KR20160036942A - Phase compensating method, and appratus applied to the same - Google Patents

Abstract

In the present invention, a phase difference compensating apparatus, and an operating method thereof are disclosed.When a transmission signal in a communication method, which does not support a multi-input multi-output (MIMO) method, is transmitted to an antenna through different paths by dividing the transmission signal into a plurality of transmission signals, the transmission signal can be prevented from being distorted or offset due to phase difference between the transmission signals by compensating the phase difference between the transmission signals which can be caused by the different paths.

Description

[0001] PHASE COMPENSATING METHOD, AND APPRATUS APPLIED TO THE SAME [0002]

In the case of dividing a transmission signal of a communication method that does not support a MIMO (Multi Input Multiple Output) scheme into a plurality of transmission signals and transmitting the transmission signal to an antenna through a different path, To compensate for the phase difference between the transmission signals.

In a communication method (e.g., WCDMA) that does not support a MIMO (Multi Input Multi Output) method, a single transmission signal is divided into a vertical polarization transmission signal and a horizontal polarization transmission signal for the purpose of expanding its coverage, Through the antenna.

As described above, dividing a single transmission signal into a vertical polarization transmission signal and a horizontal polarization transmission signal is for improving the output of the transmission signal. In order to improve the output of the transmission signal, a vertical polarization transmission signal, It is presupposed that the phases are the same between the transmission signals.

However, in the case of a horizontally polarized transmission signal, a vertical polarization transmission signal divided from a single transmission signal and a different path (for example, a cable) are transmitted to the antenna. In this case, A phase difference may occur between transmission signals.

As a result, if there is a phase difference between the vertical polarization transmission signal and the horizontal polarization transmission signal as described above, the transmission signal is distorted or even canceled, and the output of the transmission signal can not be expected to be improved at all.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a method and apparatus for transmitting a transmission signal of a communication method which does not support a MIMO (Multi Input Multi Output) To compensate for a phase difference between transmission signals that can be generated due to the different paths, thereby preventing a transmission signal from being distorted or canceled due to a phase difference between transmission signals.

According to a first aspect of the present invention, there is provided a phase compensation apparatus including a first cable for transmitting a transmission signal of a first communication scheme to an antenna, a second communication scheme Respectively; A measurement for measuring a timing error generated from a length difference between the first cable and the second cable based on a reception timing of each of the transmission signals of the second communication scheme received through the first cable and the second cable, step; And calculating a length difference between the first cable and the second cable based on the measured timing error, and when the calculated length difference is compensated, So that a phase difference does not occur between transmission signals of the first communication scheme to be transmitted.

More specifically, the transmission signal of the first communication mode includes a vertical polarized wave transmission signal and a horizontal polarized wave transmission signal classified from the same transmission signal, and the vertical polarized wave transmission signal is transmitted to the first cable or the second cable And the horizontal polarization transmission signal is transmitted to the antenna through the rest of the first cable or the second cable in which the vertical polarization transmission signal is not transmitted.

More specifically, the transmission signal of the second communication scheme received through the first cable and the second cable includes respective reference signals (RSs) for confirming the transmission time from the base station, Wherein the timing error is calculated from a time difference between the reception timings when transmission timings confirmed from the reference signal are identical for each of the transmission signals of the second communication scheme received through the first cable and the second cable, .

More specifically, at least one of the first cable and the second cable includes a cable connector for connecting a compensation cable in relation to the length adjustment, Further comprising connecting the compensating cable by a calculated length difference, or separating the compensating cable connected to the cable connector.

According to a second aspect of the present invention, there is provided a phase compensation apparatus including a first cable for transmitting a transmission signal of a first communication scheme to an antenna and a second communication scheme A receiving unit for receiving transmission signals of the first and second antennas, respectively; A measurement for measuring a timing error generated from a length difference between the first cable and the second cable based on a reception timing of each of the transmission signals of the second communication scheme received through the first cable and the second cable, part; And calculating a length difference between the first cable and the second cable based on the measured timing error, and when the calculated length difference is compensated, And not to generate a phase difference between transmission signals of the first communication method to be transmitted.

According to the phase compensation apparatus and the method of operation of the present invention, a transmission signal of a communication method that does not support a MIMO (Multi Input Multiple Output) scheme is divided into a plurality of transmission signals and is transmitted to an antenna through a different path It is possible to prevent the transmission signal from being distorted or offset due to the phase difference between the transmission signals by compensating for the phase difference between the transmission signals that may occur due to the different paths.

1 is a schematic configuration diagram of a phase compensation apparatus according to an embodiment of the present invention;
FIGS. 2 to 7 are diagrams for explaining phase differences according to an embodiment of the present invention; FIG.
8 is a flowchart for explaining an operational flow in a phase compensation apparatus according to an embodiment of the present invention;

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a phase compensation apparatus according to an embodiment of the present invention. Referring to FIG.

1, a phase compensation apparatus according to an embodiment of the present invention includes a first cable 1 and a second cable 2 for transmitting a transmission signal of a first communication scheme to an antenna, A measuring unit 200 for measuring a timing error between a transmission signal of a second communication scheme received through the first cable and a second cable, And a calculation unit 300 for calculating a length difference between the first cable and the second cable based on the measured timing error.

The entire configuration or part of the phase compensation apparatus according to an embodiment of the present invention including the receiver 100, the measurement unit 200, and the calculation unit 300 may be implemented in the form of a software module or a hardware module, Or a combination thereof.

For example, the phase compensation apparatus may have a structure that is integrated with a base station that transmits a transmission signal of a first communication scheme and a transmission signal of a second communication scheme together via an antenna 3, or may be a device separate from the base station Can be implemented.

Here, the transmission signal of the first communication scheme refers to a communication scheme that does not support a MIMO (Multi Input Multi Output) scheme. For example, WCDMA, which is a 3G communication scheme, may correspond to the transmission scheme.

In the case of the transmission signal of the first communication method, the vertical polarization transmission signal may be divided into '3G Tx_0' and the horizontal polarization transmission signal may be divided into a vertical polarization transmission signal and a horizontal polarization transmission signal, And the horizontal polarization transmission signal 3G Tx_1 is transmitted through the second cable 2 to the antenna 3 through the first cable 1 and the vertical polarization transmission signal 3G Tx_0 through the second cable 2, It is assumed that it is transmitted to the antenna 3.

In addition, the transmission signal of the second communication scheme refers to the MIMO scheme mentioned above, for example, LTE which is a 4G communication scheme can be applied thereto.

In the case of the transmission signal of the second communication scheme, the vertical polarization transmission signal may be divided into a vertical polarization transmission signal and the horizontal polarization transmission signal may be divided into a vertical polarization transmission signal and a horizontal polarization transmission signal by a MIMO scheme. Tx_1 'and the vertical polarization transmission signal LTE Tx_0 is transmitted to the antenna 3 through the first cable 1 and the horizontal polarization transmission signal LTE Tx_1 is transmitted through the second cable 2 to the antenna 3 3).

Here, each of the vertical polarized wave transmission signal LTE Tx_0 and the horizontal polarized wave transmission signal LTE Tx_1 separated from the transmission signal of the second communication method includes a reference signal RS Such a reference signal is the same as a pilot signal in the first communication method, and can be used for adjusting timing synchronization.

In the case of the reference signals included in the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1 of the second communication scheme, different frequencies (sub carriers) are used according to the application of the MIMO scheme The time between the transmission time point and the reception time point can be confirmed with respect to each of the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_l.

As a result, the vertical polarization transmission signal 3G Tx_0 of the first communication scheme and the vertical polarization transmission signal LTE Tx_0 of the second communication scheme are transmitted to the antenna 30 through the first cable 1, The horizontal polarization transmission signal 3G Tx_1 of the first communication scheme and the horizontal polarization transmission signal LTE Tx_1 of the second communication scheme are transmitted together through the cable 2 to the antenna 3.

Therefore, the antenna 3 has a structure of a dual-band dual polarization antenna capable of radiating both transmission signals received through the first cable 1 and the second cable 2.

Meanwhile, according to an embodiment of the present invention, the antenna 3 operates in such a manner that the transmission signals of the first communication scheme classified as the vertical polarization transmission signal and the horizontal polarization transmission signal are radiated together for the purpose of improving the output thereof .

In order to radiate the vertical polarized wave transmission signal (3G Tx_0) and the horizontal polarized wave transmission signal (3G Tx_1) together at the antenna (3), the vertical polarized wave transmission signal (3G Tx_0) It is presupposed that the phases of the signals (3G Tx_1) are the same.

In this regard, unlike the second communication scheme, the conventional first communication scheme does not use the MIMO scheme but uses the received signal (RX) diversity. Therefore, the dual- And receives the received signal in two paths of Rx_0 and Rx_1.

At this time, the transmission signal (Tx) of the first communication scheme is carried on the Rx_0 and Rx_1-side paths together in a single pass and transmitted.

As shown in FIG. 3, the signals radiated from the -45 ° and + 45 ° arrays of the dual polarization antenna are divided into a vertical polarization and a horizontal polarization. If the phases of the two paths are the same, The resulting horizontal or vertical polarizations will be summed together and can be canceled out if the phases are reversed.

For example, in a region where the coverage area to be serviced by the base station, such as the sea (including islands) or mountain trails, is 15 km or more in radius, the output of the transmission signal of the first communication method should be as high as possible do.

4, the transmission signal of the first communication method is divided into a vertical polarized wave transmission signal Tx_0 and a horizontal polarized wave transmission signal Tx_l When amplified by two power amplifiers, the amplified transmission signal is transmitted to the array of dual polarized antennas, which can provide more than twice the distance due to the 3 dB high output.

However, in the case of the vertical polarized wave transmission signal Tx_0 and the horizontal polarized wave transmission signal Tx_1 transmitted through the array of dual polarized antennas, since they are signals separated from a single transmission signal different from the second communication mode, orthogonality There is no orthogonality, so phase interference can occur between each other.

As a result, when the transmission signal of the first communication scheme is separately amplified by the vertical polarization transmission signal Tx_0 and the horizontal polarization transmission signal Tx_1 and then transmitted to the dual polarization antenna, no delay or phase difference between the two paths occurs , The length of the cable connected to the antenna input must be equal to or less than an integral multiple of the wavelength λ (eg λ).

However, in general, the antenna is located at the top of the steel tower installed on the roof of the building, or in the case of maritime service, it is installed in a mountain or the like.

Therefore, as shown in FIG. 5, the length of the cable connecting between the RF stage of the base station and the antenna needs to be long enough to reach 200-300 m. Therefore, the vertical polarization transmission signal (Tx_0) and the horizontal polarized wave transmission signal (Tx_1) due to the cable length difference.

Furthermore, since the first communication method uses 1.8 to 2 GHz band, when one wavelength (λ) corresponds to a cable length of 30 cm or less and the lengths of the cables are different even if the lengths are slightly different, the vertical polarized wave transmission signal (Tx_0) (Tx_1), which may cause distortion or cancellation of the signal.

For reference, when a phase difference occurs between the vertical polarized wave transmission signal Tx_0 and the horizontal polarized wave transmission signal Tx_ 1, distortion or offset of the signal occurs as shown in FIG.

6A illustrates a case where a slight phase difference is generated between the vertical polarization transmission signal Tx_0 and the horizontal polarization transmission signal Tx_l. In this case, the transmission signal received by the subscriber terminal is greatly distorted .

In the case of FIG. 6 (b), when a phase difference of 180 degrees between the vertical polarization transmission signal Tx_0 and the horizontal polarization transmission signal Tx_1 occurs, that is, a 1/2 wavelength λ, The intensity of the transmission signal received at the subscriber terminal may be significantly reduced from the original level, leading to a state in which the service can not be performed.

If the transmission signal is divided into a vertical polarized wave transmission signal Tx_0 and a horizontal polarized wave transmission signal Tx_1 for the purpose of improving the output of a transmission signal in the first communication scheme, the vertical polarized wave transmission signal Tx_0, A method of compensating a phase difference that may occur due to a difference in length between cables for transmitting the horizontally polarized wave transmission signal Tx_1 to the antenna is required.

7, the transmission signals (3G Tx_0 and 3G Tx_1) of the first communication scheme and the transmission signals (LTE Tx_0 and LTE Tx_1) of the second communication scheme are duplexed to reduce the cost of constructing the base station. Band combiner and then combines the combined transmission signals with the dual-band dual polarized antenna through the respective cables to transmit the transmission signal of the first communication scheme and the transmission signal of the second communication scheme together through the antenna Dual-band services are common.

Accordingly, in an embodiment of the present invention, in transmitting the vertical polarization transmission signal (3G Tx_0,) and the horizontal polarization transmission signal (3G Tx_1) of the first communication scheme to the antenna on the premise of the upper dual- A new method for compensating for the phase difference that may occur due to the difference in length is proposed. Hereinafter, this will be described in detail.

The receiving unit 100 receives the transmission signal of the second communication scheme through the first cable 1 and the second cable 2. [

More specifically, the receiving unit 100 receives, from the RF terminal of the base station via the first cable 1 for transmitting the vertical polarized wave transmission signal (3G Tx_0) of the first communication scheme to the antenna 3, (LTE Tx_0) of the second communication scheme to be transmitted is received at the front end of the antenna 3 at which the connection of the first cable 1 is terminated.

Likewise, the receiving unit 100 receives the horizontal polarization transfer signal (3G Tx_1) of the first communication scheme from the RF terminal of the base station via the second cable 2 for transmitting the signal to the antenna 3 Receives the horizontally polarized transmission signal (LTE Tx_1) of the second communication mode to be transmitted at the front end of the antenna 3 at which the connection of the second cable 2 is terminated.

Here, the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, which are transmitted through the first cable 1 and the second cable 2, And a reference signal RS for confirming the transmission time of each of the signals.

The measuring unit 200 measures the timing error using the transmission signal of the second communication mode received through the first cable 1 and the second cable 2.

More specifically, when the vertical polarized wave transmission signal LTE Tx_0 and the horizontal polarized wave transmission signal LTE Tx_1, which are transmitted through the first cable 1 and the second cable 2, respectively, are respectively received by the measuring unit 200, A vertical polarization transmission signal LTE generated from a difference in length between the first cable 1 and the second cable 2 based on the reception timing of the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, Tx_0) and the horizontal polarized wave transmission signal (LTE Tx_1).

At this time, the measurement unit 200 confirms the transmission time point from the base station RF terminal using the reference signal for each of the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, (LTE Tx_0) and the horizontal polarized wave transmission signal (LTE Tx_1) from the time difference between the reception time point and the reception time point.

That is, assuming that the transmission time points of the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, respectively, transmitted from the base station RF stage are the same, the first cable 1 for transmitting the respective transmission signals, (LTE Tx_0) received through the first cable 1 and the second cable 2 and the reception of the horizontally polarized transmission signal LTE Tx_1 The time points will be different from each other, and these different time differences can be measured as timing errors.

As a result, measuring the timing error between the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_ 1 means that a difference in length occurs between the first cable 1 and the second cable 2 Which is a vertical polarization transmission signal (3G0 Tx_0) of the first communication type and a horizontal polarization transmission signal (3G Tx_1), which are transmitted to the antenna (3) through the first cable (1) and the second cable Which means that there is a phase difference between them.

If a timing error is not measured between the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, the antenna 3 is connected to the first cable 1 and the second cable 2 via the first cable 1 and the second cable 2, It can be expected that no phase difference occurs between the vertical polarization transmission signal (3G0 Tx_0) of the first communication mode and the horizontal polarization transmission signal (3G Tx_1).

The calculation unit 300 calculates a length difference between the first cable 1 and the second cable 2 based on the measured timing error.

More specifically, when the timing error between the vertical polarized wave transmission signal LTE Tx_0 and the horizontal polarized wave transmission signal LTE Tx_l is measured, the calculation unit 300 calculates the first cable 1 corresponding to the measured timing error value, And the second cable (2).

Here, the timing error is measured as the difference between the time at which the vertical polarized wave transmission signal (LTE Tx_0) transmitted from the RF terminal of the base station at the same transmission time and the time at which the horizontal polarized wave transmission signal (LTE Tx_1) is received, 1 < / RTI > cable and the second cable (2).

Accordingly, the calculation unit 300 calculates the cable length capable of generating a time difference as much as a timing error value measured based on the signal transmission speed according to the conductor characteristics defined in the first cable 1 and the second table 2, .

As a result, the calculation unit 300 calculates the difference in length by the timing error value measured between the first cable 1 and the second cable 2, thereby compensating for the calculated length difference, The phase difference between the vertical polarization transmission signal 3G0 Tx_0 and the horizontal polarization transmission signal 3G Tx_1 of the first communication mode transmitted to the antenna 3 through the cable 1 and the second cable 2 .

Meanwhile, at least one of the first cable 1 and the second cable 2 according to an embodiment of the present invention includes a cable connector 4 that can connect a compensation cable for cable length adjustment.

The compensating for the calculated length difference mentioned above can be achieved by additionally connecting the compensating cable of the calculated length difference to the cable connector 4 or by removing the compensating cable connected to the cable connector 4 .

Here, the compensation cable includes a first communication type vertical polarized wave transmission signal (3G0 Tx_0) transmitted to the antenna 3 through the first cable 1 and the second cable 2, a horizontal polarized wave transmission signal 3G (Lambda) to one wavelength (lambda) so as to compensate for the maximum phase difference (1/2?

As described above, according to the phase compensation apparatus according to an embodiment of the present invention, transmission signals of a first communication scheme that does not support a MIMO (Multi Input Multiple Output) scheme are divided into a plurality of transmission signals, A first communication method that supports a MIMO scheme and that is based on a timing error value of a transmission signal of a second communication scheme transmitted in the same path as the transmission signal of the first communication scheme, It is possible to prevent the transmission signal from being distorted or offset due to the phase difference between the transmission signals by compensating the phase difference between the transmission signals of the communication system.

Hereinafter, the operation flow of the phase compensation apparatus according to the embodiment of the present invention will be described with reference to FIG. Here, for convenience of explanation, the configuration shown in FIG. 1 will be described with reference to corresponding reference numerals.

First, the receiving unit 100 receives the transmission signal of the second communication scheme through the first cable 1 and the second cable 2 (S110).

At this time, the receiver 100 is transmitted from the RF terminal of the base station to the antenna 3 through the first cable 1 for transmitting the vertical polarization transmission signal (3G Tx_0) of the first communication scheme to the antenna 3 (LTE Tx_0) of the second communication scheme at the front end of the antenna 3 at which the connection of the first cable 1 is terminated.

Likewise, the receiving unit 100 receives the horizontal polarization transfer signal (3G Tx_1) of the first communication scheme from the RF terminal of the base station via the second cable 2 for transmitting the signal to the antenna 3 Receives the horizontally polarized transmission signal (LTE Tx_1) of the second communication mode to be transmitted at the front end of the antenna 3 at which the connection of the second cable 2 is terminated.

Then, when the vertical polarized wave transmission signal LTE Tx_0 and the horizontal polarized wave transmission signal LTE Tx_1, which are transmitted through the first cable 1 and the second cable 2, respectively, are respectively received by the measuring unit 200, (LTE Tx_0) generated from the length difference between the first cable (1) and the second cable (2) based on the reception timing of each of the polarized wave transmission signal (LTE Tx_0) and the horizontal polarized wave transmission signal ) And the horizontal polarized wave transmission signal LTE Tx_1 (S120).

At this time, the measurement unit 200 confirms the transmission time point from the base station RF terminal using the reference signal for each of the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, (LTE Tx_0) and the horizontal polarized wave transmission signal (LTE Tx_1) from the time difference between the reception time point and the reception time point.

That is, assuming that the transmission time points of the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, respectively, transmitted from the base station RF stage are the same, the first cable 1 for transmitting the respective transmission signals, (LTE Tx_0) received through the first cable 1 and the second cable 2 and the reception of the horizontally polarized transmission signal LTE Tx_1 The time points will be different from each other, and these different time differences can be measured as timing errors.

As a result, measuring the timing error between the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_ 1 means that a difference in length occurs between the first cable 1 and the second cable 2 Which is a vertical polarization transmission signal (3G0 Tx_0) of the first communication type and a horizontal polarization transmission signal (3G Tx_1), which are transmitted to the antenna (3) through the first cable (1) and the second cable Which means that there is a phase difference between them.

If a timing error is not measured between the vertical polarization transmission signal LTE Tx_0 and the horizontal polarization transmission signal LTE Tx_1, the antenna 3 is connected to the first cable 1 and the second cable 2 via the first cable 1 and the second cable 2, It can be expected that no phase difference occurs between the vertical polarization transmission signal (3G0 Tx_0) of the first communication mode and the horizontal polarization transmission signal (3G Tx_1).

When the timing error is measured between the vertical polarized wave transmission signal LTE Tx_0 and the horizontal polarized wave transmission signal LTE Tx_l, the calculation unit 300 calculates the difference between the first cable 1 and the second cable 2 corresponding to the measured timing error value, 2 cables 2 (S130-S150).

At this time, the calculation unit 300 calculates a cable length (which can generate a time difference as much as a timing error value measured based on the signal transmission speed according to the conductor characteristic defined in each of the first cable 1 and the second table 2) Of the first communication scheme to be transmitted to the antenna 3 through the first cable 1 and the second cable 2 by compensating for the calculated length difference by calculating the vertical polarization transmission signal 3G0 Tx_0) and the horizontal polarized wave transmission signal (3G Tx_1).

As described above, according to an operation method of a phase compensation apparatus according to an embodiment of the present invention, transmission signals of a first communication scheme that does not support a MIMO (Multi Input Multiple Output) scheme are divided and transmitted through different paths And a timing error value of a transmission signal of a second communication mode, which is transmitted in the same path as the transmission signal of the first communication scheme, and which can be generated due to the different paths It is possible to prevent the transmission signal from being distorted or offset due to the phase difference between the transmission signals by compensating the phase difference between the transmission signals of the first communication scheme.

Meanwhile, the steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, or may be embodied in a computer readable medium, in the form of a program instruction, which may be carried out through various computer means. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

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, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the phase compensation apparatus and the operation method of the present invention, when a transmission signal of a communication method that does not support a MIMO (Multi Input Multiple Output) scheme is divided into a plurality of transmission signals and is transmitted to an antenna through a different path , It compensates for the phase difference between transmission signals that can be generated due to the different paths. Therefore, the present invention is not limited to the use of the related art, It is an invention that can be used industrially because it is practically possible to carry out clearly.

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Claims (5)

A receiving step of receiving a transmission signal of a second communication scheme transmitted to the antenna through a first cable for transmitting a transmission signal of a first communication scheme to an antenna and a second cable;
A measurement for measuring a timing error generated from a length difference between the first cable and the second cable based on a reception timing of each of the transmission signals of the second communication scheme received through the first cable and the second cable, step; And
Calculating a length difference between the first cable and the second cable based on the measured timing error so as to compensate the first cable or the second cable for the calculated length difference And compensating for the phase difference. The method according to claim 1,
The transmission signal of the first communication scheme includes,
A vertical polarized wave transmission signal and a horizontal polarized wave transmission signal classified from the same transmission signal,
The vertically polarized transmission signal may include:
The first cable or the second cable,
The horizontal polarized wave transmission signal,
Wherein the first cable or the second cable is transmitted to the antenna through the remaining portion of the first cable or the second cable in which the vertical polarization transmission signal is not transmitted. The method according to claim 1,
Wherein the transmission signal of the second communication mode, which is received through the first cable and the second cable,
A reference signal (RS) for confirming the transmission time point,
The timing error may be,
And the transmission time of the transmission signal of the second communication scheme received through the first cable and the second cable is measured from the time difference between the reception timings when the transmission time to be confirmed from the reference signal is the same Phase difference compensation method. The method according to claim 1,
Wherein at least one of the first cable and the second cable includes:
And a cable connector for connecting the compensation cable in relation to the length adjustment,
The compensation for the computed length difference may be performed by:
Wherein the compensation cable is further connected to the cable connector by the calculated length difference or the compensation cable is connected to the cable connector. A receiving unit for receiving a transmission signal of a second communication scheme transmitted to the antenna through a first cable for transmitting a transmission signal of a first communication scheme to an antenna and a second cable;
A measurement for measuring a timing error generated from a length difference between the first cable and the second cable based on a reception timing of each of the transmission signals of the second communication scheme received through the first cable and the second cable, part; And
And calculating a length difference between the first cable and the second cable based on the measured timing error so as to compensate the first cable or the second cable for the calculated length difference The phase compensation device comprising:

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