KR100711151B1 - A method for compensating time delay of a transmission signal in a radio communication system and a base station device therefor - Google Patents

Abstract

The present application discloses a transmission signal delay compensation method in a wireless communication system performing time delay compensation between a repeater and a base station according to time delay compensation data received from a user or measured by another device, and a base station apparatus for the same. A base station apparatus according to the present invention includes a transmitter for processing and transmitting transmission signals through a primary path channel and a secondary path channel, wherein a delay buffer is disposed on the primary path channel, and a time delay compensation corresponding to the secondary path channel. And a controller for receiving data and generating a delay value for the main path channel. Here, the delay buffer delays the transmission signal passing through the main path channel according to the delay value.

Base station, repeater, time delay, digital signal processor, delay buffer

Description

A method for compensating transmission delay in a wireless communication system and a base station apparatus therefor {A METHOD FOR COMPENSATING TIME DELAY OF A TRANSMISSION SIGNAL IN A RADIO COMMUNICATION SYSTEM AND A BASE STATION DEVICE THEREFOR}

1 is a conceptual diagram of a conventional wireless communication system.

2 is a conceptual diagram of a wireless communication system including a base station according to an embodiment of the present invention.

3 is a block diagram of a base station according to an embodiment of the present invention.

4 is a flowchart illustrating a method for transmitting a transmission signal of a base station according to an embodiment of the present invention.

5A is a graph illustrating a time delay between a main path transmission signal and a subpath transmission signal.

5B is a graph illustrating synchronization signals of a base station according to an embodiment of the present invention.

<Description of main parts of drawing>

1,10: wireless communication system 20,100: base station

21,110: transmitter 22: time delay compensation element

30, 201, 204: repeater 40,300: mobile communication terminal

111: modem section 112: digital signal processing section

113: link format 114: synchronization signal generator

115: time delay unit 116: distribution unit

117: delay buffer 118: analog signal processing unit

120: input unit 130: control unit

The present invention relates to a transmission signal delay compensation method and apparatus therefor in a wireless communication system, and more particularly, to a transmission signal delay compensation method for performing relay path delay compensation with a base station and a base station apparatus for the same.

Due to the rapid development of wireless communication technology and widespread use of mobile communication terminals, mobile communication has become an essential service for modern people. As a result, mobile communication service users want more high-quality services in all areas, ranging from mountainous wallpaper where mobile communication services cannot reach properly, or so-called radio shadow areas such as underground spaces with poor radio environment in urban areas. However, the area covered by one base station is limited, and it is inefficient to construct and operate the base station at a high cost in a low call area to provide high quality mobile communication service to all regions. . In order to solve the above problems, instead of additional base stations, various types of repeaters, such as optical repeaters, are installed to reduce the radio shadow area at low investment cost. However, the conventional wireless communication system has a problem in that a time delay of a transmission signal occurs due to a path difference between a repeater and a base station. To solve this problem, a device for compensating for the time delay is used.

1 is a conceptual diagram of a wireless communication system including a conventional base station. Referring to FIG. 1, a conventional wireless communication system 10 includes a base station 20, a repeater 30, and a mobile communication terminal 40.

The base station 20 receives a baseband transmission signal from a base station controller (BSC) (not shown) through a communication line connected thereto, modulates it into a preset intermediate frequency band, and then transfers the signal to the repeater 30. Send it out. The base station 20 modulates the transmission signal modulated in the intermediate frequency band into a preset high frequency band and radiates it to the air through the antenna ANT0. The transmission signal transmitted to the repeater 30 is modulated into a high frequency transmission signal by the repeater 30 and radiated through the antenna ANT1, which is later than the signal emitted through the antenna ANT0 of the base station 20. 40) is reached.

The propagation speed of light in free space is 3x10 ⁸ m / s. On the other hand, the propagation speed of light in the core of a communication line, for example an optical cable, is 2x10 ⁸ m / s, which is slower than in free space. Therefore, as shown in FIG. 5A, the transmission signal transmitted to the mobile communication terminal 40 through the repeaters 30, for example, the optical repeater, is directly transmitted from the base station 20 to the mobile communication terminal 40. There is a significant delay than the transmitted signal. When the time delay is neglected, when the mobile communication terminal 40 holding the call with the base station 20 moves in the direction of the repeater 30, the transmission signal transmitted from the repeater 30 is transmitted to the mobile communication terminal 40. There is a problem that the call quality is degraded, such as a call set up that is not within the range of the demodulation window length. To compensate for this, the transmission signal to be radiated through the antenna ANT0 among the transmission signals output from the transmitter 21 of the base station 20 is transmitted to the antenna ANT0 via the time delay compensation element 22. As the time delay compensating element 22, an element suitable for each time delay characteristic is used according to the positions of the base station 20 and the repeater 30 as physical elements. When the mobile communication terminal 40 is within the coverage of the base station 20 and the repeater 30, the mobile communication terminal 40 transmits the transmitted signal radiated through each of the antennas ANT0 and ANT1 of the base station 20 and the repeater 30. Simultaneously receive and perform wireless communication.

However, the conventional base station 20 determines the characteristics of the time delay compensation element 22 according to the time delay characteristics of each of the base station 20 and the repeater 30 when the repeater 30 is installed. Compensation element 22 is difficult to use. In addition, the time delay compensation device 22 has to consider carefully its physical characteristics in using it as a physical device, and thus the time delay compensation is not accurate. In addition, the time delay compensating element 22 may act as a loss on the path, that is, the main path, which is directly reached from the base station 20 to the mobile communication terminal 40, thereby affecting the characteristics of the base station 20.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and even when the repeater is additionally connected to the base station or the position shift of the base station or the repeater is performed, the time between the base station and the repeater transmission signal path more efficiently in signal transmission of the base station. An object of the present invention is to provide a method for performing delay compensation.

Another object of the present invention is to reduce the cost and provide a high quality mobile communication service by accurately performing the time delay compensation between the base station and the repeater transmission signal path without the addition of a separate physical element in the signal transmission of the base station. Another object of the present invention is to provide a method and an apparatus for compensating time delay between paths.

According to an aspect of the present invention, there is provided a base station apparatus of a wireless communication system, which includes: a transmission unit for processing and transmitting transmission signals through a primary path channel and a secondary path channel; a delay buffer is disposed on the primary path channel. Yes, and a control unit for receiving the time delay compensation data corresponding to the sub-path channel to generate a delay value for the main path channel. Wherein the delay buffer delays a transmission signal passing through the main path channel according to the delay value.

According to another aspect of the present invention, there is provided a base station apparatus of a wireless communication system, comprising: a transmitter for processing and transmitting transmission signals through a main path channel and a plurality of subpath channels-a main path delay on the main path channel; A buffer is disposed, a subpath delay buffer is disposed on at least one of the plurality of subpath channels, and a first delay is received by receiving time delay compensation data corresponding to the plurality of subpath channels. And a controller for generating a value and at least one second delay value. Here, the main path delay buffer delays the transmission signal passing through the main path channel according to the first delay value, and the subpath delay buffer transmits the transmission signal passing through the at least one subpath channel to the second path. Delay according to the delay value.

Preferably, the transmitter is a link format for receiving the transmission signal and converting it into a predetermined format, a distribution unit for distributing the converted transmission signal into transmission signals passing through the main path channel and each subpath channel, and the And a synchronization signal generator for outputting a synchronization signal according to the generated delay value, wherein the delay buffer receives and stores at least one of the distributed transmission signals and outputs the synchronization signal.

More preferably, the controller sets the data having the largest value among the plurality of input time delay compensation data as the maximum time delay compensation data, sets the maximum delay compensation data as the first delay value, and A value obtained by subtracting the delay compensation data corresponding to the subpath channel from the maximum delay compensation data is set as the second delay value.

According to still another aspect of the present invention, a transmission signal delay compensation method of a base station processing and transmitting transmission signals through a main path channel and a sub path channel, wherein the main path channel includes a delay buffer for delaying a transmission signal. The method includes receiving time delay compensation data corresponding to the subpath channel, generating a delay value for the main path channel, and delaying the transmission signal passing through the main path channel. Delaying according to the value.

According to another aspect of the present invention, a main path channel and a plurality of subpath channels-a main path delay buffer is disposed on the main path channel, and a subpath delay buffer on at least one subpath channel of the plurality of subpath channels. Is provided, wherein a transmission signal delay compensation method of a base station for processing and transmitting transmission signals is provided, the method comprising receiving time delay compensation data corresponding to the plurality of subpath channels and receiving a first delay value and at least Generating a second delay value, and wherein the main path delay buffer delays a transmission signal passing through the main path channel according to the first delay value, and wherein the subpath delay buffer is the at least one subpath. Delaying a transmission signal passing through the channel according to the second delay value.

Preferably, the delaying includes receiving the transmission signal and converting the transmission signal into a predetermined format, distributing the converted transmission signal into transmission signals passing through the main path channel and the respective subpath channels, and the distribution. Receiving and storing at least one of the transmitted signals, outputting a synchronization signal according to the generated delay value, and outputting the stored transmission signal according to the synchronization signal.

More preferably, the generating may include setting data having the largest value among the input plurality of time delay compensation data as maximum time delay compensation data, and setting the maximum delay compensation data as the first delay value. And setting a value obtained by subtracting delay compensation data corresponding to the subpath channel from the maximum delay compensation data as the second delay value.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a conceptual diagram of a wireless communication system including a base station according to an embodiment of the present invention. Referring to FIG. 2, the wireless communication system 1 according to an embodiment of the present invention receives a transmission signal from a base station 100 and a base station 100 through a communication line, for example, an optical cable, and transmits it to a high frequency band. Performs wireless communication with the plurality of repeaters 201-204 and at least one base station 100 and the plurality of repeaters 201-204, which are modulated into a transmission signal and radiated to the air through the antennas ANT1-ANT4. It includes a mobile communication terminal 300.

The base station 100 receives a baseband transmission signal from a base station controller (BSC) (not shown) and modulates the transmission signal of an intermediate frequency band and a high frequency band, for example, a code division multiple access (CDMA) band. Amplify and transmit. The modulated and amplified transmission signals are transmitted to the plurality of repeaters 201-204 and the mobile communication terminal 100, respectively. The base station 100 radiates a transmission signal, ie, a main path transmission signal, directly reaching the mobile communication terminal 300 through the antenna ANT0 to the air through the main path channel, and transmits a plurality of communication lines, for example, optical fibers. Each of the sub-path transmission signals transmitted to the mobile communication terminal 300 through the plurality of repeaters 201-204 through the cables, that is, the sub-path channel is transmitted.

Here, the transmission signal is a signal for performing wireless communication. In addition, the main path refers to a path of the transmission signal radiated through the antenna ANT0 of the base station 100 and directly reached to the mobile communication terminal 300, and the main path channel refers to the main path. The channel through which the main path transmission signal passes in order to transmit the transmission signal through a predetermined process. The secondary path is transmitted through one of the plurality of repeaters 201-204 through the communication line of the base station 100, and then radiated through the antennas ANT 1-ANT 4 of the repeaters 201-204. The path of the transmission signal reaching the mobile communication terminal 300 refers to a channel through which the subpath transmission signal passes in order for the subpath transmission signal to be transmitted through a predetermined process. it means.

The main path transmission signal and the sub path transmission signal are transmitted from the base station 100 to reach the mobile communication terminal 300, that is, the path time is different. This is due to the difference in the length of each path and the medium (free space, optical cable, etc.) forming the main path and the sub path. For this reason, even when the base station 100 simultaneously transmits the main path and the sub path transmission signals, the time at which each transmission signal reaches the mobile communication terminal 100, that is, the arrival time is different.

The base station 100 receives time delay compensation data indicating a difference in arrival time between the main path transmission signal and the respective subpath transmission signals among the transmitted transmission signals from a user or an operator of the base station 100. Generate delay values associated with the channel and the plurality of subpath channels, respectively. The base station 100, in order to compensate for the difference in the path time of the main path and the subpath transmission signal, the main path transmission signal and each subpath according to the time delay compensation data, i.e., according to the respective associated delay values. The transmission signal is delayed and transmitted. The base station 100 compensates for the difference in arrival time between the main path transmission signal and the respective sub path transmission signals to prevent the call disconnection of the mobile communication terminal 300, and the like. Significantly improve quality.

Figure 3 is a block diagram of a base station according to an embodiment of the present invention, Figure 5a is a graph showing the time delay between the main path transmission signal and the sub-path transmission signal, Figure 5b is a base station according to an embodiment of the present invention A graph showing synchronization signals. Referring to Figures 3, 5A and 5B, the base station 100 according to an embodiment of the present invention includes a transmitter 110, an input unit 120 and a controller 130.

The input unit 120 includes a keypad having letters, numbers, and various function keys, and generates a signal corresponding to a key input of a user or an operator. The input unit 120 receives time delay compensation data indicating a difference in arrival time between the main path transmission signal and each subpath transmission signal among the transmission signals transmitted through the transmission unit 110 from the user or operator, and correspondingly receives the corresponding signal. Outputs Preferably, the input unit 120 receives time delay data for all subpaths from a user and outputs a signal corresponding thereto.

The controller 130 performs an overall control operation of the base station 100, receives a signal corresponding to the time delay data from the input unit 120, and transmits delayed transmission signals according to the input signal. To control. In detail, the controller 130 receives a signal corresponding to the time delay compensation data for each subpath from the input unit 120 and sets the delay compensation data having the largest value as the maximum time delay compensation data. . The control unit 130 transmits the main path transmission signal so that the maximum time delay compensation data is set to a delay value and delayed by the delay value, that is, radiated through the antenna ANT0 of the transmission unit 110. To control. The control unit 130 generates each subpath transmission signal by subtracting the time delay compensation data of the corresponding subpath from the maximum time delay compensation data, that is, a delay value and delaying the generated delay value by the generated delay value, that is, The transmitter 110 is controlled to be transmitted to the repeaters 201-204 through a communication line corresponding to the secondary path.

That is, only the transmission signal for the sub path having the maximum delay compensation data among the main path and the sub path transmission signals without time delay is transmitted so that the main path and the sub path transmission signals arrive at the mobile communication terminal 300 simultaneously. The remaining transmission signals are transmitted after a certain time delay. This is because the transmission signal having the maximum delay compensation time reaches the mobile communication terminal 300 at the latest when there is no inter-path time delay compensation.

The transmitter 110 preferably includes a modem 111, a digital signal processor 112, and an analog signal processor 118. The transmitter 110 performs wireless communication with the plurality of repeaters 201-204 and the mobile communication terminal 300. In particular, the modem unit 111 performs demodulation and demodulation of a transmission signal for performing wireless communication, and in particular, inputs a baseband transmission signal including audio, video, data, etc. from a base station controller (not shown) through a communication line. And converts it into a digital transmission signal of a predetermined standard, for example, a digital in-phase quadrature-phase (IQ) signal. To this end, the modem unit 111 performs, for example, a quadrature phase shift keying (QPSK) modulation operation. The construction, operation, and function of the modem unit 111 are well known in the art, and thus detailed descriptions thereof will be omitted.

The digital signal processor 112 according to an embodiment of the present invention includes a link format 113, a synchronization signal generator 114, and a time delay unit 115. The digital signal processing unit 112 receives the modulated digital IQ signal from the modem unit 111, converts the digital IQ signal into a format suitable for transmission, and divides the converted digital IQ signal into a main path transmission signal and respective subpath transmission signals. The transmission signals are output under the control of the controller 130.

The link format 113 preferably receives the digital IQ signal from the modem unit 111 and converts the digital IQ signal into a format suitable for a predetermined transmission. For example, the link format 113 receives digital IQ signals arranged by a predetermined frequency allocation (FA) from the modem unit 111 and realigns them to be arranged by sector (for example, alpha, beta, gamma sector, etc.). Output in array.

The synchronization signal generator 114 preferably outputs synchronization signals for compensating for a difference in arrival time between the main path transmission signal and the respective subpath transmission signals under the control of the controller 130. The synchronization signals may be a series of clock signals.

The time delay unit 115 according to an embodiment of the present invention receives the rearranged digital IQ signals from the link format 113 and distributes them to the main path transmission signal and the respective subpath transmission signals ( 116 and a delay buffer 117 outputting the divided signals through independent channels, that is, at least one main path channel and a plurality of subpath channels, according to the synchronization signals input from the synchronization signal generator 114. It includes.

The delay buffer 117 receives and stores the remaining transmission signals from the distribution unit 116 except for the transmission signal having the maximum delay compensation time. The delay buffer 117 outputs each of the stored transmission signals according to the synchronization signal as shown in FIG. 5B input from the synchronization signal generator 114 such that all transmission signals arrive at the mobile communication terminal 300 simultaneously.

Preferably, the time delay unit 115 may be implemented by a field programmable gate array (FPGA). The FPGA is mounted on a transceiver card of a typical base station. Accordingly, cross-path time delay compensation can be effectively performed without adding a physical device.

The analog signal processing unit 118 receives the transmission signals through independent channels for each path from the digital signal processing unit 112, modulates the transmission signal into an analog transmission signal of an intermediate frequency band, and then modulates the transmission signal into a high frequency analog transmission signal. Output through independent channel for each path. The analog signal processor 118 modulates the main path transmission signal among the input transmission signals into an analog transmission signal of a high frequency band and radiates it to the air through the antenna ANT0. The transmission signal radiated into the air reaches the mobile communication terminal 100 directly. In addition, the analog signal processing unit 118 modulates each subpath transmission signals of the input transmission signals into analog transmission signals of an intermediate frequency band, and through communication lines corresponding to each subpath, for example, optical cables. It transmits to a plurality of repeaters 201-204, for example optical repeaters, connected on each subpath.

5A and 5B, for example, four repeaters are connected to the base station 100, and the base station 100 is an arrival time difference between the primary path and the first to fourth subpaths through the input unit 120. The first to fourth time delay compensation data are received. Among these, as shown in FIG. 5A, the value of the fourth time delay compensation data is the largest. The analog processor 118 of the transmitter 110 receives the fourth sub-path transmission signal through the distribution unit 116 and performs a predetermined process before transmitting. The delay buffer 117 of the transmitter 110 receives and stores the main path transmission signal and the first to third subpath transmission signals through the distribution unit 116. The controller 130 sets the fourth delay compensation data as a delay value for the main path transmission signal and transmits a value obtained by subtracting the first time delay compensation data from the fourth time delay compensation data and transmitting the first subpath. Set the delay value for the signal, and output the control signal accordingly.

The sync signal generator 114 generates a sync signal according to the control signal, as shown in FIG. 5B. The delay buffer 117 inputs a synchronization signal from the synchronization signal generator 114 after the fourth subpath transmission signal passes by the delay value for the first subpath transmission signal at the time when the fourth subpath transmission signal is output from the distribution unit 116. Receive. The delay buffer 117 outputs the stored first subpath transmission signal through the first subpath channel corresponding to the corresponding path. The delay buffer 117 receives the synchronization signal from the synchronization signal generator 114 after the fourth subpath transmission signal passes by the delay value for the main path transmission signal at the time when the fourth subpath transmission signal is output from the distribution unit 116. Outputs the transmission signal for the path through the main path channel. This operation is also performed on the second and third transmission signals. In this way, the transmission time of the transmission signal is appropriately adjusted according to the path through which the transmission signal passes, thereby controlling the time for the transmission signal to reach the mobile communication terminal 300 in the same manner.

4 is a flowchart illustrating a method for transmitting a transmission signal of a base station according to an embodiment of the present invention. Referring to FIG. 4, the control unit 130 of the base station 100 according to an embodiment of the present invention transmits each subpath, as illustrated in FIG. 5A, through the input unit 110 of the base station 100. Time delay compensation data for the signal is received from the user of the base station 100 (S100). In step S110, the controller 130 sets the data having the largest value among the input time delay compensation data as the maximum time delay compensation data.

In operation S120, the distribution unit 116 of the base station 100 receives a transmission signal to be transmitted to the mobile communication terminal 300 and distributes the transmission signal into a main path transmission signal and each subpath transmission signal. In step S130, the delay buffer 117 of the base station 100 stores the subpath transmission signals excluding the subpath transmission signal having the maximum time delay compensation data among the distributed main path transmission signals and the subpath transmission signals. do. At the same time, in step S140, the analog signal processing unit 140 of the base station 100 receives the sub-path transmission signal having the maximum time delay compensation data from the distribution unit 116, modulates the high-frequency analog signal, and then moves. Transmission to the communication terminal 300.

In operation S150, the controller 130 may generate a control signal instructing generation of a synchronization signal according to the input time delay compensation data, that is, the maximum time delay compensation data and the time delay compensation data for each subpath transmission signal. The signal is output to the synchronization signal generator 114 of the base station 100. In operation S160, the synchronization signal generator 114 receives the control signal and transmits the control signal to the delay buffer 117 of the base station 100 according to the control signal for the transmission signals as shown in FIG. 5B. Output sync signals. In step S170, the delay buffer 117 receives the synchronization signal, outputs the stored transmission signals to the analog signal processor 118 according to the input synchronization signal, and transmits the signal.

In describing an embodiment of the present invention, the time delay compensation data has been described as being input through an input unit of the base station, but the time delay compensation data may be measured by a separate time delay measuring device.

The present invention is not limited to the embodiments described above, and various modifications and changes can be made by those skilled in the art, which are included in the spirit and scope of the present invention as defined in the appended claims.

According to the present invention as described above, by performing the time delay compensation between the base station and the repeater transmission signal path according to the time delay compensation data received from the user or measured by another device, the repeater is further connected to the base station or the base station or Even when there is a position shift of the repeater, there is an effect that the time delay compensation between the paths can be more efficiently performed in the signal transmission of the base station.

In addition, according to the present invention as described above, it is possible to accurately perform the time delay compensation between the base station and the repeater transmission signal path without the addition of a separate physical element in the signal transmission of the base station to reduce costs and provide a high quality mobile communication service There is also an effect that can be done.

Claims (8)

A base station apparatus of a wireless communication system, A transmitter for processing and transmitting the transmission signals through the primary path channel and the secondary path channel, wherein a delay buffer is disposed on the primary path channel; and And a controller configured to receive time delay compensation data corresponding to the subpath channel and generate a delay value for the main path channel. And the delay buffer delays a transmission signal passing through the main path channel according to the delay value. A base station apparatus of a wireless communication system, Transmitter for processing and transmitting the transmission signals through the main path channel and the plurality of sub-path channels-a main path delay buffer is disposed on the main path channel, the at least one sub-path channel of the plurality of sub-path channels Delay buffer is placed, and And a controller configured to receive time delay compensation data corresponding to the plurality of subpath channels and generate a first delay value and at least one second delay value. The main path delay buffer delays the transmission signal passing through the main path channel according to the first delay value, and the subpath delay buffer transmits the transmission signal passing through the at least one subpath channel to the second delay value. Base station apparatus. The method of claim 2, wherein the transmitting unit A link format for receiving the transmission signal and converting the received signal into a predetermined format; A distribution unit for distributing the converted transmission signal into transmission signals passing through the main path channel and the respective subpath channels, and And a synchronization signal generator for outputting a synchronization signal according to the generated delay value. The delay buffer receives and stores at least one of the distributed transmission signals and outputs according to the synchronization signal. The method of claim 2, wherein the controller sets the data having the largest value among the plurality of input time delay compensation data as the maximum time delay compensation data, and sets the maximum delay compensation data as the first delay value. And setting a value obtained by subtracting delay compensation data corresponding to the subpath channel from the maximum delay compensation data to the second delay value. A transmission signal delay compensation method of a base station processing and transmitting transmission signals through a primary path channel and a secondary path channel, wherein the primary path channel includes a delay buffer for delaying the transmission signal. Receiving time delay compensation data corresponding to the subpath channel, Generating a delay value for the main path channel, and Delaying a transmission signal passing through the main path channel according to the delay value. A transmission signal through a main path channel and a plurality of subpath channels, wherein a main path delay buffer is disposed on the main path channel, and a subpath delay buffer is disposed on at least one subpath channel of the plurality of subpath channels. In the transmission signal delay compensation method of the base station for processing and transmitting the Receiving time delay compensation data corresponding to the plurality of subpath channels and generating a first delay value and at least one second delay value; and The main path delay buffer delays the transmission signal passing through the main path channel according to the first delay value, and the subpath delay buffer transmits the transmission signal passing through the at least one subpath channel to the second delay value. And delaying according to the transmission signal delay compensation method of the base station. The method of claim 6, wherein the delaying step Receiving the transmission signal and converting the received signal into a predetermined format; Dividing the converted transmission signal into transmission signals passing through the main path channel and the respective subpath channels; Receiving and storing at least one of the distributed transmission signals; Outputting a synchronization signal according to the generated delay value, and And transmitting the stored transmission signal in accordance with the synchronization signal. The method of claim 6, wherein the generating step Setting the data having the largest value among the plurality of input time delay compensation data as the maximum time delay compensation data, and And setting the maximum delay compensation data to the first delay value and setting a value obtained by subtracting the delay compensation data corresponding to the subpath channel from the maximum delay compensation data to the second delay value. Transmission signal delay compensation method.

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