JPH08322079A - Decision method for installation position or the like of extended base station in phs - Google Patents

Abstract

PURPOSE: To provide a method to decide the installation position, etc., of an extended base station in e PHS(personal handyphone system) with improvement of the reliability. CONSTITUTION: In this method, a 1st step is prepared to measure the field intensity at plural spots in a service area together with a 2nd step where the parameter of a mathematical model is adjusted to secure the coincidence as much as possible between the field intensity distribution of the service area that is decided by the simulation using the mathematical model and the field intensity distribution decided by the result of measurement, a 3rd step where the parameter value related to an extended base station including the parameter value related to the installation position of the base station to the mathematical model having its adjusted parameter and simulates the field intensity distribution of the service area when the extended base station is supposedly installed, and a 4th step where the result of simulation is evaluated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of deciding the installation position and the like of an extension base station in PHS.

[0002]

2. Description of the Related Art In the field of mobile communications, PHS (Personal Handy) is cheaper than conventional mobile phones and car phones.
Phone System) will provide communication services.

When one or a plurality of base stations are installed in a predetermined PHS service area, there is a dead zone where a call cannot be made in the PHS service area. Further, after the installation of one or a plurality of base stations, a dead zone in which a call cannot be made may occur in the PHS service area due to environmental changes in the PHS service area such as building renovation.

In such a case, in order to reduce the dead zone area, it is necessary to add a base station. When adding a base station, for example, the installation position of the base station to be added, the height of the antenna of the base station to be added, and the like must be determined so that the dead zone area is reduced as much as possible.

In order to make such a determination, a mathematical model is used to simulate the electric field strength distribution in the PHS service area, and the installation position of the base station to be added and the base station to be added are simulated based on the simulation result. It is conceivable to determine the height of the antenna.

However, since the electric field strength distribution obtained by the simulation using the mathematical model may have a large error with respect to the actual electric field strength distribution, the base station to be added is simply based on the simulation result. However, the method of determining the installation position of the antenna, the height of the antenna of the base station to be added, and the like has a problem of lack of reliability.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for determining the installation position and the like of an extension base station in PHS, which can improve reliability.

[0008]

According to the method for determining the installation position of an extension base station in a PHS according to the present invention, one or a plurality of PHS base stations are installed in a service area.
A method of determining the installation position of an additional base station in the case of adding a PHS base station, the first step of measuring the electric field strength at a plurality of points in the service area, by a simulation using a mathematical model. The second step of adjusting the parameters of the mathematical model so that the calculated electric field strength distribution of the service area matches the electric field strength distribution obtained from the measurement result of the electric field strength as much as possible. The third step of simulating the electric field strength distribution of the above-mentioned service area when the extension base station is assumed to be installed by giving a parameter value regarding the extension base station including the parameter value regarding the installation position of the base station, and the simulation result is evaluated. Regarding the 4th step to do and the extension base station By changing the parameter value, the second step, after repeating the third step and fourth step,
It is characterized by comprising a fifth step of determining a suitable parameter value for the additional base station based on the evaluation result for each parameter value for the additional base station.

The parameter value relating to the extension base station is, for example, the parameter value relating to the installation position of the extension base station,
There is a parameter value related to the antenna height position of the extension base station and a parameter value indicating the transmission power of the extension base station.

[0010]

The electric field strength is measured at a plurality of points in the service area (first step). The parameters of the mathematical model are adjusted so that the electric field strength distribution of the service area obtained by the simulation using the mathematical model matches the electric field strength distribution based on the measurement result of the electric field strength as much as possible (second step). ).

The electric field strength of the service area in the case where the additional base station is assumed to be installed is given the parameter value related to the additional base station including the parameter value related to the installation position of the additional base station to the mathematical model after the parameter adjustment. The distribution is simulated (third step). The simulation result is evaluated (fourth step). After changing the parameter value regarding the extension base station and repeating the second step, the third step, and the fourth step, based on the evaluation result for each parameter value regarding the extension base station, a suitable parameter regarding the extension base station The value is determined.

[0012]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a procedure of a method for determining the installation position of an additional base station when a PHS base station is added in a service area where one or a plurality of PHS base stations are installed. .

(1) First, the electric field strength is measured at a plurality of points in a service area where one or a plurality of base stations are installed (step 1).

(2) Next, the parameters of the mathematical model are adjusted so that the electric field strength distribution of the service area obtained by simulation using the mathematical model matches the electric field strength distribution obtained from the measurement result of the electric field strength as much as possible. Yes (step 2).

The mathematical model used for simulating the electric field strength distribution is, for example, as follows.

(I) Manhattan Street Model This model considers only direct waves. (ii) Green model Two-wave path model that synthesizes direct wave and ground reflection wave
There is a four-wave path model that combines the wave path model and the reflected waves on both side walls. (iii) Ray tracing model This is a model that considers the diffracted waves at the corners of the building. (iv) BD wave diffraction model BD waves diffracted from above the building (Building Diffracti
on Wave).

The parameters of the mathematical model are:
There are parameters related to base stations and parameters related to environments such as buildings and roads. The former includes the installation position of the base station, the height position of the antenna of the base station, the transmission power of the base station, and the like. The latter includes building diffraction loss, road diffraction loss, ground reflection loss, building reflection loss, and the like.

In step 2, the parameters relating to the environment such as buildings and roads among the parameters of the mathematical model are adjusted.

(3) Next, a parameter value relating to the extension base station is added to the mathematical model after the parameter adjustment,
The electric field intensity distribution in the above service area is simulated on the assumption that an additional base station is installed (step 3). In this example, the parameter values relating to the extension base station include a parameter value relating to the installation position of the extension base station, a parameter value relating to the height position of the antenna of the extension base station, and a parameter value relating to the transmission power of the extension base station.

(4) Next, the simulation result is evaluated (step 4). This evaluation is whether or not the dead zone area is no longer present, when the dead zone area does not exist, the area of the interference area between the existing base station and the extension base station, and when the dead zone area exists, the area of the dead zone area, etc. Based on.

If the dead zone does not exist and the area of the interference area between the existing base station and the additional base station is small, the evaluation value becomes high. On the contrary, if the dead zone area exists and the area of the dead zone area is large, the evaluation value is small.
The evaluation value is stored in association with the parameter value regarding the extension base station.

(5) The parameter value relating to the additional base station is changed, and step 2, step 3 and step 4 are repeated. Then, when an evaluation value is obtained for a predetermined number of parameter values related to the additional base station (Y in step 5).
ES), the parameter value relating to the extension base station having the highest evaluation value is determined as a suitable parameter value (step 6). Thereby, a suitable installation position of the extension base station, a suitable antenna height position of the extension base station, a suitable transmission power of the extension base station, and the like are determined.

In the above embodiment, the parameters of the mathematical model are adjusted so that the electric field strength distribution of the service area obtained by simulation using the mathematical model matches the electric field strength distribution obtained from the electric field strength measurement result as much as possible. , The parameter values relating to the extension base station such as the installation position of the extension base station are given to simulate the electric field strength distribution in the service area when the extension base station is assumed to be installed. Then, by evaluating the simulation result, the optimum installation position of the additional base station is determined. Therefore, a reliable decision result can be obtained.

[0025]

According to the present invention, it is possible to obtain a method for determining the installation position and the like of an extension base station in a PHS that can improve reliability.

[Brief description of drawings]

FIG. 1 is a flowchart showing a procedure of a method for determining the installation position of an additional base station when a PHS base station is added in a service area where one or more PHS base stations are installed. Is.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Ritsu Katayama 2-5-5 Keihan Hondori, Moriguchi City, Osaka Sanyo Electric Co., Ltd.

Claims (2)

[Claims] 1. A method of deciding the installation position or the like of an additional base station when a PHS base station is added to a service area where one or more PHS base stations are installed, the method comprising: In the first step of measuring the electric field strength at a plurality of points in, the electric field strength distribution of the service area obtained by the simulation using the mathematical model, as closely as possible to the electric field strength distribution by the measurement result of the electric field strength, Second to adjust the parameters of the mathematical model
The electric field strength of the above service area when the additional base station is assumed to be installed by adding the parameter values related to the additional base station including the parameter values related to the installation position of the additional base station to the mathematical model after step and parameter adjustment After the third step of simulating the distribution, the fourth step of evaluating the simulation result, and the parameter value related to the extension base station, and repeating the second step, the third step, and the fourth step, the parameters related to the extension base station A fifth step of deciding a suitable parameter value relating to the additional base station based on the evaluation result for each value, and a method for determining the installation position etc. of the additional base station in the PHS. 2. The parameter value relating to the extension base station includes:
A parameter value relating to the installation position of the extension base station, a parameter value relating to the height position of the antenna of the extension base station, and a parameter value indicating the transmission power of the extension base station.
The method for determining the installation position, etc., of the extension base station in the PHS described in 1.