KR20050100853A - Site selection machine optimized by cell for the electronic communication system - Google Patents

Abstract

The present invention relates to a cell optimization apparatus for selecting a base station location of a wireless communication system, and to a cell optimization apparatus for selecting a base station location of a wireless communication system capable of selecting an optimal candidate site by verifying multiple candidate base station sites. .

The present invention consists of a transmitter, a receiver and an optimizer that processes and analyzes the received data.

According to the cell optimization apparatus for base station position selection of the wireless communication system of the present invention, it is possible to apply a cell optimization technique for base station position selection on the IMT-2000 system and to easily and accurately correct the reception sensitivity (RSSI) of data equipment. It is possible to increase the reliability of the device so that the position of the base station can be selected as the optimal position.

Description

Cell optimization device for base station location selection in wireless communication system {site selection machine optimized by cell for the electronic communication system}

The present invention relates to a cell optimization apparatus for selecting a base station location of a wireless communication system, and to a cell optimization apparatus for selecting a base station location of a wireless communication system capable of selecting an optimal candidate site by verifying multiple candidate base station sites. .

Recently, due to the development of the wireless communication field, many people are using personal wireless communication devices, and accordingly, services in various frequency domains have been provided.

In operating such a wireless communication device, base stations installed at each location should be able to realize close and secure synchronization with each other. Therefore, the location selection of each base station is a very important matter, and in particular, since the construction of the base station is very expensive, many optimization techniques by measuring the reception sensitivity required for the selection of the base station have been studied.

However, the optimization technique required for the base station location is difficult to collect various selection parameters (parameters) necessary for the optimal location, and there is no data equipment that meets the standards of the recently used global mobile communication (IMT-2000) system The collection of each selected element is more difficult.

The data equipment currently in operation is dedicated to PCS systems, so when used in the global mobile communication system, the output of the transmitter is difficult to be deteriorated or the output setting is difficult to change, and the method of correcting received signal strength (RSSI) is very complicated. The error was large and there was a problem that the frequency selection (Frequency Selective) of the existing data equipment is very sensitive.

In order to solve the above problems, the present invention can be selectively applied to a PCS system and an IMT-2000 system in a method for optimizing positioning cells of a base station used to secure maximum coverage at a minimum investment cost. In addition, the present invention provides a cell optimization apparatus for selecting a location of a base station of a wireless communication system having improved reliability by easily and accurately correcting a reception sensitivity (RSSI) of data equipment.

In order to achieve the above object, the present invention comprises a transmitter, a receiver and an optimizer for processing and analyzing the received data.

The cell optimization method of the present invention is a method of installing a transmitter at a candidate station and measuring the received depth sensitivity (RSSI) while moving the receiver, and then analyzing the measured data.

The optimizer calculates the measured reception sensitivity (RSSI) along with various RF design parameters to select an optimal candidate station.

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

1 to 3, the cell optimization apparatus 10 formed by the embodiment of the present invention is composed of a transmitter 100, a receiver 200, the optimizer 300.

The transmitter 100 amplifies and transmits a signal through an amplifier (HPA) 102 by generating a digital signal in the synthesizer 101 as in the conventional frequency propagation generator as shown in FIG. 2, wherein the amplified signal is 1.8. It is configured to selectively generate signals in the PCS frequency band of GHz and IMT-2000 frequency band of 2 GHz.

In addition, a microprocessor 104 is configured at the rear end of the amplifier 102 of the transmitter 100 to configure an automatic gain control unit (AGC) 103 and to control an output using a signal sensed by the automatic gain control unit 103. do. The transmitted signal is a narrow-scale spread signal (1000 KHz BW), and the stability of the frequency is about ± 3PPM.

At this time, the output of the transmitter 100 is suitable 1W, the automatic gain control unit 103 should be stable with an input range of 15dB and an accuracy of ± 1dB at -15 ~ 45 ℃.

As shown in FIG. 3, each receiver 200 is configured to selectively receive a 1.8 GHz PCS frequency band and a 2 GHz IMT-2000 frequency band generated by the transmitter 100, as shown in FIG. 3. At the end of the receiver 201, a switch 202 for selecting the frequency band is configured, and a synthesizer 203 for converting a signal selectively received by the switch is configured. In addition, an RSSI measurement unit 204 configured to measure a signal reception sensitivity (RSSI) is configured, and is connected to the RSSI measurement unit 204 to utilize it as optimization data, and connected to the control unit 205 to control the entire system. The program may be built in, and the display unit 300 may receive the position information from the GPS receiver 207. The control unit 205 includes a correction unit 208 that stores and compensates the difference between signals in an EEPROM.

The sensitivity of the RSSI measurement unit can be measured with an accuracy of ± 1 dB up to -100 dBm when the IF is 1.23 MHz, and can be measured with an accuracy of ± 1 dB up to -110 dBm when the IF is 30 to 100 KHz.

Once the RSSI is measured 20 as shown in FIG. 3, the display unit 300 connected to the receiver 200 calculates a loss 30 and calculates an operation 50 using the RF design factor 40. In this case, an optimization program for programming the above-described process is built in.

The optimization program consists of a logging program and an analysis and display program.

The login program is capable of changing the narrowband spread signal receiver frequency and bandwidth of the 1.8 GHz / 2 GHz band using a display unit, and sequentially controlling the frequency and bandwidth.

② A function of inverting the RSSI value measured using the correction table from the received sensitivity (RSSI) stored in the correction unit 208 of the receiver 200 to the corrected value.

③ function of interlocking the GPS receiver 207 connected to the display unit 300;

④ Simultaneously log in the state of GPS applied to GPS receiver 207

⑤ It is prepared to include a function that can log in even where GPS is not received.

The analysis and display program compares propagation characteristics of ⑥ PCS band and IMT-2000 band.

⑦ It is necessary to be able to change the value of lost element and convert loss path from these value and measured reception sensitivity (RSSI).

⑧ Display loss path of designated frequency signal by different color on time axis.

⑨ Function to change the ratio of the axis

손실 Function to display the loss path of one designated frequency signal on the coordinate axis in association with GPS location information by color (10dB unit).

기능 Function to display the display on the time axis alternately on the coordinate axis

기능 Ability to display on the KTM.com Windows Diagnostic Monitor in addition to using the optimizer's own map object

작성 It is written to include the function to match the data format in the processing module to use the S / W of Cell Master.

An optimization method for base station location selection using the cell optimizer 10 includes a first step of selecting candidate stations f1 and f4 as shown in FIG. 4 and a second step of installing the transmitter 100 at each candidate station. 4, measuring reception sensitivity (RSSI) with the receiver 200 while moving between the selected candidate station and the existing base station of the PCS system f1, f2 or the IMT-2000 system f3, f4. In operation 5, the reception sensitivity RSSI is calculated by the display unit 300 to select a location.

FIG. 5 shows an analysis flow for selecting an optimal candidate station using the measured sensitivity (RSSI) as described above, and shows radio frequency factors and measurement targets used for each.

The signal measured by the reception sensitivity measuring unit 20 calculates a loss through the loss path calculator 30, and the calculation is performed through an analysis and display program built into the display unit 300, and displayed on the display window. . The RF design factor 40 used at this time is variables such as transmission strength, antenna gain, cable loss, channel allocation, and the like.

The values 50 displayed through the display window are the signal-to-interference ratio (Ex / I ₀ ) prediction, the best signal-to-interference ratio server, the best server of reception sensitivity (RSSI), the handoff area, and the like.

As described above, according to the cell optimization apparatus for base station positioning of the wireless communication system of the present invention, it is possible to apply a cell optimization technique for base station position selection on the IMT-2000 system and to correct the reception sensitivity (RSSI) of data equipment. By making it easy and accurate, it is possible to increase the reliability of the device so that the location of the base station can be selected as the optimal location.

1 is a conceptual diagram of a cell optimization apparatus for base station position selection in a wireless communication system formed according to an embodiment of the present invention.

2 is a block diagram of a transmitter of a cell optimization apparatus for base station position selection in a wireless communication system formed according to an embodiment of the present invention.

3 is a block diagram of a receiver of a cell optimization apparatus for base station position selection in a wireless communication system formed according to an embodiment of the present invention.

Figure 4 is a block diagram of the operation of the cell optimization apparatus for the base station position selection of the wireless communication system formed by an embodiment of the present invention.

5 is a diagram illustrating a cell configuration for each frequency band for using a cell optimization technique.

** <Description of the symbols for the main parts of the drawings> **

 10: cell optimizer 20: reception sensitivity measurement unit

 30: loss path calculation unit 40: radio frequency design factor

100: receiver 101: synthesizer

102: amplifier 103: automatic gain control unit

104: microprocessor 200: receiver

201: receiver 202: switch

203: synthesis unit 204: RSSI measurement unit

205 control unit 207 GPS receiver

208: correction unit 300: display unit

Claims (3)

In general, the cell optimizer for the location of the base station of the wireless communication system formed of a transmitter, a receiver, The transmitter comprises a synthesizer for generating a signal; An amplifier for amplifying the signal; A microprocessor for controlling the signal detected by the automatic gain controller (AGC) before transmitting the signal amplified by the amplifier; The receiver includes a receiver for receiving a signal of the PCS system and a signal of the IMT-2000 system, respectively; A switch capable of selecting respective signals; A synthesizer for converting the received signal; An RSSI measuring unit measuring a reception sensitivity (RSSI) of the converted signal; A display unit for performing calculation and displaying the calculated value using the measured value of the RSSI measuring unit and the position information received from the GPS receiving unit; A control unit connected to the display unit and controlling the entire apparatus; Cell optimizing apparatus for the base station position selection of the wireless communication system, characterized in that the control unit configured to correct the loss. The method of claim 1, The automatic gain controller (AGC) of the transmitter is installed at the rear end of the amplifier and is stable with an input range of 15 dB and an accuracy of ± 1 dB at -15 to 45 ° C. Cell optimizer for selection. The method of claim 1, The program used for the display unit of the receiver is composed of a login program and an interpretation and display program. The login program may be configured to change a narrowband spread signal receiver frequency and bandwidth of a 1.8 GHz / 2 GHz band using a display unit, and to sequentially control the frequency and bandwidth; A function of inverting the measured reception sensitivity (RSSI) value to the corrected value by using the reception sensitivity (RSSI) correction table stored in the correction unit of the receiver; A function of interlocking a GPS receiver connected to the display unit; A function of simultaneously logging in the state of the GPS applied to the GPS receiver; It is created including the function that login is possible even where GPS is not received, The analysis and display program includes a function for comparing propagation characteristics of the PCS band and the IMT-2000 band; A function of converting the loss paths from these values and the measured reception sensitivity (RSSI); Displaying the loss paths of the frequency signals designated on the time axis in different colors; A function for changing the ratio of the axis; Displaying a loss path of one designated frequency signal on a coordinate axis in association with GPS location information by color (in 10 dB units); A function of alternately displaying the display on the time axis and the display on the coordinate axis; Support for displaying on the KTM.com Windows Diagnostic Monitor in addition to displaying with the map object of the optimizer itself; Cell optimization device for base station location selection of a wireless communication system, comprising the function of matching the data format in the processing module to use the S / W of the Cell Master