KR20000072873A - Base station radio wave transceiving device and method thereof - Google Patents

Abstract

PURPOSE: A method and device for transceiving an electric wave of a base station is provided to delay a transmitting electric wave for a predetermined first delay time, and to delay a received electric wave for a predetermined second delay time, so that call disconnection generated due to a difference of time delay between a base station a repeater is prevented. CONSTITUTION: An electric wave transmitting unit amplifies signals inputted from a card-end through a transceiver(402). A directional coupler(404) delays signals outputted from the transceiver and signals to be transmitted to an optical repeater, to separate signals to be transmitted to a public network. A first delay unit delays the signals to be transmitted to the public network for a first delay time. The delayed signals are amplified in a high power amplifier(HPA), and an electric wave where a 35-chip is delayed is transmitted through an antenna. Signals delivered from a terminal are received through a receiving antenna in an electric wave receiving unit. Terminal signals received through the receiving antenna are switched and outputted through a duplexer(424). A low noise amplifier(LNA)(426) performs low-noise amplification of the signals outputted from the duplexer. A second delay unit delays the low-noise amplified signals for a second delay time. The delayed signals are mixed with the signals received from the optical repeater by the directional coupler, and inputted to the card-end through the transceiver. An agreement range between the first and the second delay time is decided. A first delay time range of the first delay unit is decided by referring to a modulation window of a mobile terminal, then by referring to a modulation window of a base station. A second delay time range of the second delay unit is decided by referring to the modulation window of the base station. The first and the second delay time satisfying the decided ranges are decided.

Description

Base station radio wave transceiving device and method

The present invention relates to an apparatus for transmitting and receiving a base station, and more particularly, to an apparatus and method for transmitting and receiving a base station for solving a call disconnection problem caused by a transmission time delay difference generated between cells and a terminal of a wireless transmission system. will be.

In a wireless mobile communication service including a code division multiple access (CDMA) scheme, since a single base station can cover a limited area, a plurality of base stations are provided per region. However, adding a base station requires a lot of investment. Therefore, instead of additional base stations, various types of repeaters, such as optical repeaters, are installed to expand coverage at a low investment cost. However, in the case of installing the repeater in this way, the transmission time delay generated in the process of relaying the signal between the base station and the repeater through the transmission medium such as laser, optical, microwave and the like due to the difference in the air wave transmission time delay through the air In the overlapping period between the repeater coverage area and the base station coverage area, a call is frequently broken.

In order to explain the difference in transmission time delay, FIG. 1 briefly illustrates a configuration of a general wireless transmission system using an optical repeater. In the wireless transmission system of FIG. 1, an optical repeater 12 is disposed in another area adjacent to the base station 10. The base station 10 and the optical repeater 12 are connected by an optical cable 14. Such an optical cable 14 is not installed in a straight line between the base station 10 and the optical repeater 12 is often installed by bypass.

On the other hand, the propagation speed of light in free space is 3 x 10 ⁸ m / sec. However, the propagation speed of light in the core of the optical cable is 2 × 10 ⁸ m / sec, which is slower than in free space. Therefore, the radio wave transmitted to the terminal 16 through the optical repeater 12 is significantly delayed than the radio wave transmitted from the base station 10 to the terminal 16. For this reason, when the terminal 16 holding the call at the base station moves toward the optical repeater 12, the call is frequently disconnected because the optical repeater signal on the traffic does not fall within the demodulation window length range of the supporting station traffic channel.

In order to solve this problem, the time delay factor is analyzed. First, the time delay occurring in the wireless transmission system includes a time delay between the base station 10 and the terminal 16 and the base station through the optical repeater 12 ( 10) and the time delay between the terminal 16. This time delay element will be described in detail for each communication path that can be formed in a communication and relay process between a base station, a terminal, and an optical repeater. As a communication path that can be formed during the communication and relay process between the base station, the terminal, and the optical repeater, a path formed through the base station through the terminal (hereinafter referred to as path A), the repeater, the terminal, and the repeater at the base station A path formed from the base station through the terminal (hereinafter referred to as path B), the path formed from the base station to the base station through the repeater (hereinafter referred to as path C), and the base station from the repeater, and the terminal through the terminal. There may be a path (hereinafter referred to as path D). Since the time delay factor is different depending on the path to be formed, the call is frequently disconnected for the above-mentioned reason.

2 is a diagram illustrating a conventional base station traffic channel and terminal window length extension method for solving such a problem. 1 and 2, when communication is performed through the path A, for example, in each of the three chips of the forward and reverse airwave delays (A1) between the base station 10 and the terminal 16, the base station 10 There are 36 chips in reverse system delay (B). In addition, when communication is performed through the path B, the unidirectional transmission medium delay T between the base station 10 and the optical repeater 12, the unidirectional processing delay R in the optical repeater 12, and the optical repeater 12 ), There are 45 chips unidirectional air delay (A2) between the terminal 16 and the reverse system delay (B) 36 chips at the base station 10.

When path A is formed, the round trip delay (RTD ₁ ) is the forward and backward air delay (A1) between the base station 10 and the terminal 16, each of three chips, and the reverse system delay (B) at the base station 10. 42 chips are added together. That is, the terminal signal is received at the base station with a delay of 42 chips. In this case, when the terminal moves from the base station area to the repeater area, a path B in which the terminal receives the repeater transmission signal and responds to the repeater may be formed.

When path B is formed, the round trip delay (RTD ₂ ) is the one-way transmission medium delay (T) between the base station 10 and the optical repeater 12, the one-way processing delay R in the optical repeater 12, and the optical The sum of 45 chips of the unidirectional airwave delay A2 between the repeater 12 and the terminal 16 and the 36 chips of the reverse system delay B of the base station 10 are 126 chips. In other words, the terminal signal in this case is received at the base station with a delay of 126 chips.

If the demodulation window length W _B in the base station traffic channel is 36 chips, for example, when it is tuned to the terminal signal received through the path A, the terminal delay component received through the path B is the demodulation window of the base station traffic channel. It cannot be obtained and demodulated at (W _B ). In addition, when the path A is formed, the terminal system time t ₁ has a delay component of 3 chips, whereas the path is formed, the terminal system time t ₂ is 45 chips. Have.

Therefore, if the demodulation window length W _M of the terminal is also 36 chips, for example, when it is tuned to the base station signal received through the path A, the repeater signal delay component received through the path B is converted into the demodulation window length of the terminal. W _M ) cannot be obtained and demodulated.

In the prior art for solving the time delay problem extends to W _B 'the base station demodulates the window length W _B. Thus, the terminal time delay component received through the base station antenna and the terminal time delay component received through the repeater antenna are obtained and demodulated. Similarly, the prior art extends the terminal demodulation window length from W _M to W _M '. Thus, the base station time delay component received through the base station antenna and the repeater time delay component received through the repeater antenna are obtained and demodulated.

However, in the conventional method, the time delay component of the terminals maintaining the call in the region where the base station coverage and the repeater coverage do not overlap is only one of the time delay component received by the base station antenna or the time delay component received by the repeater antenna. Therefore, even if the window length of the base station traffic is set only to W _B , there is a problem in that the performance of the traffic channel is degraded and the call quality is also degraded by extending the bandwidth to W _B '.

In addition, the window length may not be extended in the base station traffic channel. In this case, when the terminal moves from the base station coverage area to the repeater coverage area, there is a problem in that the call is disconnected because the terminal time delay component cannot be obtained and demodulated in the base station traffic channel.

3A and 3B are diagrams for explaining a conventional radio wave transmitting method for solving such a problem. Such a conventional radio wave transmitting method is disclosed in patent application 99-8971 entitled "Base station radio wave transmitting method and apparatus thereof" filed by the present applicant, the contents of which are incorporated herein by reference. Referring to FIG. 3A, a conventional radio wave transmitting method includes delaying a base station radio wave to a predetermined delay time BD corresponding to a difference between a base station time delay and a repeater time delay.

Referring to FIG. 3A, when the path B is formed, it may be demodulated in the demodulation window of the base station. That is, if the base station transmitter sets the delay time BD to 70 chips and transmits it, the round trip delay when the path A is formed is 112 chips and the round trip delay when the path B is formed is 126 chips. It's just a chip. Therefore, the call disconnection caused by the time delay difference between the base station and the repeater is prevented while maintaining the window length of the base station traffic channel.

On the other hand, referring to Figure 3b, a problem occurs when the path D is formed while the base station is tuned to the signal transmitted from the terminal connected by the path A. That is, the round trip delay (RTD ₃ ) in the path A represents 112 chips, while the round trip delay (RTD ₄ ) in the path D represents 84 chips. That is, the difference in round trip delay represents 28 chips. This problem is the same for path C.

Therefore, according to the conventional radio wave transmission method, when the terminal receives a signal from the repeater and responds to the base station or when the terminal receives a signal from the base station and responds to the repeater, the call is disconnected because the base station does not acquire the terminal signal. There is a problem that a phenomenon may occur. In order to prevent this, it is possible to extend the demodulation window of the base station, but there is a case that the window is not extended, and there is a problem that the expansion of the window degrades the signal quality.

In addition, referring to FIGS. 3A and 3B, the system time t ₃ at the terminal side in the path A represents a delay of 73 chips by adding a base station transmission delay (BD) 70 chip and an air delay (A1) 3 chip. _When the transmission signal of the terminal transmitted with ₃ as the system time is received by the terminal through the path D, the system time T ₄ at the terminal is the sum of the optical repeater medium delay, optical repeater processing delay, and air delay (T + R + A2). Shows the delay of 45 chips. Therefore, in order to prevent the disconnection of the call on the terminal side, there is a disadvantage that a window extension having many of the problems described above is required.

In addition, according to the conventional radio transmission method, since a radio wave is transmitted for each frequency alignment (FA) and sector, a relatively large delay apparatus must be installed. That is, according to the wireless transmission method according to the prior art there is a problem that the burden of the investment cost required to add a delay device is large.

An object of the present invention is to provide a base station radio transmission and reception apparatus capable of preventing a call disconnection when a terminal receives a signal from a repeater and responds to the base station.

In addition, another technical problem to be achieved by the present invention is to provide a base station radio wave transmission and reception method performed in the base station radio transceiver.

In addition, another technical problem to be achieved by the present invention is to provide a base station radio wave receiver having a relatively low burden of investment costs.

1 is a diagram illustrating a time delay between a base station and an optical repeater in a general wireless transmission system using an optical repeater.

FIG. 2 is a diagram illustrating a conventional base station traffic channel and terminal window length extension method for solving a time delay occurring in the wireless transmission system of FIG. 1.

3A and 3B are diagrams for explaining a conventional radio wave transmitting method.

4 is a block diagram showing the structure of a base station radio transceiver according to an embodiment of the present invention.

5a and 5d are views for explaining the operation of the base station radio transceiver according to the present invention.

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

40 radio wave transmitter, 402 first transceiver,

404 ... directional coupler, 406 ... 1st delay,

408 high power amplifier, 410 transmitting antenna,

42 radio receiver, 422 receiver antenna,

424 second delay, 426 duplexer,

428 low noise amplifier, 430 second transceiver.

In order to achieve the above object, a base station radio wave transceiver according to the present invention is a base station radio transceiver for transmitting and receiving radio waves at a base station of a wireless transmission system including a base station and a repeater connected to the base station, the predetermined amount of radio waves transmitted from the base station; First delay means for delaying by one delay time; And second delay means for delaying the radio wave received by the base station to a predetermined second delay time.

Further, in the apparatus, the first delay time and the second delay time may include A1 for a one-way air delay between the base station and the terminal, A2 for a one-way air delay between the repeater and the terminal, and T for a one-way transmission medium delay between the base station and the repeater. The unidirectional processing delay in the repeater is R, the demodulation window length of the base station traffic channel is W _B , the demodulation window length of the terminal is W _M , and the first delay time, which is the delay time of the first delay unit provided in the base station radio transmitter, When the second delay time that is the delay time of the second delay unit provided in the BD1 and the base station radio receiver is BD2, (c-1) Determining a range of the sum of the first delay time and the second delay time by calculating a; (c-2) Determining a range of a first delay time of the first delay unit considering a demodulation window of the mobile terminal by calculating a; (c-3) Determining a range of a first delay time of the first delay unit considering a demodulation window of the base station by calculating a; (c-4) Determining a range of a second delay time of the second delay unit considering the demodulation window of the base station by calculating a; And (c-5) determining a first delay time and a second delay time satisfying the range determined in steps (c-1) to (c-4).

In addition, the first delay means and the second delay means may include an element for processing radio waves and delay using the delay characteristic of the element. For example, the element may be a filtering element for performing filtering. Do.

According to another aspect of the present invention, there is provided a method for transmitting and receiving a base station radio wave by delaying a radio wave transmitted from a base station to a predetermined first delay time; And (b) delaying the radio wave received by the base station with a predetermined second delay time.

In accordance with another aspect of the present invention, a base station radio wave receiver according to the present invention includes a unidirectional air delay between the base station and the terminal A1, a unidirectional air delay between the repeater and the terminal A2, and a unidirectional transmission medium delay between the base station and the repeater T. When the unidirectional processing delay in the repeater is R and the demodulation window length in the base station traffic channel is W, the amount of delay time (BD) Delay means for delaying as much as characterized in that it comprises a.

Hereinafter, exemplary embodiments of a base station radio transceiver and a method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

4 is a block diagram illustrating a structure of a base station radio transceiver according to an embodiment of the present invention, and FIGS. 5A and 5B are diagrams for describing an operation of the base station radio transceiver according to the present invention. 5A and 5B are often referenced below.

Referring to Figure 4, the base station radio transceiver according to the present invention includes a radio wave transmitter 40 and a radio wave receiver 42. The wave transmitter 40 includes a transceiver 402, a directional coupler 404, a first delay unit 406, a high power amplifier 408 (HPA), and a transmit antenna 410. The radio receiver 42 also includes a receiving antenna 422, a duplexer 424, a low noise amplifier 426, a second delay unit 428, a directional coupler 430, and a transceiver 432.

Referring to the operation of the device, the input signal Si from the card-end in the radio transmitter 40 is amplified by the transceiver 402. The directional coupler 404 separates a transceiver 404, a signal (S _t) the (S _delay) after delaying the signal (S _cop) is sent out to the optical repeater signal to be sent out from the air output. The first delay unit 406 delays the signal S _delay to be sent to the air by the first delay time BD1. The delayed signal S _delay is amplified by the high power amplifier 408 (HPA), and a radio wave 412 delayed by 35 chips is transmitted through the antenna 412.

On the other hand, the signal sent from the terminal is received by the radio receiver 42 through the reception antenna 422. The terminal signal received through the reception antenna is switched and output through the duplexer 424. The low noise amplifier 426 (LNA) low noise amplifies the signal Rx output from the duplexer. The second delay unit 428 delays the low noise amplified signal Rxa by a predetermined delay time BD2. The delayed signal Rd is mixed with the signal R′cop received from the optical repeater by the directional coupler 430 and input to the card end through the transceiver 432. As a result, the base station radio wave transmission and reception apparatus according to the present invention delays transmission radio waves by a predetermined first delay time BD1 and delays the received radio wave by a predetermined second delay time BD2 to perform call processing.

Hereinafter, a method of setting the first delay time BD1 and the second delay time BD2 will be described in detail. The first delay time BD1 and the second delay time BD2 are A1 for one-way air delay between the base station and the terminal, A2 for one-way air delay between the repeater and the terminal, and T for one-way transmission medium delay between the base station and the repeater. The one-way processing delay in the repeater is determined in consideration of R, the demodulation window length of the base station traffic channel W _B , and the demodulation window length of the terminal W _M.

In this embodiment, the transmission delay (T + R) of the optical repeater is 42 chips, the unidirectional air delay delay (A1) between the base station and the terminal is 4 chips, and the unidirectional air delay delay (A2) between the repeater and the terminal is 5 chips, It is assumed that the internal processing delay B is 36 chips, the demodulation window length W _B of the base station traffic channel is 36 chips, and the demodulation window length W _M of the terminal is 40 chips. Here, the chip refers to a time corresponding to one period of the system clock of 1.2288 megahertz (MHz), that is, 0.814 microseconds (μsec).

First, when the first delay time, which is the delay time of the first delay unit provided in the base station radio wave transmitting unit, is BD1, and the second delay time, which is the delay time of the second delay unit provided in the base station radio wave receiving unit, is BD2. Next, the range of the sum of the first delay time BD1 and the second delay time BD2 is determined. That is, the sum of the first delay time BD1 and the second delay time BD2 (BD1 + BD2) ranges from 2 (42 + 1)-18 = 68 to 2 (42 + 1) + 18 = 104 chips. Is determined.

next time Next, the range of the first delay time BD1 of the first delay unit considering the demodulation window of the mobile terminal is determined. That is, the range of the first delay time BD1 considering the demodulation window of the mobile terminal is determined from (42 + 1)-20 = 23 to (42 + 1) + 20 = 63 chips.

next time Next, the range of the first delay time BD1 of the first delay unit considering the demodulation window of the base station is determined. That is, the range of the first delay time BD1 is determined from (42 + 1)-18 = 25 to (42 + 1) + 18 = 61 chips.

next time Next, the range of the second delay time BD2 of the second delay unit considering the demodulation window of the base station is determined. That is, the range of the second delay time BD2 is determined from (42 + 1)-18 = 25 to (42 + 1) + 18 = 61 chips.

Now, the first delay time BD1 and the second delay time BD2 satisfying the range determined in the above process are determined. The first delay time BD1 is preferably set to an intersection in the range between 23 and 63 chips and between 25 and 61 chips, that is, between 25 and 61 chips. For example, if the first delay time BD1 is set to 40 chips, the sum of the first delay time BD1 and the second delay time BD2 (BD1 + BD2) should be determined to be 68 to 104 chips. The second delay time BD2 may be determined within a 28 to 64 chip range. In this embodiment, the first delay time BD1 and the second delay time BD2 are set to the same 35 chip for convenience.

The first delay unit and the second delay unit 406 and 424 provided in the base station radio wave transmission and reception apparatus are provided for a purpose other than a delay to implement a delay time required to perform the function as a propagation delay. It is also possible. For example, it can be implemented as a propagation delay by outputting a signal delayed by a delay time necessary for the filtering operation by performing the filtering operation.

Referring now to FIGS. 5A and 5B, path A and path D, i.e., when the transmission output is received by the antenna of the base station while the terminal is tuned to the base station, and the terminal is tuned to the optical repeater. The round trip delay when the transmission output is received by the base station will be described.

First, in the case of the path A, if the transmission output is received by the antenna of the base station while the terminal is tuned to the base station, the round trip delay (RTD ₁ ') is the first delay unit 406 of the radio transmitter 40 35 delay delay (BD1), 4 unidirectional air delay (A1) from the base station to the terminal, 4 unidirectional air delay (A1) from the terminal to the base station, the second delay unit 424 of the radio receiver 40 ) Is the sum of 35 chips, which are the delay BD2, and 36 chips of the system delay B of the base station, that is, 35 + 4 + 4 + 35 + 36 = 114 chips.

On the other hand, if the path D is configured as the terminal moves to the repeater region in the path A, the round trip delay (RTD ₂ ′) when the transmission output is received to the base station while the terminal is tuned to the optical repeater is the optical transmission medium. Delay and one-way delay from the repeater to the terminal (T + R + A2: including the processing delay of the repeater) 47 chips, 4-way one-way delay (A1) from the terminal to the base station, the second delay unit of the radio receiver 40 At 424, the sum of 35 chips, which is the delay (BD2), and 36 chips of the system delay (B) of the base station, i.e., 47 + 4 + 35 + 36 = 122 chips.

That is, the round trip delay when the transmission output is received by the antenna of the base station while the terminal is tuned to the base station, and the round trip delay when the transmission output is received by the base station while the terminal is tuned to the optical repeater. The difference is only 122-114 = 8 chips. Accordingly, in the base station radio transceiver according to the present invention, even when the terminal receives a signal from the repeater and responds to the base station as the terminal moves from the base station to the base station, the received terminal signal is included in the processing window range of the base station. The call break can be prevented from being acquired.

In addition, the terminal system delay time (t ₁ ') when the base station signal is received by the terminal indicates 39 chips in which 35 chips of the base station transmission delay (BD1) and 4 chips of the air delay (A1) are added, and the terminal is transmitted to the terminal through an optical repeater. The terminal system time (t ₂ ′) when received represents 47 chips as the sum of the optical repeater medium delay and air delay (T + R + A2). That is, since the difference in system time is only 47-39 = 8 chips, it is within the demodulation window range of the terminal. Therefore, the effect of not having to expand the window on the terminal side can be achieved.

Next, with reference to FIGS. 5C and 5D, the round trip delay when the paths B and C are formed will be described.

First, in the case of path B, the round trip delay (RTD ₃ ') is the delay of the optical transmission medium in the forward and reverse directions, the processing delay of the repeater, and the unidirectional delay of the repeater to the terminal (T + R + A2). The system delay (B) adds up to 36 chips, that is, 47 + 47 + 36 = 130 chips.

In addition, in the case of path C, the round trip delay (RTD ₄ ') is a delay 35 chip of the first delay unit, a forward air delay 4 chip, the delay of the optical transmission medium and the processing delay of the repeater and the unidirectional delay 47 from the repeater to the terminal, And 36 chips of system delay (B) of the base station, that is, 35 + 4 + 47 + 36 = 122 chips.

Path round trip delays (RTD ₁ ′, RTD ₂ ′, RTD ₃ ′, RTD ₄ ′) for all paths represent the range of 114, 122, and 130 chips. That is, not only when the terminal responds to the base station in the state of being tuned to the base station or in response to the repeater in the state of being tuned to the repeater, but also when the terminal responds to the repeater in the state of being tuned to the base station or in the state of being tuned to the repeater Even when responding to the base station, since the received terminal signal is in the demodulation window range of the base station, it is possible to prevent the call disconnection because the base station cannot acquire the terminal signal.

On the other hand, if it is difficult to provide a delay unit in the radio wave transmitting apparatus, it may be considered to apply the base station radio wave receiving apparatus as shown in the radio wave receiving unit 42 of FIG. At this time, the delay time of the delay unit is set to correspond to the difference between the base station time delay and the repeater time delay. The terminal delay component received through the base station antenna The terminal delay component received through the repeater antenna is , The difference between the base station time delay and the repeater time delay , In other words, Becomes If the delay time is BD, It is preferable to set in the range of.

The base station radio receiver as described above can solve the time difference between the path A and the path B by delaying the received radio wave.

In this radio receiver, only two delay units may be provided for each sector irrespective of frequency allocation. For example, when applying to a radio transmitter in 4 FA and 3 sectors, 12 delay units must be provided. The radio wave receiver in 4 FA and 3 sectors can achieve the same effect even if only 6 delay units are installed.

As described above, the apparatus and method for transmitting / receiving a base station according to the present invention can prevent call disconnection caused by a time delay difference between the base station and the repeater while maintaining the length of the base station traffic channel and the demodulation window of the terminal. In addition, since the received terminal signal is included in the processing window range of the base station in all possible communication paths between the base station, the terminal, and the repeater, the call disconnection may be prevented because the base station cannot acquire the terminal signal.

Claims (7)

A base station radio wave transceiver for transmitting and receiving radio waves at a base station of a wireless transmission system including a base station and a repeater connected to the base station, First delay means for delaying a radio wave transmitted from the base station to a predetermined first delay time; And And second delay means for delaying the radio wave received by the base station to a predetermined second delay time. The method of claim 1, wherein the first delay time and the second delay time, Unidirectional air delay between base station and terminal A1, unidirectional air delay between repeater and terminal A2, unidirectional transmission medium delay between base station and repeater T, unidirectional processing delay at repeater R, demodulation window length of base station traffic channel W _B , and the demodulation window length of the terminal is W _M , and the first delay time, which is the delay time of the first delay unit installed in the base station radio transmitter, is BD1, the delay time of the second delay unit installed in the base station radio receiver. 2 When the delay time is called BD2, (c-1) Determining a range of the sum of the first delay time and the second delay time by calculating a; (c-2) Determining a range of a first delay time of the first delay unit considering a demodulation window of the mobile terminal by calculating a; (c-3) Determining a range of a first delay time of the first delay unit considering a demodulation window of the base station by calculating a; (c-4) Determining a range of a second delay time of the second delay unit considering the demodulation window of the base station by calculating a; And and (c-5) determining a first delay time and a second delay time satisfying the ranges determined in steps (c-1) to (c-4). The method of claim 1, wherein the first delay means and the second delay means, And a device for processing radio waves, and delaying using a delay characteristic of the device. The apparatus of claim 3, wherein the element is a filtering element that performs filtering. A base station radio wave transmission and reception method for transmitting and receiving radio waves at a base station of a wireless transmission system including a base station and a repeater connected to the base station, (a) delaying a radio wave transmitted from the base station to a predetermined first delay time; And (b) delaying the radio wave received by the base station to a predetermined second delay time. The method of claim 5, wherein the first delay time and the second delay time, Unidirectional air delay between base station and terminal A1, unidirectional air delay between repeater and terminal A2, unidirectional transmission medium delay between base station and repeater T, unidirectional processing delay at repeater R, demodulation window length of base station traffic channel W _B , and the demodulation window length of the terminal is W _M , and the first delay time, which is the delay time of the first delay unit installed in the base station radio transmitter, is BD1, the delay time of the second delay unit installed in the base station radio receiver. 2 When the delay time is called BD2, (c-1) Determining a range of the sum of the first delay time and the second delay time by calculating a; (c-2) Determining a range of a first delay time of the first delay unit considering a demodulation window of the mobile terminal by calculating a; (c-3) Determining a range of a first delay time of the first delay unit considering a demodulation window of the base station by calculating a; (c-4) Determining a range of a second delay time of the second delay unit considering the demodulation window of the base station by calculating a; And (c-5) determining a first delay time and a second delay time satisfying the ranges determined in steps (c-1) to (c-4). A base station radio wave reception apparatus for receiving radio waves at a base station of a wireless transmission system including a base station and a repeater connected to the base station, Unidirectional air delay between base station and terminal A1, unidirectional air delay between repeater and terminal A2, unidirectional transmission medium delay between base station and repeater T, unidirectional processing delay at repeater R, demodulation window in base station traffic channel When the length is W, the radio wave received by the base station is a predetermined amount of delay time (BD), Delay means for delaying by; base station radio wave reception apparatus comprising a.