KR20020010000A - Method for detecting frequency reuse efficiency in wireless local loop - Google Patents

Abstract

PURPOSE: A method for detecting frequency reuse efficiency of a WLL(Wireless Local Loop) system is provided to consider subscribers using omni-directional antennas and subscribers using directional antennas, when the subscribers using the omni-directional antennas and the directional antennas exist simultaneously in the WLL system, so as to correctly detect the frequency reuse efficiency. CONSTITUTION: A base station detects a command of measuring frequency reuse efficiency(211). The base station converts a mode to a frequency reuse efficiency measuring mode(213). The base station detects frequency reuse efficiency in case all subscribers use omni-directional antennas(215). The base station detects frequency reuse efficiency in case all subscribers use directional antennas(217). The base station calculates a ratio of subscribers using omni-directional antennas to subscribers using directional antennas(219). The base station detects a receive signal strength for the subscribers using the omni-directional antennas(221). The base station detects a receive signal strength for the subscribers using the directional antennas(223). The base station detects a thermal noise floor of a base station receiver(225). The base station detects a total receive signal strength(227). And the base station detects frequency reuse efficiency(229).

Description

Frequency Recognition Efficiency Detection Method of Wireless Subscriber Network System {METHOD FOR DETECTING FREQUENCY REUSE EFFICIENCY IN WIRELESS LOCAL LOOP}

The present invention relates to a wireless subscriber network system, and more particularly, to a method for detecting a frequency reuse efficiency considering an antenna type of a subscriber serving in a wireless subscriber network system.

In general, a wired telephone communication network requires a lot of costs for network construction, maintenance and repair, and also requires a long time for network construction. Therefore, a wireless local area network (WLL) system has been proposed to replace the wired telephone network, which is inexpensive and does not require a long time in a long time. The wireless subscriber network system wirelessly connects a telephone communication network with a terminal station as a subscriber to provide various services such as voice data, text data, and video data. The wireless subscriber network system requires a handoff by providing a communication service to a fixed terminal station as opposed to a mobile telecommunication system providing a communication service to a mobile station. As the service capacity can be expanded, the usage is expanding, especially in countries where wired communication networks are poorly built.

However, the fixed terminal stations of the wireless subscriber network system use a directional antenna and an omnidirectional antenna according to the installation positions of the fixed terminal stations. The reason is that the directional antenna has a characteristic of strongly radiating radio waves only in a specific direction or has a high sensitivity to radio waves from the specific direction, and the omnidirectional antenna has an essentially non-directional characteristic with respect to the direction. Therefore, when the directional antenna is used in the fixed terminal station, interference of other cells is reduced, thereby increasing frequency reuse efficiency of the wireless subscriber network system.

However, conventionally, in order to detect the frequency reuse efficiency, the frequency reuse efficiency is detected only when all fixed terminal stations that are subscribed to the wireless subscriber network system use only a directional antenna, or all the fixed terminal stations are omni-directional. Frequency reuse efficiency was detected only for the case of using only the antenna. However, since the fixed terminal stations that are subscribed to the wireless subscriber network system in the actual wireless environment use the directional antenna or the omnidirectional antenna selectively according to the installation location to maximize the transmission and reception sensitivity, In a magnetic network system, a fixed terminal station using a directional antenna and a fixed terminal station using an omnidirectional antenna are mixed. Therefore, the conventional method of detecting the frequency reuse efficiency is impossible to accurately detect the frequency reuse efficiency because all fixed terminal stations detect the frequency reuse efficiency only when the directional antenna or the omnidirectional antenna is used. There was this. Since it was impossible to detect the exact frequency reuse efficiency, there was a problem in that an incorrect frequency reuse efficiency was used in determining the wireless subscriber network system capacity and service area.

Accordingly, an object of the present invention is to provide a method for detecting frequency reuse efficiency in consideration of the type of antenna used by a fixed terminal station in a wireless subscriber network system.

The present invention for achieving the above object; A method for detecting a frequency reuse efficiency of a wireless subscriber network system, comprising: a first process of detecting frequency reuse efficiency assuming that all subscribers subscribed to the wireless subscriber network system use an omnidirectional antenna; and the wireless subscriber network system A second process of detecting frequency reuse efficiency assuming that all subscribers subscribed to the directional antenna are used; and a third process of detecting a ratio of a subscriber using a directional antenna using a omnidirectional antenna; Considering the frequency reuse efficiency when all subscribers use omni-directional antennas and the frequency reuse efficiency when all subscribers use directional antennas, the ratio of subscribers using omni-directional antennas to subscribers is used. Using the omni-directional antenna It is characterized in claim 4 constituted by any process for detecting the frequency reuse efficiency in the case where the subscriber using the subscriber and the directional antenna is present at the same time.

1 is a view showing a schematic configuration of a wireless subscriber network system for performing a function in an embodiment of the present invention

2 is a flowchart illustrating a frequency reuse efficiency detection process according to an embodiment of the present invention.

3 is a table showing the result data according to the frequency reuse efficiency detection process of the present invention

4 is a graph showing the result data according to the frequency reuse efficiency detection process of the present invention

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

1 is a view showing a schematic configuration of a wireless subscriber network system for performing a function in an embodiment of the present invention.

A wireless local loop (WLL) system provides a variety of services such as voice data, text data, and video data by wirelessly connecting a fixed terminal station, which is a subscriber, with a telephone communication network. The wireless subscriber network system does not perform a handoff by providing a communication service to a fixed terminal station as opposed to a mobile telecommunication system providing a communication service to a mobile station. Do not. The wireless subscriber network provides a communication service to a corresponding service area 100, 120, 140 through a plurality of base stations, that is, base stations 101, 121, and 141. The fixed terminal stations 103 and 9105 receive communication services from the base station 101, and selectively use a directional antenna and an omnidirectional antenna according to the installation position thereof. Similarly, fixed terminal stations 123 and 125 receive communication services from the base station 121, and selectively use directional antennas and omni-directional antennas according to their installation positions. In addition, the fixed terminal station 143 receives the communication service from the base station 141, and also uses the directional antenna and omni-directional antenna selectively according to the installation position. In this case, when the fixed terminal stations use the directional antennas, interference from other service areas is reduced, thereby increasing the frequency reuse efficiency compared to the case of using the omni-directional antennas.

2 is a flowchart illustrating a frequency reuse efficiency detection process according to an embodiment of the present invention.

First, the frequency reuse efficiency detection process according to an embodiment of the present invention is a frequency reuse efficiency when all fixed terminal stations subscribed to the wireless subscriber network system using the omni-directional antenna, and all fixed terminal stations Consider the frequency reuse efficiency in the case of directional antenna and the ratio of fixed terminal station using directional antenna to fixed terminal station using omnidirectional antenna among all fixed terminal stations subscribed to the wireless subscriber network system. .

First, in step 211, when a specific base station of the wireless subscriber network, for example, the base station 101 detects that the frequency reuse efficiency measurement command is input from the operator, the base station 101 proceeds to step 213. In step 213, the base station 101 switches its own mode to the frequency reuse efficiency measurement mode and proceeds to step 215. In step 215, the base station 101 detects frequency reuse efficiency when all subscribers of the base station 101 use the omni-directional antenna, and proceeds to step 217. Here, since the equation development process for detecting the frequency reuse efficiency is a well-known technique, the description thereof will be omitted, and assume that the frequency reuse efficiency when all the subscribers use the omni-directional antenna is F ₁ . In step 217, the base station 101 detects frequency reuse efficiency when all subscribers of the base station 101 use the directional antenna, and proceeds to step 219. In this case, it is assumed that the frequency reuse efficiency when all the subscribers use the directional antenna is F ₂ .

In step 219, the base station 101 calculates a ratio of subscribers using omni-directional antennas using omni-directional antennas among all subscribers subscribed to the base station 101, and proceeds to step 221. In this case, it is assumed that the subscriber ratio using the omni-directional antenna to the subscriber using the omni-directional antenna is A, where A can be expressed by Equation 1 below.

Here, N ₁ is the number of subscribers using omni-directional antennas, and N ₂ is the number of subscribers using directional antennas.

In step 221, the base station 101 detects the strength of the received signal received from the subscribers using the omni-directional antenna to the base station 101 and proceeds to step 223. Here, the strength of the received signal received from the subscribers using the omni-directional antenna to the base station 101 can be expressed by the following equation (2).

Here, P ₁ is the strength of the received signal received from the subscribers using the omni-directional antenna to the base station 101, F ₁ is the frequency reuse efficiency for the subscribers using the omni-directional antenna, P _Rx is the strength of the received signal received from one subscriber, E _S is the Sectorization Efficiency, and υ is the Voice Activity.

In step 223, the base station 101 detects the strength of the received signal received from the subscribers using the directional antenna to the base station 101, and proceeds to step 225. Here, the strength of the received signal received from the subscribers using the directional antenna to the base station 101 can be expressed by Equation 3 below.

Here, P ₂ is the strength of the received signal received from the subscribers using the directional antenna to the base station 101, F ₂ is the frequency reuse efficiency for the subscribers using the directional antenna, the P _Rx is the strength of the received signal received from one subscriber, E _S is the Sectorization Efficiency, and υ is the Voice Activity.

In step 225, the base station 101 detects a thermal noise floor (N _TH ) of the receiver of the base station 101 itself and proceeds to step 227. In step 227, the base station 101 detects the strength of the total received signal of the base station 101 and proceeds to step 229. Herein, the strength of the total received signal may be expressed by Equation 4 below.

Here, P _Total is the strength of the total received signal.

Therefore, the signal-to-noise ratio for one subscriber of the base station 101 can be expressed by Equation 5 below.

Thus, Equation 5 may be expressed by Equation 6 below.

Here, F denotes the frequency reuse efficiency for the case where the subscriber using the omnidirectional antenna and the subscriber using the directional antenna exist simultaneously in the base station 101.

Therefore, the total received signal strength received by the base station 101 according to Equation 6 can be expressed by Equation 7 below.

Here, when the frequency reuse efficiency when the subscriber using the omnidirectional antenna and the subscriber using the directional antenna exist simultaneously among the subscribers of the base station 101, Equation 4 and Equation 7 are the same. The calculation process is performed as in Equation 8.

Here, the equation (8) with respect to the F can be expressed by the following equation (9).

As shown in Equation 9, when the subscriber using the omnidirectional antenna and the antenna using the directional antenna exist simultaneously in the base station 101, the frequency reuse efficiency of all the subscribers of the base station 101 may use the omnidirectional antenna. Frequency reuse efficiency in case of use, frequency reuse efficiency when all subscribers of base station 101 use directional antenna, and ratio of subscribers using omni-directional antenna and subscribers using directional antenna in base station 101 It is calculated using.

Here, the result data according to the frequency reuse efficiency detection process when the omni-directional antenna using subscriber and the directional antenna using subscriber according to an embodiment of the present invention at the same time will be described with reference to FIG.

For example, the frequency reuse efficiency F ₁ when all subscribers subscribed to the base station 101 are using omnidirectional antennas is 0.667, and all subscribers subscribed to the base station 101 use directional antennas. When F ₂ , which is a frequency reuse efficiency, is 0.88, the frequency reuse efficiency is calculated when the subscriber using the omnidirectional antenna and the subscriber using the directional antenna exist simultaneously with Equation 9 described in FIG. do. The ratio of the subscriber using the omnidirectional antenna and the subscriber using the directional antenna among the subscribers of the base station 101 is shown in the table. As an example of the ratios shown in the table, when the subscriber ratio using the omnidirectional antenna is 40% and the subscriber ratio using the directional antenna is 60%, the frequency reuse efficiency value is calculated using Equation (9).

In other words, Becomes

4 is a graph showing the result data according to the frequency reuse efficiency detection process of the present invention. FIG. 4 is a graph showing frequency reuse efficiency values according to the ratio of subscribers using directional antennas among the subscribers of the base station 101 based on the table shown in FIG.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention provides accurate frequency reuse in consideration of the use of the omnidirectional antenna and the use of the directional antenna when the subscriber using the omnidirectional antenna and the subscriber using the directional antenna exist simultaneously in the wireless subscriber network system. It is possible to detect the efficiency. Therefore, it is advantageous to use accurate frequency reuse efficiency in determining the wireless subscriber network system capacity and service area.

Claims (11)

In the frequency reuse efficiency detection method of a wireless subscriber network system, A first process of detecting frequency reuse efficiency assuming that all subscribers subscribed to the wireless subscriber network system use omni-directional antennas; A second process of detecting frequency reuse efficiency assuming that all subscribers subscribed to the wireless subscriber network system use a directional antenna; Detecting a ratio of subscribers using omni-directional antennas to subscribers using omni-directional antennas; Considering the frequency reuse efficiency when all subscribers use omni-directional antennas and the frequency reuse efficiency when all subscribers use directional antennas, the ratio of subscribers using omni-directional antennas to subscribers And a fourth process of detecting a frequency reuse efficiency when the subscriber using the omni-directional antenna and the subscriber using the directional antenna are present at the same time. The method of claim 1, The fourth process is; Detecting the strength of the total received signal actually received from all the subscribers; Detecting a signal-to-noise ratio for any one subscriber of the wireless subscriber network system with the total received signal strength; Calculating the strength of the total received signal received from all subscribers from the signal to noise ratio; Frequency reuse efficiency when the subscriber using the omni-directional antenna and the subscriber using the directional antenna exist at the same time by using the strength of the total received signal and the total received signal calculated from the signal-to-noise ratio. Characterized in that it consists of a process of detecting. The method of claim 2, Detecting the strength of the total received signal actually received from all the subscribers; Detecting the strength of a signal received from subscribers using the omni-directional antenna; Detecting the strength of a signal received from subscribers using the omni-directional antenna after detecting the strength of the received signal from the subscribers using the omni-directional antenna; Detecting the strength of the signal received by the subscribers using the directional antenna and then detecting self-thermal noise to add the strength of the omni-directional antenna subscriber signal and the strength of the directional antenna subscriber signal. . In the frequency reuse efficiency detection method of a wireless subscriber network system, Detecting frequency reuse efficiency when all subscribers subscribed to the wireless subscriber network system use omni-directional antennas; Detecting frequency reuse efficiency when all subscribers subscribed to the wireless subscriber network system use the directional antenna; Calculating a subscriber ratio using an actual omni-directional antenna in the wireless subscriber network system; Detecting the strength of a received signal received from subscribers using the omni-directional antenna; Detecting strength of received signals received from subscribers using the directional antenna after detecting strength of received signals of the omni-directional antenna subscribers; Detecting thermal noise after detecting an intensity of a received signal of the directional antenna subscribers; Detecting the actual total received signal strength by adding the received signal strength of the omni-directional antenna subscribers, the received signal strength of the directional antenna subscribers, and the thermal noise; Detecting a signal-to-noise ratio for any one subscriber of the wireless subscriber network system with the actual total received signal strength; Calculating the strength of the total received signal received from all subscribers from the signal to noise ratio; Frequency reuse efficiency when the subscriber using the omni-directional antenna and the subscriber using the directional antenna exist at the same time by using the strength of the total received signal and the total received signal calculated from the signal-to-noise ratio. Characterized in that it consists of a process of detecting. The method of claim 4, wherein The strength of the received signal received from subscribers using the omni-directional antenna can be represented by the following equation (10). However, P ₁ : strength of a received signal received from subscribers using the omni-directional antenna F ₁ : Frequency reuse efficiency for subscribers using the omni-directional antenna P _Rx : the strength of the received signal received from any one subscriber E _S : Sector Efficiency υ: voice activity The method of claim 5, The strength of the received signal received from subscribers using the directional antenna can be represented by the following equation (11). However, P ₂ : the strength of a received signal received from subscribers using the directional antenna F ₂ : Frequency reuse efficiency for subscribers using the directional antenna The method of claim 6, The strength of the total received signal is actually represented by the following equation (12). However, P _Total : Actual total received signal strength N ₁ : Number of subscribers using omni-directional antenna N ₂ : Number of subscribers using directional antenna N _TH : thermal noise The method of claim 7, wherein And a signal-to-noise ratio for any one subscriber detected with the actual total received signal strength can be expressed by the following equation (13). only, Signal to noise ratio The method of claim 8, The strength of the total received signal calculated with the signal-to-noise ratio can be expressed by the following equation (14). The method of claim 9, The frequency reuse efficiency when the subscriber using the omni-directional antenna and the subscriber using the directional antenna are present at the same time can be represented by the following equation (15). However, F ₁ : frequency reuse efficiency when all the subscribers use omni-directional antenna F ₂ : Frequency reuse efficiency when all the subscribers use the directional antenna In the frequency reuse efficiency detection method of a wireless subscriber network system, Detecting frequency reuse efficiency when it is assumed that all subscribers subscribed to the wireless subscriber network system use the same first type antenna; Detecting a frequency reuse efficiency in the case where all of the subscribers use a second type antenna different from the first type antenna, if all of the subscribers use the second type antenna; Calculating a ratio of subscribers using the first type antenna and subscribers using the second type antenna among all the subscribers; And detecting the frequency reuse efficiency in case of using only the first type antenna and the frequency reuse efficiency in case of using only the second type antenna.