnitude of the communication signal received by the third antenna 313 can be detected. Thereafter, the selection switch 540 is continuously connected to the second port, and the detection switch 530 is connected to the fourth antenna 314 so that the magnitude of the communication signal received by the fourth antenna 314 can be detected. Thereafter, the selection switch 540 is continuously connected to the second port, and the detection switch 530 is connected to the fifth antenna 315 so that the magnitude of the communication signal received by the fifth antenna 315 can be detected. Thereafter, the selection switch 540 is continuously connected to the second port, and the detection switch 530 is connected to the sixth antenna 316 so that the magnitude of the communication signal received by the sixth antenna 316 can be detected. Thereafter, the selection switch 540 is connected to the first port again so as to control the magnitude of the communication signal received by the first antenna 311 to be detected.

At this time, the magnitude of the communication signal received through any one of the plurality of antennas 311 to 316 is detected by detecting the size of a communication signal passing through each of the first to sixth band pass filters 124 to 128 per one antenna . Therefore, when the duty cycle of the communication signal is T0 and the data processing time and the switching time per one band pass filter are T1, T0 can be larger than the product of T1 and the number of bandpass filters and the number of antennas. For example, if the communication signal is GSM, the minimum duty cycle is within 360us, so the data processing time and switching time per band pass filter should be less than 12us. However, this is merely an example.

In this manner, the connection switch 520 can transmit the communication signal to the band detection unit to prevent the communication signal from being cut off, and the plurality of antennas 311 to 316 can be prevented from passing through the detection switch 530 and the selection switch 540, It is possible to detect the size of a communication signal received through the communication network in real time.

9 to 10, the control unit 150 is not connected to the connection device, but only a communication line connecting the control unit 150 and the connection device is shown as being omitted. The connection device is connected to the control unit 150, . That is, at least one of the plurality of antenna switches 511 to 516, the connection switch 520, the detection switch 530, and the selection switch 540 can be controlled by the control unit 150.

11 is a flowchart showing a method of operating the communication signal compensator according to the first embodiment of the present invention. That is, FIG. 11 illustrates a method of operating a communication signal compensator connected to a connection device according to an embodiment of the present invention, or a method of operating a communication signal compensator including a connection device.

First, the connection switch 520 is connected to each of the plurality of antenna switches 511 to 516, and a communication signal having the largest signal size can be detected (S101).

The initial state can be set when the power of the communication signal compensator 100 is turned on or when the uplink signal is received for the first time.

To set the initial state, the connection switch 520 may be connected to each of the plurality of antenna switches 511 to 516, respectively. At this time, the selection switch 540 may be connected to the coupler 121. Accordingly, the size of the communication signal received by each of the antennas 311 to 316 can be detected by the detecting unit 120, and the controller 160 can detect the communication signal with the largest signal size.

The control unit 150 may connect the connection switch to the antenna that receives the communication signal having the largest signal size (S103).

The control unit 150 can acquire the antenna that receives the communication signal having the largest size based on the result of detecting the signal size. The control unit 150 may control the connection switch 520 to be connected to the antenna that receives the communication signal having the largest signal among the plurality of antennas.

In this way, the communication signal compensator can control the connection switch 520 to be sequentially connected to the plurality of antenna switches 511 to 516 when the initial state is set.

Next, the communication signal compensator can continuously receive and amplify the communication signal so as to prevent the communication signal from being interrupted, and detect the size of the communication signal received through the other antennas, thereby confirming whether or not the communication state is changed.

The control unit 150 controls the detection switch 530 and the selection switch 540 to sequentially transmit the communication signals received by the plurality of antennas 511 to 516 to the detection unit 120 at step S107.

The control unit 150 can sequentially detect the sizes of the communication signals received through the plurality of antennas 311 to 316. [

The control unit 150 can detect the size of a communication signal received through the antenna connected to the connection switch 520 and the remaining antenna not connected to the connection switch 520 among the plurality of antennas 311 to 316.

The control unit 150 controls the selection switch 540 to be connected to the connection switch 520 when it is desired to detect the size of the communication signal received by the antenna connected to the connection switch 520 among the plurality of antennas 311 to 316. [ can do.

When the controller 150 detects the magnitude of a communication signal received through the remaining antennas not connected to the connection switch 520 among the plurality of antennas 311 through 316, the selection switch 540 is turned to the detection switch 530 Can be controlled to be connected. The detection switch 530 may be sequentially connected to the remaining antennas not connected to the connection switch 520 among the plurality of antennas 311 to 316.

In this way, the controller 150 controls the detection switch 530 and the selection switch 540 to detect the magnitudes of the communication signals received by the plurality of antennas 511 to 516, respectively.

The control unit 150 can detect the communication signal having the largest signal size among the communication signals transmitted to the detection unit 120 (S109).

The control unit 150 can control to detect the size of all communication signals that have passed through each of the plurality of antennas 311 to 316 and the plurality of band pass filters 124 to 128, respectively. The control unit 150 controls the size of the communication signals received by the first antenna 311 through the first through fifth band-pass filters 124 through 128, Of the communication signals received through the first to fifth band pass filters 124 to 128 and the communication signals received by the third antenna 313 are transmitted to the first to fifth bands The size of five communication signals that have passed through each of the pass filters 124 to 128 and the size of the communication signal received by the fourth antenna 314 through the first to fifth band pass filters 124 to 128, The size of the communication signal and the size of the five communication signals through which the communication signal received by the fifth antenna 315 has passed through each of the first through fifth bandpass filters 124 to 128 and the size of the communication signal by the sixth antenna 316 And detects the size of the five communication signals through which the received communication signal has passed through each of the first through fifth band pass filters 124 through 128 The detection unit 120 can be controlled.

That is, the controller 150 can detect the size of the communication signal by the number of the antennas multiplied by the number of the band-pass filters. The same can be applied to setting the initial state.

The control unit 150 can detect the communication signal having the largest signal size by comparing the sizes of the detected communication signals with each other.

The control unit 150 can determine whether the antenna receiving the communication signal having the largest size is the same as the antenna connected to the connection switch 520 at operation S111.

The control unit 150 may control the connection switch 520 to maintain the current connection state if the antenna receiving the communication signal having the largest size is the same as the antenna connected to the connection switch 520 at present. The control unit 150 maintains the connection state of the connection switch 520 and returns to S107 to control the size of the communication signal received by the plurality of antennas 311 to 316 to be detected.

If the antenna receiving the communication signal having the largest size is not the same as the antenna connected to the connection switch 520, the controller 150 controls the connection switch 520 to be connected to the antenna having the largest communication signal, (S113).

The control unit 150 may control the connection state of the connection switch 520 to be changed if the antenna receiving the communication signal having the largest size is not the same as the antenna connected to the connection switch 520 at present.

For example, when the connection switch 520 is connected to the first antenna 311, the control unit 150 determines that the second antenna 312 of the plurality of antennas 312 is larger than the communication signal received through the first antenna 311 The connection switch 520 can be controlled to be connected to the second antenna 312.

The controller 150 changes the connection state of the connection switch 520 and returns to S107 to detect the size of the communication signal received by the plurality of antennas 311 to 316. [

As described above, the communication signal compensator according to the embodiment of the present invention continuously receives a communication signal through any one of the antennas, detects the magnitude of a communication signal received through another antenna in real time, There is an advantage to receive.

Next, Fig. 12 is a circuit diagram showing a communication signal compensator according to a second embodiment of the present invention.

The communication signal compensator according to the second embodiment of the present invention includes an antenna port 411 for forming an antenna pattern and at least one switch 420 for changing an antenna pattern, Lt; RTI ID = 0.0 >

The control unit 150 can control the switch 420. [ Specifically, the controller 150 may change the connection state of the switch 420 to form various antenna patterns.

The control unit 150 may change the connection state of the at least one switch 420 so that various antenna patterns are sequentially formed. The control unit 150 can control to detect the size of the communication signal corresponding to each antenna pattern. Specifically, the uplink signal antenna 111 can receive a communication signal and transmit it to the detection unit 120 whenever the connection state of the switch 420 is changed. The detection unit 120 can detect the magnitude of the communication signal that has passed through each of the plurality of band pass filters 124 to 126. [ The control unit 150 can control the communication signal to be received on the antenna pattern that received the communication signal having the largest communication signal size based on the detected size of the communication signal. That is, the controller 150 may control at least one of the switches 420 to form an antenna pattern having received the communication signal having the largest communication signal size.

Thereafter, the control unit 150 changes the connection state of the at least one switch 420 so that each antenna pattern is formed in sequence when the communication signal is not received, or when the predetermined time has elapsed, and repeats the above- can do.

Thereby, there is an advantage that a communication signal can be received in an optimum state by immediately reflecting the change of the communication state.

Next, FIG. 13 is a flowchart showing a method of operating the communication signal compensator according to the second embodiment of the present invention.

The control unit 150 may control the at least one switch 420 to sequentially transmit a communication signal corresponding to each antenna pattern to the detection unit 120 (S201).

The communication signal compensator 100 may form a plurality of antenna patterns as the at least one switch 420 changes the connection state. The controller 150 may change the connection state of the switch 420 to sequentially form a plurality of antenna patterns.

The control unit 150 can detect a communication signal having the largest signal size among the communication signals transmitted to the detection unit 120 (S203).

The control unit 150 may transmit a communication signal corresponding to each antenna pattern to the detection unit 120 so that the detection unit 120 may calculate the size of the communication signal according to each antenna pattern. The control unit 150 can acquire the communication signal having the largest communication signal size based on the calculated size of the communication signal. That is, the control unit 150 can obtain the antenna pattern that received the communication signal having the largest communication signal size.

The control unit 150 may control at least one of the switches 420 to form an antenna pattern corresponding to the communication signal having the largest size (S205).

The control unit 150 may control the switch 420 to receive the communication signals received in an antenna pattern corresponding to the communication signal having the largest size. That is, the controller 150 can change the connection state of the switch 420 so that the antenna pattern corresponding to the communication signal having the largest signal size is formed.

The control unit 150 can maintain the connection state of the changed switch 420. [ Specifically, the control unit 150 can maintain the connection state of the changed switch 420 and receive the communication signal with the changed antenna pattern.

The control unit 150 may detect that the communication signal is not received or the elapse of the predetermined time (S207).

The control unit 150 may sense a disconnection of the communication signal or elapse of a predetermined time to detect a change in the communication state.

According to an embodiment of the present invention, the controller 150 may detect whether or not a communication signal is received to detect a disconnection of a communication signal. Specifically, the control unit 150 can detect the size of the communication signal received through the detection unit 120. The control unit 150 can regard the communication signal as not being received if the detected communication signal is smaller than the predetermined size. If the communication signal is not received, the control unit 150 returns to S201 to control the switch 420 so that each antenna pattern is formed. On the other hand, when the communication signal is received, the controller 150 returns to S205 to maintain the connection state of the current switch 420. [

According to another embodiment of the present invention, the control unit 150 may detect the passage of a predetermined time. Specifically, the control unit 150 can change the connection state of the switch 420 and count the elapsed time. If it is determined that the predetermined time has elapsed as a result of counting, the control unit 150 may return to S201 to control the switch 420 so that each antenna pattern is formed. On the other hand, when the communication signal is received, the controller 150 returns to S205 to maintain the connection state of the current switch 420. [

As described above, the communication signal compensator 100 according to the embodiment of the present invention detects the communication state by detecting the size of the communication signal by changing the antenna pattern every time a specific condition is satisfied, There is an advantage to be able to do. In addition, there is an advantage that it can be used in connection with a multi-port coupling antenna and a simple circuit can be implemented.

The communication signal compensator described above can be applied to a configuration and a method of the embodiments described above in a limited manner, but the embodiments can be modified so that all or some of the embodiments are selectively combined .

Claims (10)

A connection device for connecting a plurality of antennas and a communication signal compensator,
A plurality of antenna switches connected to each of the plurality of antennas;
A connection switch connected to any one of the plurality of antennas through the antenna switch and receiving a communication signal received by the connected antenna and transmitting the received communication signal to a communication signal compensator so as to amplify the signal; And
And a detection switch which is connected to each of the plurality of antennas at predetermined intervals and receives a communication signal received by an antenna connected to each of the plurality of antennas at each period and transmits the received communication signal to a communication signal compensator so as to detect the size of the communication signal. The method according to claim 1,
The connection switch
Wherein the antenna switch is connected to an antenna switch for transmitting a communication signal having the largest signal among the plurality of antenna switches. The method according to claim 1,
And a selector switch connected to any one of the coupler and the detection switch connected to the connection switch. The method according to claim 1,
The selection switch
And a detector connected to the communication signal compensator and detecting a magnitude of a signal included in the communication signal compensator. A plurality of antenna switches connected to each of the plurality of antennas;
A connection switch connected to the first one of the plurality of antennas through the antenna switch;
A detection switch sequentially connected to the remaining antennas except for the first antenna among the plurality of antennas and receiving a communication signal received through each of the antennas connected to each other and transmitting the received communication signal to a detection unit;
A selector switch connected to any one of a coupler and a detection switch connected to the connection switch;
A detector for detecting a magnitude of a communication signal transmitted through the selection switch; And
And a control unit for controlling one of the plurality of antennas to be connected to the connection switch based on the magnitude of the signal detected through the detection unit. 6. The method of claim 5,
The control unit
Acquires a communication signal having the largest signal size through the detection unit and controls the plurality of antenna switches and the connection switch to connect the connection switch to an antenna corresponding to the obtained communication signal. The method according to claim 6,
The control unit
And controls the connection switch to be connected to the second antenna when a size of the communication signal received through the second antenna among the plurality of antennas is larger than a size of the communication signal received through the first antenna. 6. The method of claim 5,
The selection switch
When detecting the magnitude of a communication signal received through the remaining antennas except for the first one of the plurality of antennas, when the magnitude of the communication signal received through the first antenna is detected, The communication signal compensator to be connected. 6. The method of claim 5,
The detection unit
A plurality of bandpass filters,
A switch for passing the communication signal transmitted to the detection unit to one of the plurality of band pass filters,
And a power detection element for detecting the magnitude of a communication signal passing through any one of the band-pass filters. 6. The method of claim 5,
A band setting unit for determining a frequency band of the communication signal based on the magnitude of the signal detected by the detecting unit; And
And an output setting section for determining an output band based on the determined frequency band and the waveform of the communication signal.

Images