KR20000060567A - Base station radio wave transmitting method and device thereof - Google Patents

Abstract

PURPOSE: An apparatus for delivering propagations of a base station is provided to maintain calls even when a terminal is out of a base station coverage or a repeater coverage as maintaining widow length of a traffic channel in the base station, by generating terminal time delaying components received through a base station antenna and terminal time delaying components received through a repeater antenna within the window length obtained/demodulated in the traffic channel. CONSTITUTION: A signal(Si) inputted from a card end is amplified through a transceiver(402). A directional coupler(404) delays a signal(St) of the transceiver with a signal(Scop) delivered to an optical repeater, and separates a signal(Sdelay) delivered to the air. A delayer(406) delays the signal(Sdelay) to a delay time corresponding to a difference between a base station time delay and a repeater time delay. The signal(Sdelay) is amplified in a high power amplifier(HPA)(408), and a delayed propagation(412) is delivered through an antenna(410).

Description

Base station radio wave transmitting method and apparatus therefor

The present invention relates to a base station propagation method and apparatus, and more particularly, to a base station propagation method and apparatus for solving the call disconnection problem caused by the transmission time delay difference generated between the cells and the terminal of the 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 optical repeater as described above, since the optical transmission time delay through the optical cable and the air wave transmission time delay through the air are different between the base station and the repeater, a call is made in the overlapping section between the repeater coverage area and the base station coverage area. The problem frequently occurs.

In order to explain the difference in the transmission time delay, a configuration of a general wireless transmission system is briefly illustrated in FIG. In the wireless transmission system of FIG. 1A, the 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 moves toward the optical repeater 16, the call is frequently disconnected because the optical repeater signal on the traffic does not fall within the demodulation window length range.

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. FIG. 1B details the time delay that occurs in the system of FIG. 1A. 1B, there is a unidirectional air delay A1 between the base station 10 and the terminal 16 and a unidirectional system delay B at the base station 10 between the base station 10 and the terminal 16. . Further, between the optical repeater 12 and the terminal 16, 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, the optical repeater There is a unidirectional air delay A2 between the 12 and the terminal 16 and a unidirectional system delay B at the base station 10.

As a result, the terminal round trip delay in the base station area across the base station-terminal-base station can be expressed as RTD1, and the terminal round trip delay in the repeater area across the base station-relay-terminal-relay-base station. Can be expressed as RTD2. At this time, if the demodulation window length in the base station traffic channel is W, the terminal round trip delay (RTD2) in the repeater region is too large to obtain and demodulate the terminal delay component received by the repeater antenna.

2 is a diagram illustrating a conventional base station radio wave transmission method for solving such a time delay problem. Referring to FIG. 2, according to the conventional base station propagation method for solving the time delay problem, the window length is extended from W to W '. 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. However, in the conventional base station propagation method, the time delay component of a terminal maintaining a call in an area where the base station coverage and the repeater coverage do not overlap is either a time delay component received by the base station antenna or a time delay component received by the repeater antenna. Since only one signal is received, even if the window length of the base station traffic is set to W, a sufficient amount is extended to W ', thereby degrading the performance of the traffic channel and reducing the call quality.

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.

An object of the present invention is to provide a base station propagation method capable of acquiring and demodulating a terminal time delay component without expanding the window length of the base station traffic channel.

Another object of the present invention is to provide an apparatus for transmitting a base station radio wave for implementing the above method.

FIG. 1A is a diagram for describing a time delay between a base station and a repeater in a general wireless transmission system.

FIG. 1B is a detailed view of a time delay occurring in the system of FIG. 1A.

2 is a view for explaining a conventional base station radio wave transmission method for solving the time delay problem.

3 is a view for explaining a base station radio wave transmission method according to the present invention.

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

5 is a block diagram illustrating another implementation of the delay unit of FIG. 4.

<Description of the code | symbol about the principal part of drawing>

A1 ... one-way air delay between the base station and the terminal,

B ... one-way system delay at the base station,

T ... unidirectional transmission medium delay between base station and optical repeater,

R ... one-way processing delay in optical repeater,

A2 ... unidirectional air delay between the optical repeater and the terminal,

W ... demodulation window length in base station traffic channel,

BD ... delay time,

RTD ... terminal round trip delay in base station area,

RTD '... Delayed terminal round trip delay in the base station area.

In order to achieve the above object, the present invention provides a method for transmitting a base station in a base station of a wireless transmission system including a base station and a repeater connected to the base station. And delaying by a predetermined delay time corresponding to the difference in delay.

The delay time is unidirectional air delay between the base station and the terminal A1, unidirectional air delay between the repeater and the terminal A2, unidirectional transmission medium delay between the base station and the repeater T, unidirectional processing delay at the repeater R, base station traffic When the demodulation window length in the channel is W, the delay time amount BD is It is preferable to set to.

In addition, the delay time BD may be set by measuring a forward delay time of the repeater signal based on the base station signal at the terminal.

In addition, the step (a) may include the step of delaying using the delay characteristics of the (a-1) device. Step (a-1) may include delaying using the filtering characteristic of the filtering element and using the delay characteristic of the filtering element.

In order to achieve the above object, the base station radio wave transmission apparatus according to the present invention is a radio wave transmission apparatus provided in a base station of a wireless transmission system including a base station and a repeater connected to the base station, the base station time delay and repeater time delay And propagation delay means for delaying the delay with a predetermined delay time corresponding to the difference of.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the base station radio wave transmission method and apparatus according to the present invention.

3 is a diagram illustrating a base station radio wave transmission method according to the present invention. Referring to FIG. 3, in the base station radio wave transmission method according to the present invention, a base station delays and outputs a radio wave by a predetermined delay time corresponding to a difference between a base station time delay and a 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 Therefore, if the delay time is BD,

It is preferable to set in the range of.

As such, when the base station delays and outputs the radio wave, the RTD, which is a terminal round trip delay in the base station area, is further delayed by the amount of delay time BD and shifted to RTD 'as shown. As a result, the terminal time delay component received through the base station antenna and the terminal time delay component received through the repeater antenna may exist within a window length W that can be obtained and demodulated in the base station traffic channel. Therefore, even when the terminal moves out of base station coverage or repeater coverage, the call may be maintained without disconnection.

The base station radio wave transmission method as described above may be implemented in the radio wave transmission apparatus of the base station. 4 is a block diagram illustrating a structure of a base station radio wave transmitting apparatus according to an embodiment of the present invention for implementing the above method. Referring to FIG. 4, the apparatus for transmitting base stations according to the present invention includes a transceiver 402, a directional coupler 404, a delay unit 406, a high power amplifier 408, and an antenna 410. Equipped. The delay time setting in the delay unit 406 is determined by the difference between the base station time delay and the repeater time delay. Such a delay time may be measured through a terminal delay measurement.

Referring to the operation of the device, the input signal Si from the card end 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 delay unit 406 delays the signal S _delay to be sent to the air with a delay time corresponding to the difference between the base station time delay and the repeater time delay. For example, the time delay difference between the two signals received at the terminal between the optical repeater and the base station installed through the optical transmission path of about 5 km is about 37 chips as a result of the terminal DM measurement. 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). In this case, if the window length of the base station traffic channel is set to 36 chips, the base station delay time is On chip Set between chips, ie between 46 and 75 microseconds. The delayed signal S _delay is amplified by the high power amplifier 408 (HPA), and the delayed radio wave 412 is transmitted through the antenna 412.

As described above with reference to FIG. 3, when the base station delays and outputs the radio wave, the RTD, which is a terminal round trip delay in the base station area, is further delayed by the delay time BD and shifted to the RTD ′, thereby increasing the base station traffic channel. The terminal time delay component received through the base station antenna and the terminal time delay component received through the repeater antenna may exist within the window length W that can be obtained and demodulated in the. Accordingly, the call may be maintained without being disconnected even when the terminal moves out of base station coverage or repeater coverage as the terminal moves while maintaining the window length of the base station traffic channel.

The delay unit 406 provided in the base station radio wave transmitting apparatus may be provided for a purpose other than a delay, and may implement a delay time required to perform the function as a propagation delay.

5 illustrates another implementation of the delay unit 406 in a block diagram. Referring to FIG. 5, the delay unit 406 includes a first multiplier 502, a filter 504, a second multiplier 506, and a frequency generator 508.

Referring to the operation of the delay unit 406, the first multiplier 402 multiplies the input signal S ′ _cd by the signal f ₂ output from the frequency generator 508 to thereby obtain the first signal f _1. -f ₂ ) Filter 504 and outputs the signal (f ₁ -f ₂₎ filtering by performing a predetermined filtering operation for a first signal (f ₁ -f _2). A second multiplier 506, and outputs the signal (f ₁₎ of the delayed frequency f ₁ by multiplying a signal (f ₂₎ output from the filtered signal (f ₁ -f ₂₎ and the frequency generator (508). The amount of time delay can be appropriately set according to the type and arrangement of elements used in the filter. In other words, it is possible to implement the required propagation delay by using a device for a function other than a delay such as filtering.

As described above, the base station propagation method according to the present invention can prevent the call disconnection caused by the time delay difference between the base station and the repeater while maintaining the window length of the base station traffic channel.

Claims (10)

A method for transmitting radio waves in a base station of a wireless transmission system including a base station and a repeater connected to the base station, (a) delaying the base station propagation to a predetermined delay time corresponding to the difference between the base station time delay and the repeater time delay. The method of claim 1, wherein the delay time is 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 delay time amount (BD), The base station radio wave transmission method characterized by the above-mentioned. 3. The method of claim 2, wherein the amount of delay time BD is set by measuring a forward delay time of a repeater signal based on a base station signal at a terminal. According to claim 1, wherein the step (a), and (a-1) delaying using the delay characteristic of the device. 5. The method of claim 4, wherein step (a-1) is a step of delaying using the filtering characteristic of the filtering element and using the delay characteristic of the filtering element. A radio wave transmitting apparatus provided in a base station of a wireless transmission system including a base station and a repeater connected to the base station, And propagation delay means for delaying the base station propagation to a predetermined delay time corresponding to the difference between the base station time delay and the repeater time delay. The method of claim 6, wherein the propagation delay means, 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 delay time amount (BD), The base station radio wave transmission apparatus characterized by the above-mentioned. 8. The apparatus of claim 7, wherein the amount of delay time BD is set by measuring a forward delay time of a repeater signal based on a base station signal at a terminal. 7. The apparatus of claim 6, wherein the propagation delay means is provided for a function other than a delay to implement a delay time required for performing the function as a propagation delay. The base station radio wave transmitting apparatus according to claim 9, wherein the propagation delay means is a filtering element.