KR100574655B1 - Subscriber positioning service for wireless communication network - Google Patents

Abstract

The present invention provides a wide range of location information such as the origination location and mobile situation of DGPS (Differential GPS) reference station and CDMA wireless subscriber without increasing GPS in CDMA network, thereby increasing the stability of wireless subscriber and applying to traffic control system. The present invention provides a subscriber location information service method of a wireless communication network, the method comprising: measuring a difference between transmission time delays of a base station to which the mobile station belongs and two or more adjacent base stations; Transmitting, by the communication terminal, the transmission time delay measurement values to a base station to which the communication terminal belongs; Forming, by the base station receiving the transmission time delay measurements, circles representing the distance from each base station to the corresponding communication terminal according to the measurement values; Calculating, by the base station, coordinate information of the communication terminal using an intersection of the formed circles; Obtaining, by a DGPS reference station, terminal location information by performing error detection and correction on the calculated coordinate information; The obtained terminal location information is transmitted to the corresponding communication terminal and is displayed to be viewed by the subscriber. The location information is provided to the wireless communication network subscriber at a low cost by using a base station repeater and a DGPS reference station. Improve the accuracy of location tracking.

Description

Subscriber positioning service for wireless communication network {Subscriber positioning service for wireless communication network}

1 is a block diagram of a positioning system of a wireless communication network according to the prior art.

2 is a configuration diagram of a positioning system of a wireless communication network to which an embodiment of the present invention is applied.

3 is a flowchart of a method for providing subscriber location information in a wireless communication network according to the present invention;

Explanation of symbols on the main parts of the drawings

111, 112, 113: base station 120: mobile communication terminal

131, 132: repeater 140: DGPS reference station

The present invention relates to a subscriber location information service of a wireless communication network, and more particularly, to be suitable for serving location information such as a subscriber's location and mobile situation through positioning of a terminal in a code division multiple access (CDMA) network. The present invention relates to a subscriber location information service method of a wireless communication network.

In general, a subscriber station subscribed to a CDMA wireless communication network or a mobile communication network has a virtual noise phase (PN phase) representing a difference in transmission time delay (number of PN code time delay chips) of a neighboring base station, and a pilot channel of a base station. ), The strength indicating the signal-to-noise ratio of the signal, and the base station currently performing soft handover, the base station to perform the handover, and the virtual noise offset (PN offset) of neighboring base stations. This information is continuously measured inside the terminal and transmitted to the base station when the terminal performs a handover during the call state. The base station to be handed over can use this information received from the terminal to easily obtain the transmitted signal.

Using this information, it is possible to measure the difference in the transmission time delay between the base stations adjacent to the terminal and the terminal. Therefore, unique information such as base station information for handover and signal-to-noise ratio of the pilot channel of each base station according to the position of the terminal. It is possible to track the location of the terminal using.

In this way, in 1996, the Federal Communications Commission required all wireless carriers in the country to provide a new E-911 service with location information as its main content.

The US Federal Communications Commission has provided two levels of basic 911 services and E-911 services to enable wireless operators to easily implement 911 services.

In general, the location measurement method performed by the radio positioning system on the ground can be largely classified into three types.

One method is to receive a signal sent from a base station (BS, or base station) to a mobile station (MS, or mobile station), which is a terminal, and measure the position by comparing the signal strength with a statistical probability distribution.

The other is a direct finding system for measuring the position of a mobile station by measuring the angle of arrival (AOA) of a signal sent from the base station to the mobile station.

Third, the position is measured using the distance between the mobile station and the base station, such as a time of arrival (TOA) for measuring a propagation time or a time difference of arrival (TDOA) using a relative difference of propagation arrival times from two base stations. Ranging Position Location System.

The TOA positioning method is a method of obtaining a distance by measuring a propagation time between a terminal and a base station. This principle forms circles around each base station from several measurements taken by several base stations and allows the target terminal to be at the intersection of these circles.

In a system using a GPS (Global Positioning System) satellite, which is a representative positioning system, the position of a terminal is obtained by using a TOA method. In the case of GPS satellite systems, recursive least squares are generally used to determine absolute positions.

Basically, the TOA must be operated correctly by both the base station and the terminal, and must be time-sampled to know when the signal originated from the terminal at the base station. In the positioning system using the TOA method, it is necessary to know the positions of four or more base stations and the pseudo distance to each base station in order to find the position of the terminal.

If the altitude is fixed, at least three base station locations are required. In this case, the position of the mobile station 120 is calculated at the intersection of the circles formed by the three base stations 111, 112, and 113 as shown in FIG.

However, in the related art described above, the transmission time delay difference between adjacent base stations within the terminal is processed in units of 1/8 chips and then reported to the base station in units of 1 chip. Therefore, in case of using only the information related to the base stations such as the transmission time delay difference between the base stations, the accuracy of location tracking has an error range of up to about 244m, which makes it difficult to accurately locate the base station.

The present invention was created to solve the above-mentioned conventional problems, and an object of the present invention is to provide location information such as the origination location and mobile situation of a differential GPS (DGPS) reference station and a CDMA wireless subscriber without using GPS in a CDMA network. It is to provide a subscriber location information service method of a wireless communication network to increase the stability of the wireless subscriber by applying a wide range of services to be applied to a traffic control system.

In the subscriber location information service system of the wireless communication network of the present invention for achieving the above object, the difference in the transmission time delay of the base station to which the communication terminal belongs, and the difference in the transmission time delay of two or more neighboring base stations in preparation for handover A base station delay value measuring step of measuring a difference in transmission time delays of three or more base stations, including; A repeater delay value measuring step of measuring, by the communication terminal, a difference in transmission time delays from a plurality of repeaters in a base station to which the communication terminal belongs; and the transmission time delay measurement values measured by the base station and repeater delay value measuring step; Transmitting to a base station to which the mobile station belongs; A circularity step of the base station receiving the transmission time delay measurement values after the transmitting step, forming circles representing distances from each base station to the corresponding communication terminal according to the measurement values; A coordinate information calculating step of calculating, by the base station, coordinate information of the communication terminal by using intersections of the circles formed by the circularity step; A location information acquiring step, after the coordinate information calculation step, the DGPS reference station acquires terminal location information by performing error detection and correction on the calculated coordinate information; And a display step of transmitting the obtained terminal location information to the corresponding communication terminal after the location information obtaining step so that the subscriber can check the location information.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a configuration diagram of a positioning system of a wireless communication network to which an embodiment of the present invention is applied, and FIG. 3 is a flowchart of a method for providing subscriber location information of a wireless communication network according to the present invention.

This embodiment is applied to a wireless communication network system as shown in FIG. The system includes a DGPS reference station 140, a plurality of CDMA mobile communication base stations 111, 112 and 113, a plurality of small repeaters 131 and 132 for improved call quality and location tracking, and a graphic-enabled liquid crystal display (LCD). It is configured to include a mobile communication terminal 120 equipped with.

DGPS is a technique for obtaining a more accurate position by correcting the factors causing the coordinate error of the GPS. DGPS has a real-time processing method and a post-processing method, and there is an Inverted DGPS recently developed for an automatic vehicle location (AVL).

The DGPS reference station 140 stands at a fixed position precisely measured using GPS. In the DGPS reference station 140, an expensive DGPS base station GPS receiver is installed. If the precise position is input to the GPS receiver for the DGPS reference station, the error of the coordinates received and calculated in real time can be found. This error is not simply used, but is stored in a storage medium such as a hard disk in the form of RAW data and transmitted at a radio frequency (RF).

In real-time processing, when the data received by RF is put into the GPS receiver, the corrected position comes out immediately. In the post-processing, coordinates are corrected by using the RAW data stored in the mobile chain mobile communication terminal 120 and the RAW data of the DGPS reference station 140.

The location information service method applied to such a system operates in the order shown in FIG.

According to FIG. 3, the method of the present embodiment is an improvement of the TOA method. First, the mobile communication terminal 120 compares a value of measuring a difference (chip delay) of a transmission time delay of each base station to which it belongs, and preparing for handover. The difference value of the transmission time delays of two or more neighboring base stations is measured. Therefore, the mobile communication terminal 120 measures the difference in transmission time delay from three or more base stations 111, 112, and 113. Herein, if the mobile communication terminal 120 belongs to the base station 112 indicated by BS2, the base station for the remaining two handovers becomes BS1 111 and BS3 113 (S300 to S310).

In addition, the mobile communication terminal 120 also measures the difference in the transmission time delay of the small repeaters (131, 132) installed to improve the call quality for the radio shade area in the base station 112 to which it belongs. At least two small repeaters 131 and 132 measuring the difference in transmission time delay should be at least two, and the larger the number, the better the accuracy of the measurement. For example, a GPS receiver such as GEC PLESSY or JRC in a foreign country receives and processes data from up to 12 GPS satellites to improve accuracy and maintains an error range within 1 m (S320).

The mobile communication terminal 120 measures the transmission time delay measurement measured from the base station 112 to which it belongs, the transmission time delay measurement measured from the neighbor base stations 111 and 113 in preparation for handover, and to which it belongs. Three kinds of measurement values such as transmission time delay measurement values of the small repeaters 131 and 132 in the base station 112 are loaded on an access channel of the base station 112 to which the base station 112 belongs. (S330).

The base station 112, which knows its coordinate value, the coordinate value of the neighboring base station, and the coordinate values of the repeaters in the base station, transmits time to various base stations 111, 112, and 113 sent by the mobile communication terminal 120. Interpret the delay measurements so that circles are created around each base station. These circles represent the distance between the base station and the mobile communication terminal 120, which is a measure of the transmission time delay. The distance from the mobile communication terminal 120 to the base station BS1 111 is 'r1', the base station BS2 112 is 'r2', and the base station BS3 113 is referred to as 'r3' (S340).

In addition, the base station 112, to which the mobile communication terminal 120 belongs, interprets the transmission time delay measurement values of the small repeaters 131 and 132 depending on it, so that small circles are generated in the above manner. The distance from the mobile communication terminal 120 to the small repeater 1 131 is 'r2_1' and the distance from the small repeater 2 132 will be referred to as 'r2_2' (S350).

The base station 112 to which the mobile communication terminal 120 belongs determines the position of the corresponding mobile communication terminal 120 by checking an intersection formed of a plurality of circles generated using the transmission time delay measurement value. As such, the base station 112 may calculate coordinate information of the mobile communication terminal 120 belonging to the base station 112 according to the transmission time delay measurement value (S360).

Techniques for specifying the location of a location object at that intersection using a circle representing a distance from a plurality of reference points to the location object are well known. In the case of circles formed of three base stations 111, 112, 113 and two small repeaters 131, 132, each circle will have a radius r1, r2, r3, r2_1, and r2_2, and 5 One intersection will be formed for every three selectable combinations within the two populations. As described above, a processing technique for a case where a plurality of intersection points appear is also known.

The base station 112 to which the mobile communication terminal 120 belongs transmits the calculated terminal coordinate information to the DGPS reference station 140.

The DGPS base station 140 transmits to the base station 112 the correct position information correcting the elements causing the coordinate error in the received terminal coordinate information. Here, the DGPS base station 140 performs error detection and correction on the coordinate information, which is omitted according to the error detection and correction technique of general DGPS base station equipment (S370).

The process of calculating the position information of the mobile communication terminal 120 in the DGPS base station 140 may be performed in either real time processing or post processing. In this embodiment, there is no difference according to the adoption of the real time processing or the post processing method.

The base station 112, which has received the correct position information with the error correction, is loaded on the paging channel and transmits the information to the mobile communication terminal 120 (S380).

The mobile communication terminal 120 displays a coordinate value sent by the base station 112 to which the mobile communication terminal 120 belongs to the graphic liquid crystal display window. As a result, the current location information of the current subscriber displayed on the mobile communication terminal 120 is corrected and represented with high accuracy (S390).

As such, the present embodiment uses a DGPS reference station operated for error correction of a conventional GPS receiver and a CDMA mobile communication network using an existing repeater installed to improve call quality at a base station. Information can be provided.

The embodiments described above are within the scope of various changes, modifications, and equivalents of the present invention. Therefore, the present invention is not limited to the description of the examples.

According to the subscriber location information service method of the wireless communication network of the present invention has the following advantages.

First, location information can be provided to a subscriber of a wireless communication network at low cost by using an existing base station repeater and a DGPS reference station. In addition, compared to the conventional terminal location tracking method, the accuracy of the terminal location measurement can be improved, thereby ensuring the stability of the subscribers of the wireless communication network, thereby enabling the terminal location information service request for emergency rescue and rescue.

In particular, in the city center of high-rise buildings or apartment complexes, there are many error factors such as multipath fading, which results in poor positioning accuracy and poor call quality. In this case, when a small repeater suitable for improving call quality is installed around the base station and then the present invention is applied, the terminal location information is calculated using not only the measured values of the base stations but also the measured values of the repeaters. There is an advantage of improving the location tracking accuracy of the subscriber.

Claims (3)

A base station delay value in which a communication terminal measures a difference in transmission time delay of three or more base stations, including a difference in transmission time delay of a base station to which it belongs, and a transmission time delay of two or more adjacent base stations in preparation for handover. Measuring step; A repeater delay value measuring step of measuring, by the communication terminal, a difference in transmission time delays from a plurality of repeaters in a base station to which the communication terminal belongs; Transmitting to a base station to which the mobile station belongs; A circularity step of the base station receiving the transmission time delay measurement values after the transmitting step, forming circles representing distances from each base station and each repeater to the corresponding communication terminal according to the measurement values; A coordinate information calculating step of calculating, by the base station, coordinate information of the communication terminal by using intersections of the circles formed by the circularity step; A location information acquiring step, after the coordinate information calculation step, the DGPS reference station acquires terminal location information by performing error detection and correction on the calculated coordinate information; And a display step of transmitting the obtained terminal location information to a corresponding communication terminal to display the subscriber terminal for identification after the location information obtaining step. delete delete

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