KR20010046118A - Multisector base station apparatus of communication system - Google Patents

Abstract

PURPOSE: A multi-sector base station apparatus of a communication system is provided to implement multi-sector base station of above 6 sectors in volume of BCP(BTS Control Processor) and CCP(Call Control Processor), thereby reducing interference with other base station. CONSTITUTION: The first to the N antennae(Ant1-AntN) are installed in each cell region instead of base stations. The first through the N optical/RF converters(10-1 - 10-N) are installed in each cell region instead of base stations together with the first through the N antennae and change the RF signal processed by the first through the Nth antennae into light signal. The first through the Nth optical cables(20-1 - 20-N) transmits and receives the light signal converted from the first thorugh the N optical/RF converters. The first through the Nth RF/optical converters(30-1 - 30-N) are installed in multi-sector base station positioned in a certain constant region and change light signal transmitted and received to/from the first through the N optical cable into an RF signal. The first to the N RF input/output terminals(40-1 - 40-N) transmit and receive the RF signal transmitted from the first through the N RF/optical converters as sector 1 to sector N. Therefore, a cell region is formed by each sector of multi sector base station.

Description

Multisector base station apparatus of communication system

The present invention relates to a multisector base station of various communication systems using a code division multiple access (CDMA) scheme, wherein the multisector base station is not directly installed in each cell area. In order to increase base station capacity and coverage and save system resources by installing only the Remote Antenna and the Optical / RF Converter which are connected to each sector in the base station at the base station location. A multisector base station apparatus of a communication system.

In general, the capacity of various communication systems such as DCS (Digital Cellular System), PCS (Personal Communication System), and satellite communication system using CDMA method satisfy both of them in consideration of forward link capacity and reverse link capacity in case of single cell. In the range, the capacity of the reverse link is usually less than the capacity of the forward link, so the capacity of the system is determined by the capacity of the reverse link.

In this case, the capacity of the CDMA communication system can be expressed by Equation 1 below.

Where C is the maximum number of concurrent users of an omni or sector base station,

W / R: (bandwidth) / (data rate) as processing gain,

F: frequency reuse efficiency,

S: Sectorization gain (when omni base station; 1, 3 sector base station; 2.55),

Eb / No: (energy / noise power density per bit).

In Equation 1, F denotes interference from another base station as a frequency reuse efficiency. In the CDMA scheme, the capacity of the base station is limited by the F because of the characteristic that the capacity is limited by the interference.

In particular, as the number of sectors increases, the interference between sectors increases, and the efficiency due to the sector increase decreases significantly.

Therefore, the number of sectors of the base station currently used so far is up to 6 sectors, and no more sector base stations are used.

On the other hand, in the conventional case where each base station is installed in each cell area as shown in Figure 1, the capacity that can be accommodated by one base station is approximately 24 if the maximum number of simultaneous users base station, three sector base station The case is limited to 60 people.

At this time, the capacity of the three sector base station is less than three times the capacity of the omni base station.

However, even in this case, there is a problem in that a new base station should be installed due to the limitation in terms of capacity even in a place where radio waves can be propagated far away due to a good wireless environment, and a multisector base station of 6 sectors or more is installed due to high user density. Problems have also arisen due to inter-sector interference.

Here, the base station capacity determined as described above is readjusted in consideration of the soft handoff ratio with other base stations. In the soft handoff area with other base stations, one terminal is connected to two base stations and is connected to two call channels. Therefore, the efficiency of the call channel is reduced by half.

That is, if the handoff ratio is HR, the maximum number of simultaneous use considering the handoff ratio is as shown in Equation 2 below.

As described above, in the soft handoff area with other base stations, since one terminal is connected to two communication channels at the same time, there is a problem in that the efficiency of the communication channel is lowered to maximize the capacity.

In other words, the handoff method is a soft handoff method and a softer handoff method. The soft handoff method is performed at the time of handoff with another base station. It is communicating with two channels at the same time. Softer handoff method is performed when handoff between sectors in one base station. Since the channel is shared between sectors, only PN offset is changed to new sector value when connected to the channel of previous sector. In other words, it communicates with one channel during handoff.

In addition, in the prior art, a considerable cost is required to secure sufficient space for installing the base station equipment, and when the base station is expanded or the base station is moved according to the additional capacity or coverage required even after the base station is installed once after the wireless network design. In order to change the location of the base station, the entire base station has to be removed / relocated, so there is a problem in that a significant loss in cost and time occurs.

The present invention has been made to solve the problems caused by the conventional base station shape and installation method, the purpose of the six sectors within the capacity of the BCP (BTS Control Processor) and CCP (Call Control Processor) in the CDMA communication system The above-described multi-sector base station is implemented, and only the remote antenna and the optical / RF converter are installed without directly installing the base station in each cell area, and then connected to each sector of the multi-sector base station through an optical cable to each sector of the multi-sector base station. Formation of one cell area reduces interference with other base stations, implements softer handoff during handoff between cells, increases base station capacity and coverage, increases efficiency of base station equipment, system resources, base station installation space and cost. It is to provide a multi-sector base station apparatus of a communication system to save the cost.

1 is a view showing a base station arrangement in a conventional communication system,

2 is a block diagram of a multi-sector base station apparatus of a communication system according to the present invention;

3 is a view showing a connection state between each sector of the multi-sector base station and the antenna installed in each cell area of the communication system according to the present invention.

<Explanation of symbols for main parts of drawing>

Ant1 to AntN: first to Nth antennas

10-1 to 10-N: 1st to Nth optical / RF converter

20-1 to 20-N: 1st to Nth optical cable

30-1 to 30-N: First to Nth RF / optical converters

40-1 to 40-N: First to Nth RF input / output terminals

The multisector base station apparatus of the communication system of the present invention for achieving the above object provides a first to Nth antenna and a first to Nth optical / RF converter in place of a base station in each cell region. After the N optical / RF converter is connected to the first to Nth RF / optical converters in the multisector base station through the first through Nth optical cables, one cell area is formed with each sector of the multisector base station. First to Nth RF / optical converters of multi-sector base stations through the first to Nth optical cables by converting RF signals received through the first to Nth antennas into optical signals in the Nth to Nth optical / RF converters. And then converts the optical signal received through the first through N-th optical cables from the first through N-th RF / optical converter into an RF signal and transmits the RF signal to the first through N th RF input / output terminals. The reception processing is performed for each of 1 to sector N.

Hereinafter, the configuration and operation of a multi-sector base station apparatus of a communication system according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram of a multi-sector base station apparatus of a communication system according to the present invention, wherein first to N-th antennas Ant1 to Antnt installed in place of a base station in each cell area where a base station is to be installed, and a base station to be installed. The first to Nth antennas Ant1 to AntN are provided in each cell area together with the first to Nth antennas Ant1 to AntN to convert the RF signals transmitted and received by the first to Nth antennas Ant1 to AntN into optical signals. First to Nth optical / RF converters 10-1 to 10-N and first to Nth optical / RF converters 10-1 to 10-N for transmitting and receiving optical signals converted by the first to Nth optical / RF converters 10-1 to 10-N. Optical fibers installed in the N-th optical cables 20-1 to 20-N and multi-sector base stations located in a predetermined region, and transmitted and received through the first to N-th optical cables 20-1 to 20-N. First to Nth RF / optical converters 30-1 to 30-N for converting signals into RF signals and transmitted from the first to Nth RF / optical converters 30-1 to 30-N. RF signal is transmitted by sector 1 to sector N It consists of the first to N RF input and output terminals (40-1~40-N) to process new.

The first to Nth antennas Ant1 to AntN and the first to Nth optical / RF converters 10-1 to 10-N are configured in place of the base station in each cell area where the base station is to be installed. The first to Nth RF / optical converters 30-1 to 30-N and the first to Nth RF input / output terminals 40-1 to 40-N are provided in a multisector base station consisting of sectors 1 to sector N. to be.

The first to Nth antennas Ant1 to AntN and the first to Nth optical / RF converters 10-1 to 10-N provided in place of the base station are the first to Nth optical cables 20-1 to 20. -N) is connected to the first to Nth RF / optical converters 30-1 to 30-N in the multisector base station.

3 is a view showing a connection state between each sector of the multi-sector base station and the antenna installed in each cell area of the communication system according to the present invention. Each state (sectors 1 to N) is shown connected via an optical cable.

The operation of the multi-sector base station apparatus of the communication system according to the present invention configured as described above is as follows.

In the present invention, first to Nth antennas Ant1 to AntN and first to Nth optical / RF converters 10-1 to 10-N are provided in each cell region instead of the base station. The optical / RF converters 10-1 to 10-N are connected to the first through Nth RF / optical converters 30-1 through the first through Nth optical cables 20-1 through 20-N. 30-N) to form one cell area with each sector of the multi-sector base station.

In the first to N-th optical / RF converters 10-1 to 10-N, the RF signal of the terminal processed through the first to N-th antennas Ant1 to AntN is input and converted into an optical signal. The first through N th optical cables 20-1 through 20-N are transmitted to the first through N th RF / optical converters 30-1 through 30-N of the multisector base station.

Then, the first through N-th RF / optical converters 30-1 through 30-N of the multi-sector base station receive the optical signals received through the first through N-th optical cables 20-1 through 20-N. The signal is converted into an RF signal and transmitted to the first to Nth RF input / output terminals 40-1 to 40-N.

Accordingly, in the first to N-th RF input / output terminals 40-1 to 40-N, the sectors 1 to RF signals transmitted from the first to N-th RF / optical converters 30-1 to 30-N are received. Receive processing is performed for each sector N.

On the contrary, in the first to N-th RF / optical converters 30-1 to 30-N of the multi-sector base station, RF signals transmitted and processed by the first to N-th RF input / output terminals 40-1 to 40-N are received. After converting to an optical signal, the first to Nth optical / optical converters 10-1 to 10-N of each cell area are transmitted through the first to Nth optical cables 20-1 to 20-N. .

Then, in the first to Nth RF / optical converters 10-1 to 10-N of each cell region, the RF signals are transmitted through the first to Nth optical cables 20-1 to 20-N. The signal is converted into a signal and received and processed by the terminal in each cell area through the first to Nth antennas Ant1 to AntN.

As described above, in the present invention, by connecting each sector of a multi-sector base station located in a certain area with an antenna located in each cell area through an optical cable, all cells are formed by one base station in the conventional manner. Since cells are formed by different sectors of the same base station, interference between them is significantly reduced.

Therefore, even if the sector is increased by 6 sectors or more, unlike when using several sectors in a narrow area as in the conventional multi-sector base station, the sector gain does not decrease and the capacity of the base station limited by interference increases, so that one base station can simultaneously accommodate it. Increase the maximum number of concurrent users.

In the conventional handoff region, since one terminal is connected to two different base stations and simultaneously has two call channels (soft handoff), the efficiency of the call channel is reduced by half. As the softer handoff is formed between handoffs between sectors, two handoff channels are not simultaneously connected at the time of handoff.

Therefore, the efficiency of the call channel can be prevented from being lowered by half in the handoff area, and since the channel is shared between sectors, it is possible to appropriately cope with a change in the number of users in one cell.

In addition, in the conventional case, once the base station is installed once, there is a disadvantage in that it takes a lot of cost and time when moving or expanding. However, in the present invention, since only the antenna and the optical / RF converter are installed, the moving base is easy and the base station is not relocated when expanding It is possible at cost and time.

On the other hand, in the present invention, when the distance between the multi-sector base station located in a certain region and the antenna of each cell area connected by the optical cable is 50 km or less, the present invention can be applied as it is without any change to the multi-sector base station. Is larger than 50 km, the RTD (Round Trip Delay) is large, the maximum size of the search window (Search Window) is limited, it is impossible to search the pilot signal in the search window.

Accordingly, in the present invention, a delay corresponding to a time difference corresponding to a distance between an antenna located at a distance of 50 km or more and a multisector base station is provided as an offset value in the search window so as to be solved by an intentional delay.

In other words, by intentionally delaying the search window, the pilot signal received from an antenna 50km or more apart without expanding the search window is searched.

As described above, the present invention, by installing the remote antenna and the optical / RF converter connected by the optical cable to each sector of the multi-sector base station located in a certain region without directly installing the base station in each cell area by interference By reducing the restrictions on the limited base station capacity, the base station efficiency can be improved and the time and cost required to install the base station can be reduced, as well as the cost and time when the base station is expanded and moved due to the increase in capacity or the change of service location. There is an effect that can be done.

Claims (2)

First to N-th antennas provided in place of the base station in each cell area where the base station is to be installed, and the first to N-th antennas are installed together in place of the base station in each cell area where the base station is to be installed, First to Nth optical / RF converters for converting RF signals transmitted and received by the antenna to optical signals, and First to Nth optical signals for transmitting and receiving optical signals converted by the first to Nth optical / RF converters. A first through N-th RF / optical converter installed in a cable and a multi-sector base station located in a predetermined region to convert an optical signal transmitted and received through the first through N-th optical cables into an RF signal; First to Nth RF input / output stages for transmitting and receiving RF signals transmitted from the 1st to Nth RF / optical converters for each sector 1 to sector N, so as to form one cell area in each sector of the multisector base station. Multi-sector base station of the communication system, characterized in that Value. The method of claim 1, wherein when the distance between the multisector base station and the antenna of each cell region connected by the optical cable is 50 km or more, a delay equal to a time difference corresponding to the distance between the multisector base station and the antenna is given as an offset value in the search window. A multisector base station apparatus of a communication system, characterized in that to search for a pilot signal received from an antenna 50km or more apart without extending the search window.