KR20030022907A - Method for forming distribute antenna in simulcast transmission system - Google Patents

Abstract

PURPOSE: A method for forming distributed antennas in a simulcasting system is provided to optimize the installation of the distributed antennas upon simulcasting, so as to optimize a transceiving characteristic of a mobile terminal. CONSTITUTION: Signals of a mobile terminal(500) received in plural distributed antennas(410,420) are transmitted to a CBS(Center Base Station)(100). The difference of paths between the mobile terminal(500) and the distributed antennas(410,420) and the square root of the difference between the plural distributed antennas(410,420) are extracted from the transmitted signals. The path difference and the square root of the difference between the distributed antennas(410,420) are multiplied, and a multiplied value is divided by a light velocity, to calculate a signal delay time between the distributed antennas(410,420). And the minimum installation distance between the distributed antennas(410,420) is calculated from the calculated signal delay time.

Description

Method for forming distributed antenna in simulcast transmission system

The present invention relates to a method for forming a distributed antenna in a simultaneous broadcasting transmission system. In particular, the present invention relates to a method for forming a distributed antenna in a simultaneous broadcasting transmission system. It relates to an antenna forming method.

The mobile communication system is composed of a mobile terminal (cell phone), a base station (BTS), a base station controller (BSC) and a switching center (MSC), and a base station is provided between the mobile terminal and the base station controller. The signal format is changed to be suitable for the distributed antenna forming link and the wired link. The base station controller is a function of each element of the base station and a means of access between the cell operators, base station operation management, service state management of hardware and software in the base station, and call It performs monitoring functions such as resource allocation and configuration for traffic, information collection about base station operation, and base equipment related to base station operation, monitoring and fixing. The switching center configures an access point for user traffic between the base station controller management and the mobile communication network and the mobile switching center of the general telephone network or the same mobile communication system.

In the mobile communication system, there is a simultaneous broadcasting system having a plurality of base stations. The simultaneous broadcasting transmission system has a plurality of base stations and a phase difference of a signal generated by a time mismatch between the base stations and a base station in a signal overlapping area between the base stations and the base stations. It is used to prevent a decrease in reception rate due to

Various methods for automatically synchronizing message transmission of transmitters in a base station used in such a simultaneous broadcasting transmission system have been proposed and are currently in use.

For example, Korean Patent Application No. 1994-704297 (Method and Apparatus for Synchronizing Simultaneous Broadcasting Transmission System) is used. There is no particular mention of how to install the antenna.

An object of the present invention is to solve the problems of the prior art, it is possible to optimize the installation of the distributed antenna during the simultaneous transmission in the simultaneous broadcast transmission system, so that the simultaneous broadcast transmission that can optimize the transmission and reception characteristics of the mobile terminal It is to provide a method for forming a distributed antenna in a system.

In the distributed antenna formation method in the simultaneous broadcasting transmission system according to the present invention for achieving the object of the present invention, the product of the period and the optical speed of the pseudo noise code in a communication method using a plurality of distributed antennas through the distributed antennas An installation distance between the plurality of distributed antennas is obtained by dividing the path difference between the mobile terminal receiving the service and the distributed antennas.

Preferably, the installation distance between the distributed antennas is an installation distance between two distributed antennas, and the path difference between the plurality of distributed antennas is a path difference in the simultaneous dedicated area of the two distributed antennas.

And according to another feature of the present invention for achieving the above object, transmitting a mobile terminal signal received from a plurality of distributed antennas to a base station / controller, between the mobile terminal and a plurality of distributed antennas in the transmitted signal Obtaining a signal delay time between the distributed antennas by dividing a path difference and a square of distances between the plurality of distributed antennas, multiplying a path difference between the distributed antennas and a square of the distances between the distributed antennas by an optical speed, The minimum installation distance between the distributed antennas is calculated from the signal delay time.

Preferably, the minimum installation distance between the distributed antennas is a minimum installation distance between two distributed antennas.

The signal delay time is a value larger than the time of one pseudo noise (PN) chip of the pseudo noise code used in the communication scheme in which the distributed antenna is used.

In addition, the minimum installation distance is obtained by dividing the result of multiplying the optical speed by the period of the pseudo noise code used in the communication scheme using the distributed antenna divided by the path difference between the two distributed antennas of the plurality of distributed antennas and the mobile terminal.

1 is a view for explaining a method of forming a distributed antenna in a general simultaneous transmission system

FIG. 2 is a view for explaining a time delay device in the simultaneous transmission system shown in FIG.

3 is a diagram for explaining an optimal separation distance between distributed antennas in a simultaneous transmission system according to the present invention.

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

FIG. 1 is a view for explaining a method of forming a distributed antenna in a general simultaneous transmission system, and FIG. 2 is a view for explaining a time delay apparatus in the simultaneous transmission system shown in FIG.

The distributed antenna installation method in the simultaneous transmission system shows a distributed antenna installation method in a macro cell. In FIG. 1, a plurality of distributed antennas (first to fifth distributed antennas) are arranged in a macro cell 200. Type antennas 410, 420, 430, 440, and 450).

In this case, the first to fifth distributed antennas 410, 420, 430, 440, and 450 are connected to the base station / repeater 100.

A characteristic of the distributed antenna installation method in such a general simultaneous transmission system is that the distributed antennas are not installed directly facing each other. At this time, if each of the distributed antennas 410, 420, 430, 440, and 450 are installed so as not to directly face each other, fading is reduced, and the size of the received signal is increased by about twice.

In particular, when the base station and the repeater 100 for providing a communication service to the CDMA mobile terminal in the general simultaneous transmission system shown in FIG. 1 are appropriately distributed to increase the effect of the Rake Receiver. A time delay device 500 is installed between the antenna 400 and the base station / repeater.

In other words, the code division multiple access method uses a rake receiver to separate a multipath signal, which requires a minimum time delay between signals, and for such a delay, distributed antennas must be spaced apart or there must be a time delay device 500. It is.

In this case, the rake receiver is one of the important features of the code division multiple access method, and the rake receiver refers to a receiver having a function capable of separating two signals having a time difference (delay) from each other. It is a characteristic obtained by.

Among the phenomena affecting the transmission quality when communicating using electromagnetic waves, the most influential factor is fading due to multipath, and fading due to multipath is a phase difference (time delay) of a signal arriving at a receiver through different paths. Difference).

This fading reduces the size of the signal, resulting in intensive transmission errors. And time delay causes inter-symbol interference (ISI). In most of the communication methods using radio waves, fading is overcome to some extent using diversity techniques, and time delay is reduced by using equalizers that compensate each time delay.

That is, CDMA recognizes signals that are independent of each other even if they are received with a time difference, so that effects such as time diversity can be obtained. Such a receiver capable of separating signals arriving in different paths (or time differences) is called a rake receiver.

However, the time delay difference between the two signals is 1 chip (where the chip is used to distinguish the bits of data at intervals of one pulse of spreading code. In the case of QCDMA (Up-banded IS-95), the spreading rate is 1.2288 Mbps. If the time is shorter than 0.814㎲, signal separation by the rake receiver cannot be performed, which will adversely affect the signal.

Since the outdoor delay characteristic of a mobile communication environment (a macrocell: a cell having a cell radius of about 5 km to 20 km) is known to be about 2 dB to 3 dB, it is possible to obtain a great effect with a rake receiver in such an environment.

In this case, reference numerals 310 to 350 indicate transmission / reception regions of the first to fifth distributed antennas 410, 420, 430, 440, and 450.

3 is a view for explaining the optimum separation distance of the distributed antenna in the simultaneous transmission system according to the present invention.

Herein, the distance between the first and second distributed antennas 410 and 420 is L, and the distance between the midpoints of the first and second distributed antennas 410 and 420 and the center base station (CBS) 100 is determined. D, assuming that the output from the mobile terminal 500 is received by the two first and second distributed antennas (410, 420), the signal coming into the base station / repeater (CBS) 100 from the second distributed antenna 420 Has a delay time of T compared to the first distributed antenna 410.

At this time, T can be obtained by the following equation.

T = 2u / c + L / (c / 2) = (2u + 2L) / c

2u is a path difference between the mobile terminal 500 and two first and second distributed antennas 410 and 420, L is a distance between the first and second distributed antennas 410 and 420 as described above, and c is a free space. Luminous flux at (3 x 10 ⁸ m).

2u / c is a delay due to a path difference between the mobile terminal 500 and the two first and second distributed antennas 410 and 420, and L / (c / 2) is the first and second distributed antennas 410 and 420. A time delay by the coaxial transmission path between the base station / relay (CSB) 100 is shown.

At this time, the range of the path difference 2u between the mobile terminal 500 and the two first and second antennas 410 and 420 is simply 0 to L by the distance L between the first and second distributed antennas 410 and 420. Instead, the path difference in the simulcasting region made by the two distributed antennas 410 and 420 should be applied.

The simulcasting region width can be known as the simulcasting region between the first and second distributed antennas 410 and 420 when the distance L between the two distributed antennas 410 and 420 is known. When the transmission area width is W_4, the path difference between the mobile terminal 500 and the first and second distributed antennas 410 and 420 becomes 2u. In this case, the width of the simultaneous transmission area is the width from the midpoint between the first and second distributed antennas 410 and 420 toward the first and second distributed antennas 410 and 420. Since it is small, there is no problem in view of the communication between one distributed antenna and the mobile terminal 500. The simultaneous transmission area width W_4 between two distributed antennas is obtained by multiplying the distance between the first and second distributed antennas 410 and 420 by 0.14. That is, W_4 is known as 0.14L (m).

Therefore, the simultaneous transmission area width W_4 becomes 2u, which is a path difference between the mobile terminal 500 and the first and second distributed antennas 410 and 420.

At this time, in order for the signal transmission between the mobile terminal 500 and the base station / relay (CSB) 100 to be correct without distortion, the length d of the pulse in the baseband should be more than twice the time delay. That is, 2T <d.

When the heights of the first and second distributed antennas 410 and 420 are ha and hb, respectively, ha = hb = 5 m (Meter), and when the antenna height of the mobile terminal 500 is hm, hm = 1.5 m When the distance L between the first and second distributed antennas 410 and 420 is 300 m, and the path difference between the mobile terminal 500 and the first and second distributed antennas 410 and 420 is 2u = 42 m, the maximum allowable delay time is T. = 2.28 ms.

In this case, in case of CT-2 (aka city phone), which has a data rate of 72 Kbps, the allowable time delay is 6.95 ms or less. Since the allowable time delay is below 1.845 ㎲, the maximum allowable delay should be considered.

In general, the distance between distributed antennas should be about 500m in urban areas and about 1,700m in rural areas, which should take into account the density and topography of subscribers.The distance between distributed antennas and distributed antennas that transmit simultaneously is distributed through distributed antennas The minimum distance is determined according to the width SEC of the transmitted chip CHIP.

In the code division multiple access (CDMA) scheme, the number of chips of one PN code of the short PN code is 2 ¹⁵ (32768). The period of this PN code is 26.67 × 10 ^{-3 /} 32768 = 8.139 × 10 ^-7 (sec), and T is one chip when the delay of the received signal (multipath delay, etc.) is T. If larger than width Tc, the two signals can be distinguished through correlation. In other words, the correlation between the two signals is γ = 0, so they are distinguished. Therefore, T> Tc can be received regardless of the delay.

Therefore, the delay time T shown in Equation 1 may be expressed as Equation 2 below.

T = (2.14 × L) / c

In this case, as described above, since T &gt; Tc, Equation 2 may be represented by Equation 3 below.

(2.14 x L) / c> Tc

Here, Equation 3 may be represented by Equation 4 as follows.

L> (Tc × c) /2.14

That is, L> (8.139 x 10 ^-7 x 3 x 10 ⁸ ) /2.14.

Therefore, the distance between two distributed antennas should be at least 114.0981 (m).

The distributed antenna installation method in the simultaneous broadcast transmission system according to the present invention has the following effects.

First, the base station and the relay period distance can be optimized to reduce fading and improve reception sensitivity.

Second, if the length of the PN code used in each communication scheme is known, the optimal separation distance between antennas can be known, and thus the transmission / reception characteristics of the mobile terminal can be optimized.

Claims (7)

Obtaining the installation distance between the plurality of distributed antennas by dividing the product of the period and the optical speed of the pseudo noise code in a communication method using a plurality of distributed antennas by the path difference between the mobile terminal and the distributed antennas provided with the communication service through the distributed antennas A distributed antenna forming method in a simultaneous broadcasting transmission system, characterized in that. The method of claim 1, wherein the installation distance between the distributed antennas is an installation distance between two distributed antennas. The method of claim 2, wherein the path difference between the plurality of distributed antennas is a path difference in a simultaneous dedicated area of the two distributed antennas. Transmitting mobile terminal signals received from a plurality of distributed antennas to a base station / controller; Obtaining a path difference between the mobile terminal and a plurality of distributed antennas and a square of a distance between the plurality of distributed antennas in the transmitted signal; Obtaining a signal delay time between the distributed antennas by dividing a value obtained by multiplying a path difference between the distributed antennas and a square of the distance between the distributed antennas by an optical speed; And obtaining a minimum installation distance between the distributed antennas from the signal delay time. The method of claim 4, wherein the minimum installation distance between the distributed antennas is a minimum installation distance between two distributed antennas. 5. The distributed antenna of claim 4, wherein the signal delay time is greater than a time of a PN chip of a pseudo noise code used in a communication scheme in which the distributed antenna is used. Forming method. The path between the two distributed antennas of the plurality of distributed antennas and the mobile terminal is obtained by multiplying the optical speed by a period of a pseudo noise code used in a communication scheme using the distributed antenna. A distributed antenna forming method in a simultaneous broadcasting transmission system, characterized by dividing by a difference.