KR100766602B1 - Method and system for measuring location using round-trip delay information in cdma network - Google Patents

Abstract

A method and a system for estimating a location by using round-trip delay information in a CDMA(Code Division Multiple Access) network are provided to remove an error of location estimation by correctly checking a service range of a mobile terminal based on RTD(Round-Trip Delay) information. A system for estimating location using round-trip delay information in a CDMA network includes a base station(506), a base station controller(508), an operation management unit(520), and a location estimation unit(516). The base station(506) calculates and transmits the round-trip delay information of a mobile terminal. The base station controller(508) generates a location information message by packing the location information and the round-trip delay information of the mobile terminal received from the base station(506). The operation management unit(520) receives the packed location information message from the base station controller(508). The location estimation unit(516) receives the location information message from the operation management unit(520) and estimates a location of the mobile terminal.

Description

METHODS AND SYSTEM FOR MEASURING LOCATION USING ROUND-TRIP DELAY INFORMATION IN CDMA NETWORK}

1 is a view showing the configuration of a position estimation system according to the prior art.

2 is a flowchart of a position estimation process using an exchange according to the prior art.

3 is a flowchart of a position estimation process using a PDSN according to the prior art.

4 is a diagram illustrating a connection configuration of a base station and a repeater according to the related art.

5 is a diagram illustrating a configuration of a position estimation system according to an exemplary embodiment of the present invention.

6 is a flowchart of a process of transmitting location information using a circuit call according to the present invention;

7 is a flowchart illustrating a location information transmission process using a packet call according to the present invention.

8 illustrates time delay in a base station service area.

9 illustrates time delay in an optical repeater service area.

10 illustrates time delay in an RF repeater service area.

11 is a view showing the configuration of an optical repeater service area according to an embodiment of the present invention.

12 is a diagram showing the configuration of an RF repeater service area according to an embodiment of the present invention.

13 is a view for explaining an example of a position estimation method using the RTD according to the present invention.

The present invention relates to a method and system for estimating position using round-trip delay information, and to a method and system for accurately estimating the position of a mobile terminal using an RTD value.

Algorithms and detailed methods for location tracking in mobile networks have been proposed. In the synchronous CDMA wireless network, the gpsOne method (Snap Track) proposed by Qualcomm is mainly used.

In the gpsOne method, GPS measurement data, a virtual noise phase (PN Phase), a cell ID, and an RTD value which are measured and provided to a system by a mobile terminal are mainly utilized. In this method, the calculation is divided into seven detailed methods.

In the case of GPS (Global Positioning System), AFLT (Advanced Forward Link Trilateration), and Hybrid, the location is based on the data measured by the mobile terminal according to the message defined in the standard (Standard: 3GPP2 C.S0022-A v1.0). Estimate

However, in the case of Cell Sector Round Trip Delay (Safe Net), the internal information of the system (especially the base station) is used, and there is no standard definition on how to use it or how to use it. In addition, there are currently only items that utilize this, but the situation is not practically implemented.

On the other hand, in the position estimation method, the GPS measurement data of the mobile terminal can be the most accurate position estimation, but there is a limitation that the mobile terminal must be in a position to receive the GPS signal of the satellite.

In case of position estimation through PN Phase (Pseudo Noise Phase), one Ref PN (Reference Virtual Noise) itself is provided because the mobile terminal in the traffic state performs service through only one active set. Therefore, it is difficult to secure a PN phase for position estimation.

On the other hand, in case of RTD (Round Trip Delay) information, information generated by the reception demodulation unit of the base station can extract information from a mobile terminal in a traffic state having one active set. Therefore, in a mobile terminal that performs service through only one active set or an area where GPS service is not available, it is possible to estimate the location more accurately by using RTD information.

However, in the current mobile communication network, a standard for determining the position of the mobile terminal to receive RTD information is not determined. Therefore, the conventional location estimation apparatus estimates the location using only Cell ID information, GPS measurement data, and PN phase information provided by the base station, but this has a problem of showing a lot of errors.

1 is a view showing the configuration of a position estimation system according to the prior art.

Referring to FIG. 1, the conventional location estimation method includes first, a method via a mobile switching center (MSC) 108 that performs a voice service, and second, a packet data serving node (PDSN) 110 performing a data service. It is divided into ways via.

The method via the switch 108 is a method of finding a location of a mobile terminal through a registration order method or a paging method.

2 is a flowchart of a position estimation process using an exchange according to the prior art.

Referring to FIG. 2, when the location estimating apparatus 112 requests a location from the switch 108 (step 200), the switch 108 sends a registration request order to a base station controller 106. Message) (step 202).

The base station controller 106 transmits a paging signal to the base transceiver station (BTS) 104 (Ordered Registration, step 204). Here, the paging signal is a position registration request signal by a command of the base station controller 104.

The mobile station 100 transmits a paging response signal to the base station controller 106 (Ordered Registration, step 206).

The base station controller 106 then sends a Location Update Request Message of the mobile terminal to the exchange (step 208), and the exchange 108 sends its response message to the base station controller 106 (step 210).

The base station controller 106 transmits the cell ID information to which the mobile terminal belongs to the switch 108 according to the A1 standard (3GPP2 A.S001) (step 212).

The exchange 108 transmits the cell ID information to the location estimating apparatus 112 (step 212), and the location estimating apparatus 112 determines the location of the base station to which the mobile terminal belongs via the cell ID.

The location information service calculated according to the above method is mainly used in a service with low accuracy.

On the other hand, the way via the PDSN (110) is a method of finding the location of the mobile terminal based on the message measured by the terminal.

3 is a flowchart of a position estimation process using a PDSN according to the prior art.

Referring to FIG. 3, the mobile terminal 100 transmits an initialization signal to the base station controller 106 (step 300), and the base station controller 106 requests connection management (Connection Management) to the exchange 108 (step). 302).

The exchange 108 then requests channel assignment to the base station controller 106 (step 304), thus establishing a traffic channel between the base station controller 106 and the mobile terminal 100 (step 306).

After the traffic channel is established, a channel for packet data service is established between the base station controller 106 and the PDSN 110 (A11 Setup, step 308).

Thereafter, the mobile terminal 100 transmits information for estimating the position of the mobile terminal, for example, GPS measurement data, a cell ID, and a PN phase to the position estimating apparatus, and the position estimating apparatus 112 estimates the estimated position information. Is provided to the mobile terminal 100 (step 310).

The method shown in FIG. 3 uses the data call connection through data paging, the data connection through SMS paging, or the data connection by the subscriber's request. Is measured and transmitted to the location estimating apparatus via the PDSN.

Here, signal processing is performed according to the standard defined in 3GPP2 C.S0022 (or IS-801), and is mainly used in high accuracy services.

However, according to the related art, the position estimating apparatus 112 may acquire only cell ID information when passing through the MSC, and only GPS measurement data, cell ID, and PN phase may be obtained when passing through the PDSN. . That is, in the related art, a standard for transmitting RTD (Round-Trip Delay) information to the position estimating apparatus is not defined.

On the other hand, even when using the RTD information, when estimating the location of the mobile terminal, many errors will inevitably occur.

In order to accurately estimate the location of the mobile terminal, the mobile communication network is ideally constructed only with a base station.

However, as shown in FIG. 4, the mobile communication network is constructed with the base station 400 and the repeaters 402, 404, 406 due to the reduction of investment cost and other reasons. Two to five optical repeaters 402 are usually connected to each sector of the base station 400 to extend service coverage, and in-building repeaters 404 and RF repeaters 406 are constructed in each shaded area. It is.

Since the optical repeater 402 is connected to the base station by an optical cable, the factor of delaying the signal may be analyzed as the delay due to the optical cable and the delay of the optical repeater itself.

In the case of the RF repeater 406, a service may be provided through a base station or an optical repeater. Therefore, the signal delay factor of the RF repeater may be a delay of the RF repeater when serving through the signal of the base station. In addition, in case of service through another repeater signal, it may have various delay factors such as delay factor to other repeater, delay of other repeater itself, and delay of RF repeater.

In particular, in the case of the optical repeater 402, it is difficult to predict the delay because the optical cable is not laid in the diameter path between the base station 400 and the optical repeater 402. Therefore, in order to estimate the location of the subscriber station in the repeater region other than the direct service area of the base station, a large number of errors of the PN-Phase or the RTD itself occur, and thus, a large number of errors of the position estimate are generated.

In the present invention, to solve the problems of the prior art as described above, it is proposed a position estimation method and system using the round trip delay information that can transmit the RTD (round trip delay) information to the position estimation device.

Another object of the present invention is to provide a method and system for estimating position using round trip delay information that can minimize errors in using RTD information.

In order to achieve the above object, according to a preferred embodiment of the present invention, a system for estimating the location of a mobile terminal, the base station for calculating the RTD information of the mobile terminal; A base station controller for generating a location information message by packing RTD information of the mobile terminal and location related information of the mobile terminal; A packing message relay unit for receiving the packed location information message from the base station controller; And a position estimating unit for receiving the position information message from the packing message relay unit and estimating the position of the mobile terminal.

According to another aspect of the present invention, a system for estimating a location of a mobile terminal, comprising: a base station for calculating RTD information of the mobile terminal; A base station controller configured to receive RTD information of the mobile terminal and location related information of the mobile terminal; An operation manager to pack the RTD information of the mobile terminal and the location related information to generate a location information message; And a position estimating unit for receiving the position information message from the operation management unit and estimating the position of the mobile terminal.

According to another aspect of the present invention, a method for estimating the position of a mobile terminal in a mobile communication system including a base station, a base station controller, an operation management unit, and a position estimating unit, (a) the base station receives RTD information of the mobile terminal; Calculating; (b) receiving, by the base station controller, RTD information of the mobile terminal and location related information of the mobile terminal; (c) at least one of the base station controller and the operation manager packing the RTD information and the location related information of the mobile terminal to generate a location information message; And (d) the location estimator receiving the location information message to estimate the location of the mobile terminal.

According to another aspect of the present invention, a method for estimating a position of a mobile terminal in a mobile communication system including a base station, a repeater, a base station controller, a packing message relay unit, and a position estimating unit (a) the base station controller and packing message relay Receiving, by at least one of the units, a location information message generated by packing RTD information of the mobile terminal and location related information of the mobile terminal; (b) comparing the inherent RTD information of the databased repeater and the RTD information of the mobile terminal to determine a service area of the mobile terminal; And (c) estimating the location of the mobile terminal based on the determined service area.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components have the same number as much as possible even if displayed on different drawings. Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of a method and system for estimating position using the round trip delay information according to the present invention.

5 is a diagram illustrating a configuration of a position estimation system according to an exemplary embodiment of the present invention.

5 illustrates a CDMA network, as shown in FIG. 5, a position estimation system according to the present invention includes one or more repeaters 502, 504, a base station 506, a base station controller 508, an exchange 510, a home. Location register (HLR, 512), PDSN (Packet Data Serving Node, 514), location estimator 516, NMS (Network Management System, 518) and operation management (Operating and Management: O & M, 520) It may include.

The base station 506 performs a wireless connection with the mobile terminal 500 and a wired / wireless connection function between the mobile terminal 500 and the base station controller 508. Although FIG. 5 illustrates one base station 506, it will be apparent to those skilled in the art that a plurality of base stations may be included.

The base station controller 508 is located between the base station 506 and the switch 510 and is responsible for base station management and control. The exchange 510 provides a mobile communication service to a mobile communication subscriber. The exchange 510 has functions such as circuit switching between subscribers, incoming and outgoing relay processing, handoff, and roaming, and manages a VLR (Visitor Location Register) database.

The home location register 512 is connected to the exchange 510 and stores information about the mobile terminal subscriber.

The PDSN 514, which provides packet data service to the mobile terminal, is connected to the base station controller 508 and performs the process of establishing, maintaining, and terminating a Point-to-Point Protocol (PPP) session for the subscriber.

The position estimator 516, which is connected to the PDSN 514 and the exchange 510, may include a Position Determination Entity (PDE) 516. The location estimator 516 has a function of receiving a GPS signal, receives information related to the location of the mobile terminal 500 using a line call or a packet call, and estimates the location of the mobile terminal 500.

The NMS (latitude and longitude storage unit) 518 manages location information of base stations and repeaters included in the mobile communication network, that is, latitude and longitude information. The location estimator 516 may estimate the location of the mobile terminal 500 by referring to latitude and longitude information of the NMS 518.

The operation manager O & M 520 is connected to the base station controller and is responsible for maintenance and repair of the base station 506 and the base station controller. Typically, when the base station 506 establishes a call with the mobile terminal 500 and the base station controller 508, the base station controller 508 periodically calculates round trip delay (RTD) information of the mobile terminal 500. To send.

Here, RTD (round trip delay) information means a propagation delay that occurs while the mobile terminal 500, the base station 506, and the repeaters 502 and 504 transmit and receive signals wirelessly. RTD of the mobile terminal 500 RTD is the self delay of the mobile terminal 500, the radio link delay between the mobile terminal 500 and the base station 506 or repeaters (502, 504) and of the base station 506 or repeaters (502, 504) It contains information about self delays.

The RTD information of the mobile terminal is generated by one or more base station 506 demodulators corresponding to the service area of the mobile terminal 500. Conventionally, a standard for transmitting such RTD information to the location estimator 516 is not determined. Did.

According to the present invention, when the base station controller 508 receives the RTD information of the mobile terminal from the base station 506 in order to transmit the RTD information to the position estimating unit 516, the RTD information and the position related information of the mobile terminal are transmitted. Pack to generate location information message. Alternatively, the base station controller transmits the RTD information and the location related information of the mobile terminal to the operation management unit 520 (O & M equipment), respectively, and the location management message is packed by the operation management unit 520 (O & M equipment). Can be generated.

Information included in the location information message is shown in Table 1 below.

Geo message division Contents Remarks Msg ID Indicates the message type Distinguish PSMM / PPSMM Seq ID Serial number generated in each job Serial number of the PSMM / PPSMM Time When the message occurs - Mobile ID Terminal MDN or IMSI REF_PN Reference PN Obtained from PSMM or PPSMM Number of PN PNs measured Obtained from PSMM or PPSMM MSC [0] NID number that the system has (exchange switch) Determining PN by using PN Phase acquired by the terminal and acquiring it through neighbor list stored in the system BSC [0] BSC number the system has BTS [0] BTS number the system has SEC [0] Sector number of system PN [0] PN the system has PN_PHASE [0] Information acquired by the terminal Obtained from PSMM or PPSMM PN_Strength [0] Information acquired by the terminal Obtained from PSMM or PPSMM RTD [0] Round trip delay measured by the system Acquired from BTS ㆍ ㆍ ㆍ ㆍ ㆍ ㆍ ㆍ ㆍ ㆍ NID [n] NID number that the system has (exchange switch) Determining PN by using PN Phase acquired by the terminal and acquiring it through neighbor list stored in the system BSC [n] BSC number the system has BTS [n] BTS number the system has SEC [n] Sector number of system PN [n] PN the system has PN_PHASE [n] Information acquired by the terminal Obtained from PSMM or PPSMM PN_Strength [0] Information acquired by the terminal Obtained from PSMM or PPSMM RTD [n] Round trip delay measured by the system Acquired from BTS

As shown in Table 1, the location information message according to the present invention includes RTD [0 to n] information according to an active set (set of base stations connected to the mobile terminal) of the mobile terminal. In addition, an exchange identifier, a base station controller identifier, a base station identifier, a sector identifier, virtual noise identifier information, etc., to which the mobile terminal 500 belongs, are included.

According to the present invention, the location information message generated by the base station controller 508 may be transmitted to the location estimator 516 via the packing message relay. In addition, the location information message generated in the O & M equipment through each information received from the base station controller may be transmitted to the location estimation unit.

Here, the packing message relay unit is a component for transmitting the location information message to the location estimating unit 516. Preferably, the operation manager 520 may generate and relay a packing message. It can be made through a dedicated interlocking device connected to).

In the present invention, the use of the operation management unit is generally because the mobile communication provider already uses a dedicated line line for centralizing the data of the operation management unit (O & M).

According to the present invention, the location information message may be transmitted to the location estimator 516 using a circuit call for voice service and a packet call for data service.

6 is a flowchart illustrating a process of transmitting location information using a circuit call according to the present invention.

Referring to FIG. 6, when the position estimating unit (position estimating apparatus) requests a position to the switch 510 (step 600), the switch 510 transmits a paging signal to the mobile terminal 500 (step 602). .

Thereafter, the mobile terminal 500 transmits a paging response signal to the base station controller 508 (step 604), and the base station controller 508 transmits the response signal to the exchange 510 (step 606, Paging Response transmission). ).

The exchange 510 makes an allocation request to the base station controller 508 (step 608), and the base station controller 508 establishes a call with the mobile terminal 500 in accordance with the allocation request. (Step 610). After the call is established, the base station controller 508 sends a call setup complete message to the exchange 510 (step 612). After the call setup, the base station 506 calculates the RTD of the mobile terminal and periodically sends it to the base station controller 508 (step 614).

Base station controller 508, on the other hand, requests periodic pilot measurement report to mobile terminal 500 (Periodic Pilot Measurement Report Order: PPMRO, step 616).

PPMRO includes the information shown in Table 2 below.

In response to the request, the mobile terminal 500 transmits a pilot strength measurement message (PSMM) or a pilot pilot strength measurement message (PPSMM) to the base station controller 508 (step 618).

The PSMM or PPSMM includes virtual noise phase (PN-Phase) information as shown in Tables 3 and 4 below.

The base station controller 508 periodically receives the RTD information from the base station 506 (step 620), and generates a message and transmits the location information including the virtual noise phase and the RTD information to the operation manager 520 (step 622). ).

As described above, the location information message according to the present invention may further include an exchange, a base station controller, and a base station identifier in addition to the virtual noise phase and RTD information.

The operation manager 520 transmits the generated or received location information message to the location estimator 516 (step 624).

The location estimating unit 516 according to the present invention may perform a process of estimating the location of the mobile terminal using the RTD information of the mobile terminal included in the location information message.

On the other hand, Figure 7 is a flow diagram of a location information transmission process using a packet call according to the present invention.

Referring to FIG. 7, the mobile terminal 500 transmits an initialization signal to the base station controller 508 (step 700), and the base station controller 508 requests the switch 510 to manage the connection (step 702).

Switch 510 then requests channel assignment to base station controller 508 (step 704), thereby establishing a traffic channel between base station controller 508 and mobile terminal 500 (step 706).

After the traffic channel is established, a channel for packet data service is established between the base station controller 508 and the PDSN 514 (A11 Setup, step 708).

Meanwhile, as described above, when a call is established between the mobile terminal 500 and the base station controller 508, the base station 506 periodically calculates and transmits RTD information of the mobile terminal to the base station controller (step 712).

The base station controller 508 transmits the PPMRO to the mobile terminal 500 as in FIG. 6 (step 714), and the mobile terminal 500 transmits the PSMM or PPSMM including the virtual noise phase to the base station controller 508. (Step 716).

At the same time, the base station controller 508 receives RTD information from the base station 506 (step 718), and the base station controller 508 generates a location information message including the information as shown in Table 1 above, or generates respective information. Transfer to operation management unit 520 (step 720).

The operation manager 520 transmits the location information message generated by the base station controller 508 to the location estimator 516 (step 722). In this case, the base station controller 508 may transmit only the RTD information and the location related information of the mobile terminal, and the operation manager 520 may generate the location information message by packing the above information.

Meanwhile, the location estimator 516 may receive GPS data measured by the mobile terminal 500 in addition to the location information message according to the IS-801 standard (step 724).

When data for position estimation is received, the position estimator 516 estimates the position of the mobile terminal 500.

Thereafter, the base station controller 508 and the PDSN 514 release the A11 setting (step 726), and the mobile terminal 500 and the exchange 510 release the call (step 728).

As described above, since the base station controller 508 according to the present invention packs the RTD information of the mobile terminal together with other location related information, the operation manager 520 transmits the packed message to the location estimator 516. The location estimator 516 can calculate the location of the mobile terminal more accurately using the RTD information.

On the other hand, in the system as shown in Figure 5, the end of the system for performing the mobile communication wireless network service is the base station 506, the repeater (502, 504) is used to widen the service radius of the base station and eliminate the shadow area.

Depending on the location and location, there are many places where the radius of service by the repeater is wider than that of the base station itself. Currently used repeaters are commonly referred to as optical repeaters (optical repeaters, In-Building repeaters, 502), RF repeaters (referred to as repeaters not connected to the base station, depending on the interworking method with the base station, band conversion repeaters, micro repeaters, ICS repeaters, including small and ultra small home repeaters).

In the service coverage illustrated in FIG. 4, if the mobile terminal is in a direct coverage area through the antenna of the base station, the radial distance between the base station and the terminal can be estimated relatively accurately through the RTD.

However, in the case of mobile terminals in optical repeater area, in-building repeater area, and RF repeater area, the measured RTD value has considerably large RTD value due to delay effect such as optical cable or repeater's own delay component. Due to this, many errors occur in estimating the radial distance between the base station and the terminal. The delay components in each service area are classified as follows.

8 is a diagram illustrating a time delay in a base station service area.

Referring to FIG. 8, the base station direct service area includes a base station self delay (BTS_Delay), a radio link delay (BTS_RF_Delay) to the mobile terminal, and a mobile terminal self delay (MS_Delay). Is determined as follows.

Full RTD = BTS_Delay + 2 * BTS_RF_Delay + MS_Delay

FIG. 9 is a diagram illustrating a time delay in the optical repeater service area, and FIG. 9 illustrates a configuration in which the base station 506 and the optical repeater 502 are connected by optical cables and optical end stations 900 and 902.

Referring to FIG. 9, the delay in the optical repeater service area may include a base station self delay (BTS_Delay), a mobile terminal self delay (MS_Delay), a delay (Optic_Delay) between the base station 506 and the optical repeater through the optical station 900,902, The repeater itself delay (Repeater_Delay), and the radio link delay from the repeater to the mobile terminal (Repeater_RF_Delay).

At this time, the total RTD value is calculated through Equation 2 below.

Total RTD = BTS_Delay + MS_Delay + 2 * Optic_Delay + Repeater_Delay + 2 * Repeater_RF_Delay

10 is a diagram illustrating time delay in the RF repeater service area.

Referring to FIG. 10, in the RF repeater service area, a base station self delay (BTS_Delay), a mobile terminal self delay (MS_Delay), a radio link delay (BTS_Repeater_RF_Delay) between a signal source base station (mortgage station) and an RF repeater, and an RF repeater self delay (Repeater_Delay), there is a radio link delay (Repeater_RF_Delay) from the RF repeater to the mobile terminal.

At this time, the total RTD value is calculated through Equation 3 below.

Total RTD = BTS_Delay + MS_Delay + 2 * BTS_Repeater_RF_Delay + Repeater_Delay + 2 * Repeater_RF_Delay

In the above, the parts that can predict each delay value are the base station itself delay, the self delay of the mobile terminal, the optical repeater itself delay and the RF repeater itself delay. In other words, each system and terminal have a provision for a delay value during production, so it is not a problem to make a prediction.

The biggest problem is the delay component by the optical end station and the optical cable between the base station and the optical repeater. Since it is practically difficult to install the optical cable between the base station and the optical repeater in diameter, it is laid longer than the actual distance between the actual base station and the optical repeater. If the correct DB is made, it helps a lot in predicting the delay value, but the reality is that the accurate DB for the installed length is not managed, and this is also the case for the RF repeater.

In order to accurately estimate the location of the mobile terminal, it is necessary to accurately predict the RTD value of the repeater in each service area. According to the present invention, as illustrated in FIGS. 5, 11, and 12, the repeaters 502 and 504 The unique RTD measurement unit 503 is connected.

Here, the unique RTD analysis unit may be 1/8 chip unit, but another chip unit may be used.

11 is a diagram showing the configuration of an optical repeater service area according to an embodiment of the present invention, Figure 12 is a diagram showing the configuration of an RF repeater service area according to an embodiment of the present invention.

The inherent RTD measuring unit 503 according to the present invention measures the inherent RTD values of the optical repeater 502 and the RF repeater 504, etc., to compensate for the position estimation error, preferably wired to the debugger port of the repeater. Can be directly connected.

The direct connection to the debugger port is to keep the active set of native RTD measurement unit 503 as one and to minimize delay between the repeater and native RTD measurement unit 503.

In addition, the unique RTD measurement unit 503 may be a mobile terminal carried by the operator, otherwise it may be a terminal that is pre-equipped to transmit the RF test and abnormality of the repeater to the NMS (518).

As described above, since the inherent RTD measurement unit 503 according to the present invention is connected to the repeater with a minimum delay, the inherent RTD value calculated by the inherent RTD measurement unit 503 is represented by Equation 2 and the above. In Equation 3, the radio link delay from the repeater to the mobile terminal is neglected.

Therefore, the inherent RTDs of the optical repeater and the RF repeater are calculated through Equations 4 and 5 below.

Inherent RTD of optical repeater = BTS_Delay + MS_Delay + 2 * Optic_Delay + Repeater_Delay

Unique RTD of RF Repeater = BTS_Delay + MS_Delay + 2 * BTS_Repeater_RF_Delay + Repeater_Delay

Since the unique RTD measuring unit 503 is directly connected to the optical repeater or the RF repeater, the unique RTD measured by the unique RTD measuring unit 503 may be transmitted to the position estimating unit 516 while maintaining the traffic state with only one active set. Can be.

The process of transmitting the measured unique RTD information by the unique RTD measuring unit 503 may be the same as the call processing procedure of FIG. 6, and may be transmitted and stored in advance to the position estimating unit to estimate the position of the mobile terminal 500. have.

When the location estimation unit 516 receives the RTD information of the mobile terminal 500 from the operation management unit 520 as shown in Figs.

When the mobile terminal belongs to a plurality of base station service areas, the mobile terminal RTD may be calculated corresponding to one or more base stations, and the location estimator 516 may include an optical repeater in which the mobile terminal RTD corresponding to one or more base stations belongs to each base station. Or, it is determined whether it is larger than the inherent RTD of the RF repeater.

If the mobile terminal RTD at a specific base station is larger than the unique RTD of the optical repeater or RF repeater belonging to the base station, the location estimator 516 determines that the mobile terminal 500 is in the optical repeater or RF repeater service area. In the opposite case, it is determined that the base station is in the service area.

After the service area is determined, the position estimator 516 according to the present invention performs a process of measuring the exact position of the mobile terminal by referring to latitude and longitude information of the base station and the repeater stored in the NMS 518.

For example, when it is determined to belong to a specific repeater service area, the position estimator 516 calculates a distance where the mobile terminal is located in the repeater through Equation 6 below.

Distance from repeater = (RTD of mobile terminal-inherent RTD of repeater) / 2 * 3 * 10 ⁸

Meanwhile, when belonging to the base station service area, the distance from the base station of the mobile terminal is calculated through Equation 7 below.

Distance from base station = (RTD of mobile terminal-native RTD of base station) / 2 * 3 * 10 ⁸

According to the present invention, RTD values of mobile terminals corresponding to one or more base stations may be received in the location information message received by the location estimator 516. In this case, the location estimator 516 may estimate the location of the mobile terminal by calculating the distance of the mobile terminal 500 from each base station (or a repeater belonging to the base station).

13 is a view for explaining an example of a position estimation method using the RTD according to the present invention.

In Fig. 13, the basic premise is as follows.

1) Latitude / longitude of A base station 506-1: 37-29-08.126, 127-00-45.981

2) Latitude / longitude of B base station 506-2: 37-29-30.769, 127-01-29.859

3) Latitude / longitude of optical repeater 502: 37-29-22.174, 127-00-51.123

4) RTD analysis unit: 1/8 chip

5) Base station self delay (BTS_Delay): 240

6) Unique RTD of Optical Repeater: 520

In addition, the information included in the location information message received from the operation management unit 520 according to the present invention is shown in Table 5 below.

Location Information Message for the Example of FIG. 13 division Unique RTD Measurement Unit Mobile terminal Remarks Msg ID One One Seq ID One 2 Time 00: 00: 00: 00 00: 00: 20: 00 Mobile ID 010-####-#### 010-####-#### REF_PN 4 4 Number of PN One 2 MSC [0] One One BSC [0] One One BTS [0] One One SEC [0] 0 0 PN [0] (pseudo noise) 4 8 PN_PHASE [0] 0 0 1 chip unit PN_Strength [0] 4 8 RTD [0] 520 550 1/8 chip unit NID [1] One BSC [1] One BTS [1] 2 SEC [1] 0 PN [1] 8 PN_PHASE [1] 497 1 chip unit PN_Strength [0] 14 RTD [1] 290 1/8 chip unit

In Table 5, the location information message transmitted from the unique RTD measurement unit 503 and the mobile terminal 500 are simultaneously shown, where RTD [0] is the base station A of the mobile terminal corresponding to the base station A and RTD [1] Value.

In FIG. 13, the mobile terminal 500 is composed of two active sets.

On the other hand, the unique RTD measurement unit 503 is composed of one active set, the unique RTD information is calculated by the above equation (4).

13 and Table 5, the RTD of the mobile terminal 500 corresponding to the A base station 506-1 is 550, and the RTD of the mobile terminal corresponding to the B base station 506-2 is 290.

For the base station A, the mobile terminal 500 is determined to be in the service area of the optical repeater because the RTD 550 of the mobile terminal is larger than the native RTD 520 of the optical repeater connected to the base station A.

On the other hand, for the base station B, it is RTD 290 of the mobile terminal, and since there is no unique RTD for the repeater, the mobile terminal is determined to be in the service area of the base station B.

Accordingly, the radii at the repeater belonging to the base station A and the base station B, which can be obtained through the RTD, are calculated as follows through Equations 6 and 7.

Radius centered on optical repeater connected to base station A = (550-520) / 2/8 * 3 * 10 ⁸ / 1,228,800 = 458 (m)

Radius centered on base station B = (290-240) / 2/8 * 3 * 10 ⁸ / 1,228,800 = 763 (m)

Here, 1/8 corresponds to an analysis unit, and the resolution of each base station and the receiving chip manufacturer may be larger (1/16), but is generally about 1/9.

In the above-described method, when the radius is calculated from the repeater or the base station, as shown in FIG. 13, the position of the mobile terminal 500 can be accurately estimated.

If, as in the present invention, the location of the mobile terminal is estimated without using a unique RTD, a large error occurs.

For example, in the above, if the radius is obtained around the RTD of the base station A, a large error occurs as follows.

Radius centered on base station A = (550-240) / 2/8 * * 3 * 10 ⁸ / 1,228,800 = 4730

According to the present invention, the service area of the mobile terminal can be grasped to accurately estimate the location of the mobile terminal, and even if the base station includes a large number of repeaters, the repeater's unique RTD is used to determine in which service area the mobile terminal is located. It can be confirmed that accurate position estimation is possible.

On the other hand, when servicing in a building by using an in--ilding repeater, it is likely that the mobile terminal counts one active set through a location information message because the signal from the repeater is usually counted in the traffic state. . In this case, the repeater's unique RTD will be sufficient to know that the subscriber is in a particular building.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art will be able to make various modifications, changes, and additions within the spirit and scope of the present invention. Additions should be considered to be within the scope of the following claims.

As described above, according to the present invention, there is an advantage in that the accuracy of location information estimation of the mobile terminal can be improved in a CDMA wireless network.

In addition, according to the present invention, since the RTD information which is an important factor for estimating the position can be transmitted to the position estimating unit, there is an advantage that accurate position estimation is possible.

In addition, according to the present invention, it is possible to accurately grasp the service area of the mobile terminal through the unique RTD information has the advantage of eliminating the error of the location estimation.

Claims (18)

In the system for estimating the position of the mobile terminal, A base station for calculating and transmitting RTD information of the mobile terminal to a base station controller; A base station controller for generating a location information message by packing RTD information of the mobile terminal and location related information of the mobile terminal received from the base station; An operation manager to receive the packed location information message from the base station controller; And And a position estimating unit configured to estimate the position of the mobile terminal by receiving the position information message from the operation manager. delete The method of claim 1, And at least one base station for calculating RTD information of the mobile terminal. The method of claim 1, And the location-related information includes at least one of an exchanger identifier, a base station controller identifier, a base station identifier, a sector identifier, and a virtual noise identifier information included in a mobile communication network. The method of claim 1, A repeater for extending service coverage of the mobile terminal; And Position estimating system further comprises a unique RTD measuring unit for measuring the unique RTD information of the repeater. The method of claim 5, The unique RTD measurement unit is connected to a debugger port of the repeater. The method of claim 5, The repeater is an optical repeater, and the inherent RTD measuring unit is configured to determine one or more of the inherent RTD of the optical repeater by the base station self delay, the self delay of the mobile terminal, the radio link delay between the base station and the optical repeater, and the self delay of the optical repeater. Calculating the sum by calculating the position. The method of claim 5, The repeater is an RF repeater, and the inherent RTD measurement unit is configured to determine the inherent RTD of the RF repeater, the self delay of the base station, the self delay of the mobile terminal, the radio link delay between the signal source base station and the RF repeater, and the RF repeater itself. And estimating at least one of the delays. The method of claim 5, And the location estimating unit determines a service area of the mobile terminal by comparing an RTD of the mobile terminal corresponding to one or more base stations with a unique RTD corresponding to one or more repeaters belonging to each base station. The method of claim 9 Latitude and longitude data storage unit for storing the latitude and longitude data of the base station and the repeater, And the location estimating unit estimates the location of the mobile terminal based on the latitude and longitude data after determining whether the service area of the mobile terminal is a base station or a repeater. The method of claim 1 And the location information message is transmitted using at least one of a circuit call and a packet call. In the system for estimating the position of the mobile terminal, A base station for calculating RTD information of the mobile terminal; A base station controller configured to receive RTD information of the mobile terminal and location related information of the mobile terminal; An operation manager to pack the RTD information of the mobile terminal and the location related information to generate a location information message; And And a position estimating unit configured to estimate the position of the mobile terminal by receiving the position information message from the operation manager. A method for estimating the position of a mobile terminal in a mobile communication system including a base station, a base station controller, an operation manager, and a position estimator, (a) calculating, by the base station, RTD information of the mobile terminal; (b) receiving, by the base station controller, RTD information of the mobile terminal and location related information of the mobile terminal; (c) at least one of the base station controller and the operation management unit packs the RTD information and the location related information of the mobile terminal to generate a location information message; and and (d) estimating, by the position estimator, the position of the mobile terminal by receiving the position information message. A method for estimating the position of a mobile terminal in a mobile communication system including a base station, a repeater, a base station controller, an operation manager, and a position estimator, (a) receiving, by at least one of the base station controller and the operation manager, a location information message generated by packing RTD information of the mobile terminal and location related information of the mobile terminal;  (b) comparing the inherent RTD information of the databased repeater and the RTD information of the mobile terminal to determine a service area of the mobile terminal; And (c) estimating the position of the mobile terminal based on the determined service area. delete The method of claim 14, And the location-related information includes at least one of an exchanger identifier, a base station controller identifier, a base station identifier, a sector identifier, and a virtual noise identifier information included in a mobile communication network. The method of claim 14, The repeater is an optical repeater, and the unique RTD of the optical repeater is calculated by summing one or more of the base station self delay, the self delay of the mobile terminal, the delay between the base station and the optical repeater, and the self delay of the optical repeater. Position estimation method. The method of claim 14, The repeater is an RF repeater, and the unique RTD of the RF repeater is one or more of a self delay of the base station, a self delay of the mobile terminal, a radio link delay between a signal source base station and the RF repeater, and a self delay of the RF repeater. A position estimation method characterized in that it is calculated by adding up.

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