KR100683906B1 - Method and System for Providing Location Finding Service by Using Frequency Offset - Google Patents

Abstract

The present invention relates to a method and a system for providing a location detection service using frequency offset.

The present invention by artificially applying a frequency offset to the wireless communication signal path via a passive divider, a bidirectional amplifier and a repeater between the base station and the terminal to determine the position of the terminal located in the coverage of the bidirectional amplifier or repeater, The present invention relates to a method and system for providing a service for more accurately detecting a location of a terminal by using an applied frequency offset as a cell identifier such as coverage of a repeater.

According to the present invention, it is possible to recognize the repeater in the cell and to provide a way to determine the location of each mobile communication terminal in the in-building environment to increase the accuracy of the location detection service to provide a variety of location-based services using the same The effect is that you can.

Location Detection, Frequency Offset, Repeater, Inbuilding, Mobile Terminal, Location Based Service

Description

Method and system for providing location detection service using frequency offset {Method and System for Providing Location Finding Service by Using Frequency Offset}

1 is a diagram showing the configuration of a mobile communication system having a plurality of base stations and repeaters in a cellular environment;

2 is a block diagram showing a system for providing a location detection service using a frequency offset according to a preferred embodiment of the present invention;

3 is a block diagram schematically illustrating a system for position detection using a divider and a frequency offset device in an inbuilding environment according to a preferred embodiment of the present invention;

FIG. 4 is a block diagram schematically illustrating a system for detecting a location using a divider and a frequency offset device in multiple stages in an in-building environment according to a preferred embodiment of the present invention; FIG.

5 is a block diagram showing the configuration of a repeater including a frequency offset generator according to a preferred embodiment of the present invention;

6A is a block diagram showing an internal configuration of a frequency offset generator according to a first embodiment of the present invention;

6B is a block diagram showing an internal configuration of a frequency offset generator according to a second preferred embodiment of the present invention;

7 is a graph showing a relationship between a frequency offset and a Doppler transition,

8A and 8B are views showing the form of position information including frequency offset error information according to a preferred embodiment of the present invention;

9A is a diagram illustrating a case where a multi-frequency offset component is generated in a base station and a repeater region when detecting a position according to an exemplary embodiment of the present invention;

9B is a diagram illustrating a case where a multi-frequency offset component is generated in a plurality of repeater regions when detecting a position according to an exemplary embodiment of the present invention.

10 is a view for explaining a method of setting a frequency offset and frequency offset error in a repeater, etc. according to a preferred embodiment of the present invention;

FIG. 11 is a diagram for describing frequency offset setting when a value of a frequency offset provided to a base station modem is an average value of actual frequency offsets of each finger according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

200: mobile communication terminal 202: frequency offset generator

204: Splitter 206: Mobile Communication Network

208: base station 210: base station controller

212: mobile switching center 214: location detection server

The present invention relates to a method and a system for providing a location detection service using frequency offset. More specifically, the frequency offset is artificially applied to the wireless communication signal path via the passive divider, the bidirectional amplifier, and the repeater between the base station and the terminal so that the position of the terminal located in the coverage of the bidirectional amplifier or the repeater can be determined. The present invention relates to a method and a system for more accurately detecting a location of a terminal by using an applied frequency offset as a cell identifier such as coverage of a repeater.

Since the Internet communication service, which is symbolized by the World Wide Web, has been in the spotlight, communication service has already made a big difference in human life in all aspects of society, economy and politics. Therefore, in recent years, the diffusion of high-speed communication network, such as the Internet infrastructure for using a variety of communication services in a better environment has been greatly increased.

In addition, in recent years, a number of companies have been developing technology for wireless Internet to provide a communication service that transcends space. The wireless Internet service refers to a service that provides Internet contents through a mobile communication network. The wireless Internet service is an advanced personalization service according to the use of the terminal of the individual and has a feature of providing a unique information based on the mobility of the user. In particular, recently, Location Based Services (LBS) has been highlighted among various wireless Internet services.

Location-based service refers to a communication service that locates a portable terminal such as a mobile phone, a personal digital assistant (PDA), a notebook PC, and provides additional information related to the identified location. Location-based services are integrated with information processing technologies such as mobile communication technology, Internet technology, mobile terminal technology, Geographical Information System (GIS), Global Positioning System (GPS), Intelligent Transport System (ITS), and various contents technologies. The service is expected to explode in the future.

In order to use the location-based service, it is essential to know the location of the wireless communication terminal. The technique of locating a wireless communication terminal is called PDT (Position Determination Technology), which is a handset-based method using a Global Positioning System (GPS) signal and a network using a base station received signal. -Based) method, and recently, a hybrid method that combines the two technologies to improve the position accuracy has been developed.

Any handset-based method using GPS has the advantages of freely available anyone, unlimited number of users, continuous positioning in real time, and relatively accurate position measurement.

However, the handset-based method using GPS has a problem that the path for location measurement is multiple and the location determination ability is limited especially in the city center due to lack of visible satellites. In addition, positioning is almost impossible in a place where satellites are not visible (such as in a tunnel, inside a building, or in a basement of a building), and a large error occurs in the positioning state according to the placement of the satellite viewed from the receiver. There is this. In addition, the time to first fix (TTFF), which is the actual time required for the GPS receiver to determine its location in the first place, sometimes takes about several minutes to several tens of minutes, which can be helpful to service users of location-based wireless Internet. There is a problem that causes great inconvenience.

Therefore, the network-based approach is mainly used in the shadow area of GPS propagation. The basic principles of network-based positioning include Angle of Arrival (AOA), RF Fingerprint, and Time Difference of Arrival (TDOA). The network-based method has the advantage that positioning is possible even in the shadow area of GPS radio waves, but since the position of the terminal is measured by identifying the cell in which the terminal is included, accurate positioning may not be performed as compared to the handset-based method using GPS. There is a problem.

1 is a diagram illustrating a configuration of a mobile communication system having a plurality of base stations and repeaters in a cellular environment.

In the following description, a code division multiple access (CDMA) system is mainly described for convenience of description. In FIG. 1, the location of the terminal is illustrated in three cases.

First, since the terminal 1 (100) is directly connected to the base station 1 (102), the position detection can be easily performed. Since the terminal 1 100 is located in an open area, the terminal 1 100 may detect a location using a handset based method using a GPS signal, and since the terminal 1 100 is directly connected to the base station 1 102 instead of a repeater, the base station received signal may be used. A network-based approach can be used to perform relatively accurate location detection.

Meanwhile, since the terminal 2 110 is located in the open area, the terminal 2 110 may detect a location using a handset based method using a GPS signal, similar to the terminal 1 100. However, since the terminal 2 110 receives the service using the repeater 112 through the base station 2 114, there is a problem in that accurate position measurement is difficult to be made when using the network-based method of detecting the position based on the base station. This is because the mobile communication system does not recognize that the terminal 2 110 receives a signal through the repeater 112.

That is, the terminal 2 (110) receiving service using the repeater is incorrectly measured because the position of the terminal is transmitted to the cell ID (Cell ID) of the base station 2 (114), and is transmitted through the repeater 112 Problems related to engineering and operation, such as statistics of the call is incorrectly delivered. In addition, a special type of identifier is introduced to measure the location of the terminal, and basically, a cell is classified into a pseudorandom noise code in the case of CDMA. However, since the repeater uses the same pseudo noise code as the base station, it is difficult to distinguish between the signal at the repeater and the signal at the base station. Therefore, when receiving a service through the repeater 112, such as the terminal 2 (110), it is possible to detect which base station is located in the subscriber, but there is a problem that it is difficult to detect where in the base station. Therefore, the above-described network-based schemes can be used only as a useful method when configured in an environment of a base station, and in an environment where there are many repeaters as in the present, if the repeater is not considered, a lot of errors are caused in position detection. In particular, when the optical repeater is configured, there is a problem that the delay propagation time of the optical fiber is longer than the propagation time in the air and there is no way to recognize that the signal is received by the optical repeater.

On the other hand, since the terminal 3 (130) is indoors, i.e., in an in-building environment, it is difficult to receive GPS radio waves, and thus, the terminal 3 (130) has a problem in that location detection cannot be performed using a handset-based method. Therefore, the location of the terminal should be measured by network-based positioning. In this case, only the cell ID of the base station 4 132 can be used for location detection, and actual location detection such as division of each floor is not possible. There is a problem that it is difficult to accurately locate the terminal in the building.

In order to solve the above problems, the present invention provides a wireless communication signal path via a passive divider, a bidirectional amplifier, and a repeater between the base station and the terminal to determine the position of the terminal located in the coverage of the bidirectional amplifier or repeater. It is an object of the present invention to provide a method and system for providing a service for more accurately detecting a location of a terminal by dividing cells by artificially applying a frequency offset, using the applied frequency offset as a cell identifier such as coverage of a repeater. do.

According to a first object of the present invention, in a mobile communication system, a mobile communication using a forward frequency offset for detecting a position of the mobile communication terminal by giving a frequency offset to a forward signal transmitted in a forward path from a base station to a mobile communication terminal side. A method of providing a location detection service of a terminal, the method comprising: (a) generating an offset application signal by applying the frequency offset to the forward signal, and transmitting the offset application signal to the mobile communication terminal; (b) transmitting a modulated signal modulated in synchronization with the offset applying signal to the base station; (c) extracting the frequency offset from the modulated signal and generating position information including the frequency offset; And (d) the location information is transmitted to a location determination server, and calculating the location of the mobile communication terminal using the location information. Provide a method of providing.

According to a second object of the present invention, a mobile communication terminal using a reverse frequency offset for detecting a position of the mobile communication terminal by giving a frequency offset to a reverse signal transmitted in a reverse path from a mobile communication terminal to a base station in a mobile communication system A method of providing a location detection service of a method, the method comprising: (a) generating an offset application signal by applying the frequency offset to the reverse signal, and transmitting the offset application signal to the base station; (b) extracting the frequency offset from the offset application signal and generating position information including the frequency offset; And (c) the location information is transmitted to a location determination server, and calculating the location of the mobile communication terminal using the location information. Provide a method of providing.

According to a third object of the present invention, in a mobile communication system of an in-building environment, which is an indoor space including a plurality of remotes directly connected to a mobile communication terminal, a frequency offset is applied to a forward signal transmitted by a forward path from a base station to a mobile communication terminal. In the position detection service providing system of a mobile communication terminal using a forward frequency offset to detect the position of the mobile communication terminal by providing a signal, and receives the signal transmitted from the base station to branch the signal into a plurality of distribution signals and then the distribution A divider for distributing the signal into one or more paths; A frequency offset generator which receives the divided signal and gives the frequency offset to the divided signal to generate an offset application signal; A base station configured to receive a modulated signal modulated in synchronization with the offset application signal from the mobile communication terminal, extract the frequency offset, and generate position information including the frequency offset; And a location determination server for receiving and using the location information to calculate the location of the mobile communication terminal. 6. The location detection service of the mobile communication terminal using forward frequency offset in a mobile communication system of an in-building environment. Provides a system to

According to a fourth object of the present invention, in a mobile communication system of an in-building environment, which is an indoor space including a plurality of remotes directly connected to a mobile communication terminal, a frequency offset is applied to a reverse signal transmitted in a reverse path from a mobile communication terminal to a base station. In the position detection service providing system of a mobile communication terminal using a reverse frequency offset to detect the position of the mobile communication terminal by providing a, the offset application signal by applying the frequency offset to the path signal of the remote received from the mobile communication terminal Frequency offset generator for generating a; A base station receiving the offset application signal to extract the frequency offset and to generate location information including the frequency offset; And a location determination server configured to receive and use the location information to calculate the location of the mobile communication terminal in a mobile communication system of an in-building environment. Provides a system to

According to a fifth object of the present invention, in a mobile communication system in a repeater environment for extracting and amplifying a signal transmitted from a base station when the mobile communication terminal is located in a shadowed area, it is transmitted in a forward path from the base station to the mobile communication terminal side. A system for providing a location detection service for a mobile communication terminal using a forward frequency offset for detecting a position of the mobile communication terminal by giving a frequency offset to a forward signal, the system comprising receiving a signal transmitted from a base station and converting the signal into a plurality of distributed signals. A splitter for splitting the split signal into one or more paths after branching; A repeater including a frequency offset generator for receiving the divided signal and giving the frequency offset to the divided signal to generate an offset application signal; A base station configured to receive a modulated signal modulated in synchronization with the offset application signal from the mobile communication terminal, extract the frequency offset, and generate position information including the frequency offset; And a location determination server for receiving and using the location information to calculate the location of the mobile communication terminal, wherein the location determination service of the mobile communication terminal using forward frequency offset is provided in a mobile communication system in a repeater environment. Provide a system.

According to a sixth object of the present invention, in a mobile communication system in a repeater environment for extracting and amplifying a signal transmitted from a base station when the mobile communication terminal is located in a shadowed area, the mobile communication terminal is transmitted in a reverse path from the mobile communication terminal to the base station. In the position detection service providing system of a mobile communication terminal using a reverse frequency offset to give a frequency offset to the reverse signal to detect the position of the mobile communication terminal, the frequency offset to the path signal of the remote received from the mobile communication terminal A repeater including a frequency offset generator for applying an offset to generate a signal; A base station receiving the offset application signal to extract the frequency offset and to generate location information including the frequency offset; And a location determination server for receiving and using the location information to calculate the location of the mobile communication terminal. The mobile terminal of the repeater environment provides a location detection service of a mobile communication terminal using a reverse frequency offset. Provide a system.

According to a seventh object of the present invention, a frequency offset generator for detecting a position of the mobile communication terminal by giving a frequency offset to a signal transmitted and received in a mobile communication system, the oscillator for generating a reference frequency; A direct digital synthesizer for generating an offset application reference frequency from the reference frequency; And a local oscillator for performing the uplink or downlink frequency conversion on the reference frequency and the offset application reference frequency to provide the frequency offset.

According to an eighth object of the present invention, a frequency offset is detected in a mobile communication system by detecting a position of the mobile communication terminal by giving a frequency offset to a signal transmitted / received in a mobile communication system, and generating a reference frequency using only one local oscillator. Letting oscillator; A direct digital synthesizer which generates an offset-applied reference frequency from the reference frequency to perform an upward or downward frequency conversion to provide the frequency offset; And a local oscillator for performing the uplink or downlink frequency conversion to the reference frequency to provide the frequency offset.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In a digital communication system, frequency (carrier) synchronization is required, in which a transmitter modulates information and a receiver demodulates a signal transmitted to a carrier. The subscriber receiver performs synchronization between the localized carrier and the carrier used in the base station, demodulates the received signal, modulates the transmission signal of the terminal, and transmits it. In order to reduce the frequency error, the frequency synchronization loop is operated at the subscriber station. On the other hand, the receiving end of the base station receives a terminal transmission signal synchronized with the transmission carrier of the base station. This transmission signal is used for synchronization with the carrier used at the base station and also used to demodulate the signal.

When a signal is transmitted and received between the base station and the terminal, a frequency error may occur due to the effects of fading such as the characteristics of the transceiver and the mobility of the terminal on the transmission and reception path. The frequency error is mainly caused by the error in the local clock generator of the subscriber unit and the frequency Doppler caused by the movement of the subscriber. In the present invention, a frequency offset is defined as an artificially generated value using a device capable of arbitrarily adjusting a frequency offset value among the frequency error values. In the present invention, the frequency offset is used as an identifier for distinguishing a subscriber's location.

When the frequency offset is generated in the forward direction, the terminal synchronizes with the signal to which the frequency offset is applied to the signal transmitted from the base station, modulates the signal, and transmits the signal to the base station. At this time, the base station operates a synchronization loop to synchronize the received signal with the signal of the base station, and uses the frequency offset applied in the forward direction as an identifier of the cell where the terminal is located.

When a frequency offset is generated in the reverse direction, the terminal synchronizes with the signal of the base station, modulates the signal, and transmits the signal to the base station. When the frequency offset is applied to the reception path of the base station, the transmission signal of the terminal is transmitted to the base station by applying the frequency offset. The base station operates a synchronization loop to synchronize the received signal with the signal of the base station, and uses the frequency offset applied in the reverse direction as an identifier of the cell where the terminal is located.

2 is a block diagram illustrating a system for providing a location detection service using a frequency offset according to a preferred embodiment of the present invention.

As shown in FIG. 2, the system for providing a location detection service using frequency offset according to an exemplary embodiment of the present invention includes a mobile communication terminal 200, a frequency offset generating device 202, a distributor 204, and a mobile communication network 206. And location detection server 214.

The mobile communication terminal 200 according to the preferred embodiment of the present invention performs frequency synchronization to match the frequency offset generated from the frequency offset generator 202.

On the other hand, such location search for the terminal may be performed when the user of the mobile communication terminal 200 requests the location-based service or when there is a request of the mobile communication network 206 to provide the location-based service. It may also be performed periodically according to a predetermined period (tracking service or the like) set in advance.

On the other hand, the mobile communication terminal 200 according to a preferred embodiment of the present invention is a PDA (Personal Digital Assistant), cellular (Cellular) phone, PCS (Personal Communication Service) phone, Hand-Held PC (Hand-Held PC), GSM ( Global System for Mobile (WD) phone, Wideband CDMA (W-CDMA) phone, EV-DO phone, EV-DV (Data and Voice) phone and MBS (Mobile Broadband System) phone may include. It may also include a wireless local loop (WLL), a phone of a digital trunked radio system (TRS), or the like. Here, MBS phone refers to a mobile phone to be used in the fourth generation system currently being discussed.

Frequency offset generator 202 according to a preferred embodiment of the present invention receives a signal from the distributor 204 to generate a frequency offset to each signal transmitted to the mobile communication terminal 200, or the mobile communication terminal 200 The signal is received from the remote controller and generates a frequency offset in the signal transmitted from each remote and transmits to the divider (or combiner) 204. Frequency offset generator 202 according to a preferred embodiment of the present invention is a device that can distinguish the mobile communication terminal 200 in the remote area of each repeater system by giving a frequency offset in the signal transmission and reception path, frequency offset A detailed internal configuration of the generator 202 will be described later in detail.

The divider (or combiner) 204 according to the preferred embodiment of the present invention is a device for dividing the same signal into several paths, and by connecting the aforementioned frequency offset generator 202 to the part going to each path, The path signal to the mobile communication terminal 200 in the remote area is divided and transmitted using the frequency offset.

The mobile communication network 206 according to the preferred embodiment of the present invention is a ground infrastructure that allows data to be exchanged with the mobile communication terminal 200 through an air interface so that the mobile communication terminal 200 can communicate while moving. Functions such as handoff and radio resource management. Mobile communication network 206 comprises a base station 208, a base station controller 210, and a mobile switching center 212. The mobile communication network 206 in the preferred embodiment of the present invention receives a signal including the frequency offset from the mobile communication terminal 200 and transmits the location information including the frequency offset information to the location detection server 214.

The base station 208 is a network endpoint device that directly interworks with the mobile communication terminal 200 by performing baseband signal processing, wired / wireless conversion, and transmission and reception of wireless signals. The base station 208 transmits parameter information capable of measuring frequency offset information to the location detection server 214 via the base station controller 210 and the mobile switching center 212 for the location detection service.

The base station controller 210 controls the base station 208, assigns and releases radio channels to the mobile communication terminal 200, controls transmission output of the mobile communication terminal 200 and the base station 208, and soft handoff between cells. It performs handoff and hard handoff determination, transcoding and vocoding, global positioning system (GPS) clock distribution, and operation and maintenance of the base station 208.

The mobile switching center 212 performs a switching function for the call request of the mobile communication terminal 200 and a control function to enable the mobile communication network to operate efficiently. That is, basic and additional service processing of the mobile communication terminal 200, incoming and outgoing call processing of the subscriber, location registration and handoff procedure processing, interworking with other networks, and the like. The mobile switching center 212 of the IS-95 A / B / C system includes an Access Switching Subsystem (ASS) that performs distributed call processing, an Interconnection Network Subsystem (INS) that performs centralized call processing, operation and maintenance. It includes a subsystem such as a Central Control Subsystem (CCS) that is in charge of the centralization function, and a Location Registration Subsystem (LRS) that performs storage and management of information on mobile subscribers. In addition, the mobile switching center 212 for 3rd and 4th generation may include an Asynchronous Transfer Mode (ATM) switch (not shown), which increases the transmission rate and the efficiency of line use by packet transmission per cell. . The mobile switching center 212 according to the preferred embodiment of the present invention performs a function of transmitting the location information including the frequency offset information transmitted via the base station 208 and the base station controller 210 to the location detection server 214. .

The location detection server 214 according to a preferred embodiment of the present invention receives the location information including the frequency offset information of the subscriber from the mobile communication network 206 to determine whether the subscriber is located in the base station environment or the repeater environment (manual divider, It is responsible for determining the location of optical repeater, RF repeater, multidrop optical repeater, variable repeater, microwave repeater, digital optical repeater, distributed antenna system or in-building distributed antenna system). To this end, the position detection server 214 according to the preferred embodiment of the present invention has additional information such as remote information of each repeater system and a table of frequency offsets or signal transmission / reception time delay information.

In addition, the location detection server 214 according to a preferred embodiment of the present invention may provide location information including the frequency offset information of the subscriber to the mobile communication terminal 200. Such location information is provided in the assisted-global positioning system (A-GPS) together with data of observable satellite information in a corresponding area to more accurately detect the location of the terminal.

Meanwhile, the location detection service according to the preferred embodiment of the present invention may include a mobile payment service, a location-based billing service, an emergency rescue service, an advertisement, a push type advertisement, a traffic information providing service, and / or a logistics service. have.

3 is a block diagram schematically illustrating a system for position detection using a divider and a frequency offset device in an inbuilding environment according to a preferred embodiment of the present invention.

The system of Figure 3 is applicable to either forward and / or reverse path. In addition, both the distributor 300 and the mobile communication terminal in each remote 308, 310, 312 area of the in-building system may be connected to a radio frequency cable and an optical cable. In addition, the distributor 300 according to the preferred embodiment of the present invention may be a structure of a donor of each in-building distributed antenna system or a general signal distributor.

In the forward direction, the divider 300 distributes the same signal in multiple paths. In a preferred embodiment of the present invention, the frequency offset generators 302, 304, and 306 are connected to each distributed path, so that each remote ( Signals transmitted to the mobile communication terminals in the areas 308, 310, and 312 are separately transmitted after applying the frequency offset. This enables the detection of the subscriber of the mobile communication terminal in each remote 308, 310, 312 area of the in-building system, which is conventionally recognized as being in the same cell, as being in that specific area within the same cell, thereby providing precision in position detection. To increase.

In the reverse direction, the frequency offset generators 302, 304, and 306 are placed in the path of the signal input from the mobile communication terminal in each remote 308, 310, and 312 area of the inbuilding system as opposed to the forward direction. In the same way, the frequency offset can be used to distinguish the signals. That is, the frequency offset generators 302, 304, and 306 are placed on one path in the forward or reverse direction to generate a frequency offset, thereby distinguishing the mobile communication terminals in each remote 308, 310, and 312 area of the in-building system. To make it possible. On the other hand, according to the front-rear relationship between the distributor 300 and the frequency offset generators 302, 304, and 306, the entire repeater may be divided, or the entire repeater winding may be divided into one coverage area.

FIG. 4 is a block diagram schematically illustrating a system for detecting a location by using a divider and a frequency offset device in multiple stages in an in-building environment according to a preferred embodiment of the present invention.

In the structure of the in-building, when the distributors 400, 410, and 420 and the frequency offset generators 411, 412, 413, 421, 422, and 423 are connected in multiple stages, the frequency offset generators 411, 412, 413, 421, 422 and 423 should be installed at the end 410 and 420 connected to the mobile communication terminal in each remote 414, 415, 416, 424, 425 and 426 area of the inbuilding system. If not, it is because it prevents accurate position measurement by considering the installed next stage as the same cell, not the division of the final mobile communication terminal stage in each remote 414, 415, 416, 424, 425, 426 area of the inbuilding system. For example, if the frequency offset generator is installed in the 400 to 420 stage and is not installed in the following stage, the 420 or lower stage is divided into one cell.

5 is a block diagram illustrating a configuration of a repeater including a frequency offset generator according to a preferred embodiment of the present invention.

The form of detecting the position of the mobile communication terminal using the frequency offset generator described in FIGS. 3 and 4 can be applied to a system using an RF repeater, an optical repeater, and the like.

In other words, in case of optical repeater, it can be applied in the same way as in-building environment, but if multiple multidrop optical repeaters are connected to one optical line, which is only multidrop, frequency offset to remote of the corresponding multidrop optical repeater It should be installed to give

In addition, in the case of the RF repeater, it is recognized that the signal transmitted from the distributor, etc. are propagated in the air, and the frequency offset generating method according to the preferred embodiment of the present invention can be applied by using the frequency offset generating device inside the RF repeater. . In this case as well, it is applicable to either forward and / or reverse paths. In addition, in the case of the repeater already installed, the frequency offset generator may be installed and operated independently of the repeater in the wireless communication signal path.

As shown in FIG. 5, the transmit signal received at the receive antenna 500 of the forward link is sent to a forward low noise amplifier (LNA) 504 via a receive duplexer 502. The forward low noise amplifier 504 sends a transmission signal to the frequency offset generator 506 to generate a frequency offset. The transmission signal having the frequency offset is sent to a drive amplifier (DA) 508 having a drive amplification function and a gain function, amplified by a high power amplifier (HPA) 510, and then a transmission duplexer 512. Amplified and radiated through the transmitting antenna 514 via the. In the reverse case, a frequency offset generator 518 may be inserted between the reverse low noise amplifier 516 and the driving amplifier 520 to achieve the same effect. However, the insertion position is not limited thereto, and may be inserted between the high output amplifiers 510 and 522 and the driving amplifiers 508 and 520, and may be inserted between the duplexers 502 and 512 and the high output amplifiers 510 and 522. have.

6A is a block diagram showing an internal configuration of a frequency offset generating device according to a first embodiment of the present invention.

As shown in FIG. 6A, the frequency offset generator 600 for generating a frequency offset includes a down converter 605 and an up converter 607, and a local oscillator (LO) 604 and 606. Will be used. The separate switch device 609 located at the input unit and the output unit is for switching the frequency offset generating block to minimize service failure. That is, when a problem occurs in the frequency offset generating block and the proper frequency offset is not applied to the signal, the switch device 609 is turned off (path is switched) so that the signal is output without passing through the frequency offset generating block. Be sure to In this way, the repeater is indistinguishable, but service reliability can be improved by not affecting service provision.

The two local oscillators 604, 606 must use the same reference frequency. If the same reference frequency is not used, the frequency error caused by the difference of the reference frequency rather than the randomly generated frequency offset will affect the frequency stability and affect the call quality of the system. To this end, a reference frequency for generating only a frequency offset is generally generated by using a temperature compensated X-tal oscillator (TCXO) 602 or the like. A frequency such as 10 MHz may be input and used.

In this way, the frequencies of the local oscillators 604 and 606 that are initially set become the same value. If the same value is set and input, the offset error of the frequency of the output signal is zero. In order to give an offset error of the output frequency, an offset is given to the frequency of one local oscillator of two local oscillators 604 and 606. Here, the reference frequency is used to give the frequency offsets of the local oscillators 604 and 606 to tens of Hz or hundreds of Hz. However, if the reference frequency is set in each of the two local oscillators 604 and 606, two reference frequencies exist, which causes the quality of the system such as synchronization. Therefore, the preferred embodiment of the present invention uses a Direct Digital Synthesizer (DDS) 608 to prevent this. That is, a new reference frequency is directly generated by the digital synthesizer 608 using the reference frequency generated by the temperature compensated crystal oscillator 602. In the direct digital synthesizer 608, the frequency control is precise, so that the frequency offset of the local oscillator 606 can be adjusted to the desired amount (possibly up to several Hz units or less).

Meanwhile, the frequency offset values set by the local oscillators 604 and 606 are used as values for confirming the frequency synchronization error distribution of the corresponding terminal. The distribution of the frequency synchronization error is different depending on the speed and the moving direction of the moving object and is distributed based on the frequency offset. The frequency offset value set in consideration of Doppler frequency values according to the speed of the moving object can be changed in steps of about tens to hundreds of Hz. Therefore, a small offset interval generated by the local oscillators 604 and 606 does not significantly affect actual performance. In addition, since an environment such as in-building has low mobility, a large number of cells can be distinguished when the interval of the frequency offset to distinguish is small. If the interval of setting the frequency offset is large, it is possible to introduce a restriction in classifying cells according to the mobility of the moving object. The relationship between the frequency offset and the Doppler transition will be described with reference to FIG. 7.

Device having a device structure of Figure 6A for generating a frequency error in addition to, if not the same structure as that of Figure 6A, so many that may be, is a F _r frequency is input F _r + f _0, F _r + 2f _0, F _r Generating and outputting a frequency offset such as -f ₀ or F _r -2f ₀ may be a preferred embodiment of the present invention. For example, there may be a device that provides a frequency offset using a reference frequency and a power control temperature compensated crystal oscillator (Voltage Control TCXO) together. Any frequency offset generated by these various devices may be used for detecting the location of the subscriber, which may be a preferred embodiment of the present invention.

6B is a block diagram showing an internal configuration of a frequency offset generator according to a second preferred embodiment of the present invention.

The frequency offset generator 610 of FIG. 6B is modified from the frequency offset generator of FIG. 6A. As shown in FIG. 6B, the frequency offset generator 610 for generating a frequency offset includes a down converter 615 and an up converter 617, and includes a local oscillator 614 and a direct digital synthesizer 616. Will be used. This has the advantage that it is simpler to apply than using two local oscillators 604 and 606 in FIG. 6A. The frequency offset generator 610 of FIG. 6B has a disadvantage in that the range of frequencies that can be directly synthesized by the digital synthesizer 616 is limited. However, since the frequency offset generator 610 does not affect the up-conversion and down-conversion, the configuration of the equipment is not limited.

Meanwhile, as described in FIG. 6A, the same reference frequency generated in the temperature compensated crystal oscillator 612 should be applied to the local oscillator 614 and the direct digital synthesizer 616. In addition, even if the positions of the local oscillator 614 and the direct digital synthesizer 616 used for up-conversion and down-conversion are changed, they may have the same function.

7 is a graph illustrating a relationship between frequency offset and Doppler transition.

As shown in FIG. 7, f ₀ represents the step of frequency offset and F _d represents the Doppler frequency domain. In FIG. 7, it is shown that the subscriber position in the cell can be detected by the frequency offset and the step unit of the frequency domain by the Doppler. At this time, since the Doppler frequency F _d is different depending on the speed of the moving body, the maximum speed of the moving body should be taken into account in the actual environment, and accordingly, a step of f ₀ is required to distinguish each cell. Otherwise, the cell discrimination error appears due to the Doppler transition due to the speed of the maximum moving body.

In addition, since the value for the actual frequency offset is obtained with polarity, the cell step may be divided according to + and − accordingly. The step of frequency offset can be applied differently according to mobility. For example, a small value is applied in the case of in-building which has low mobility, and a large value is applied in the road situation where the mobility is large.

On the other hand, in consideration of the performance of the reception block against the frequency offset, the maximum possible frequency offset value should be set in advance to minimize the influence on the performance such as the quality. Considering the Doppler frequency, if the maximum configurable frequency offset value is nf ₀ , the number of repeaters of a single cell (or sector) that can be distinguished only by the frequency offset is 2n + 1.

8A and 8B illustrate the form of location information including frequency offset information according to a preferred embodiment of the present invention.

Location information including frequency offset information according to a preferred embodiment of the present invention may have a form based on the frequency offset as shown in Figure 8A, or may have a form based on each remote of each repeater system as shown in Figure 8B have.

The base station information may be an ID of the base station, pseudo noise code information, and / or GPS location information, and may include corresponding sector information.The location information of each remote of each repeater system may be GPS information of each remote of the repeater system. If, in the case of inbuilding may include GPS information of the building. In addition, the time delay information refers to a transmission delay time of each remote of each repeater system, and detailed building information includes the corresponding floor or the location of the corresponding floor in the case of inbuilding.

On the other hand, at the time of position detection according to a preferred embodiment of the present invention, not only the information as shown in Figs. 8A and 8B for each call or each terminal, but also quality information about the call, for example, call drop information. , Type of service, quality of service (QoS) value, and the like may be transmitted along with location information.

FIG. 9A is a diagram illustrating a case where a multi-frequency offset component is generated in a base station and a repeater region when detecting a position according to an exemplary embodiment of the present invention.

As shown in FIG. 9A, when the areas of the base station 900 and the repeater 902 coexist, there may be a limitation in applying cell division due to the aforementioned frequency offset. This corresponds to both the forward and reverse directions, but there is a difference in the manner in which the modems of the terminal and the base station operate with respect to the frequency offset according to the forward and reverse directions.

Here, the repeater refers to an optical repeater, an RF repeater, a multidrop optical repeater, a wave repeater, a microwave repeater, a digital optical repeater, a distributed antenna system, an in-building distributed antenna system, and a subway distributed antenna system. In distributed antenna systems, both optical and RF distributed systems can be applied. In addition, the part referred to as a repeater may be a single system or, in the case of a distributed system, may be a final RF part.

First, when the frequency offset is applied in the forward direction, the application of the offset is limited according to the frequency synchronization method of the terminal. When only a single signal is applied, the terminal adjusts frequency synchronization to the signal transformed by the forward frequency offset, and the base station receives the transmission signal of the terminal in a form misaligned by the frequency offset error applied in the forward direction. That is, the terminal 1 904 is a terminal that receives only the base station 900 signal, and the frequency offset is distributed around 0 Hz in synchronization with the base station 900. Here, the frequency offset error due to Doppler or the like has a probabilistic distribution. Meanwhile, the terminal 2 906 receives a signal through the repeater 902. If a predetermined frequency offset, e.g., nfo is set in the forward direction as the separator of the cell in the repeater 902, the signal received by the terminal 2 906 through the repeater 902 will have a frequency offset distribution of nfo. Location detection can be performed in a manner.

Even if the multipath is received, the terminal receiving only the signal having the same frequency offset component among the signals of the multipath performs the above operation and can easily locate the terminal. However, a terminal receiving a signal having a different frequency offset among multipath signals may have a location detection result depending on which frequency offset is used as a cell identifier.

In the case of the terminal 3 908, that is, the terminal is located in the overlapping area 910 of the base station 900 and the repeater 902, there is a limit in applying the frequency offset as the identifier of the cell according to the frequency synchronization scheme. . That is, the terminal 3 908 receives both the signal of the base station 900 and the forward signal of the repeater 902 in which the frequency offset is set. The terminal 3 908 performs frequency synchronization. The synchronization may be synchronized by using a frequency offset used as a cell identifier as an average value of frequency offsets of two signals, or may be synchronized by a frequency offset of a maximum signal magnitude.

When a signal having a different frequency offset is input, each finger of the terminal operates in synchronization with the corresponding signal component. However, when the terminal transmits the reverse signal toward the base station or the repeater, the reference frequency should be set to synchronize with the base station signal. At this time, the reference frequency is adjusted with a temperature compensated crystal oscillator based on the value of the frequency offset of each finger. According to a preferred embodiment of the present invention, the reference value of the frequency offset is defined as the average value of the frequency offset of each finger at present. That is, in the case of the terminal 3 908, the reference frequency offset becomes (0 + nfo) / 2 since the reference value is the average value of the frequency offsets of the base station 900 signal and the repeater 902 signal. Here, the average value may be an average value of two values or a weighted average value. Since this is a difference according to the implementation method, the method of classifying the location of the terminal using the provided value does not depart from the scope of the present invention.

FIG. 9B is a diagram illustrating a case where a multi-frequency offset component occurs in a plurality of repeater regions during position detection according to a preferred embodiment of the present invention.

As in the method of determining the frequency offset in FIG. 9A, since the terminal 1 920 receives only the signal of the repeater 1 912, the frequency offset is synchronized with the signal to which the forward frequency offset is applied to the signal transmitted from the repeater 1 912. This is determined. In addition, in the case of the terminal 2 922, the reference frequency offset is an average value of the frequency offsets of the repeater 1 912 signal to which the forward frequency offset is applied and the repeater 2 914 signal to which the forward frequency offset is applied, and the terminal 3 (924). ), The reference frequency offset is the average of the frequency offsets of repeater 1 (912) signal with forward frequency offset, repeater 3 (916) signal with forward frequency offset, and repeater 4 (918) signal with forward frequency offset. do.

In case of applying the frequency offset in the reverse direction, the case is divided according to the operation of the frequency offset of the base station modem. There may be a case where the value of the frequency offset provided to the base station modem is the value of the actual frequency offset of each finger, and may also be the average value of the actual frequency offset of each finger.

Hereinafter, a case in which the frequency offset is applied in the reverse direction will be described with reference to FIG. 9B.

In each of the repeaters 912, 914, 916, and 918, the reverse frequency offset is set as the repeater cell division identifier. In the case of a single path as in the case of the terminal 1 920, only the signal of the repeater 1 912 is received, so that only the signal of the single frequency offset in the area is transmitted, so that the base station modem can easily detect the frequency offset.

However, in the case of the terminal 2 922 and the terminal 3 924 receiving signals from a plurality of repeaters, each base station modem detects several different frequency offsets. Fingers are assigned to the path. In the case of terminal 2 922, at least two fingers are assigned and these fingers have components of two different frequency offsets. In the case of terminal 3 924, at least three different fingers are assigned and this finger is assigned. Has components of three different frequency offsets. The base station modem receives signals having different components of the frequency offset, and operates a frequency synchronization routine for the frequency offset for each finger so that each finger can distinguish that the signal is input through each repeater.

In this case, the base station uses the frequency offset of the received signal of each finger, indicating that terminal 2 922 is located between repeater 1 912 and repeater 2 914, and terminal 3 924 repeats relay 1 ( 912, repeater 3 916, and repeater 4 918. At this time, if the signal strength and / or time delay information is provided together with the frequency offset, a more accurate position can be found. However, for this purpose, the location of each repeater, transmission time delay information from the base station to the repeater, and / or transmission time delay information of the repeater itself should be managed by a database.

Meanwhile, according to another embodiment of the present invention, the value of the frequency offset provided to the base station modem may be the average value of the actual frequency offset of each finger, not the value of the actual frequency offset of each finger. In this case as well, when a signal of a single frequency offset in each cell (base station or repeater) is received, the correct position is provided, but in the case of terminal 2 922 and terminal 3 924, the average value of the frequency offset error is provided. Therefore, the position may be provided in a form of overlapping regions of the repeater and the repeater corresponding to the frequency offset, or overlapping regions of the repeater and the base station.

FIG. 10 is a diagram for describing a method of setting a frequency offset and a frequency offset error in a repeater and the like according to a preferred embodiment of the present invention.

FIG. 10 illustrates the contents of FIG. 7 in more detail. In the frequency display part of FIG. 10, F means a reference RF frequency or a center frequency of a signal.

In order to distinguish a plurality of repeaters, a different frequency offset is set for each repeater and a frequency offset error is set differently. The value of the frequency offset error that can be set is a range in which frequency synchronization can be adjusted so that the base station modem can demodulate a signal. This is possible from -nfo Hz to + nfo Hz. The modems in current CDMA basestations are known to be capable of more than +/- 1.2 KHz (eg, Qualcomm CSM 5000 chips), and the actual implementation of modems is clearly beyond this range.

In FIG. 10, the distribution of the frequency offset errors in the base station region is represented by 1000 regions, and the region 1002 and region 1004 are error distributions due to the set frequency offsets of the repeaters. The distribution of frequency offset errors is in the format shown to refer to the frequency offset error guard band setting. The value of the frequency offset error measured at each frequency offset setting is changed by the Doppler effect. This value is represented by -fd Hz to + fd Hz depending on the angle between the subscriber and the base station (or repeater). In FIG. 10, the value of fd is indicated at 1008 and becomes the maximum Doppler frequency. Since the Doppler frequency varies depending on the frequency used, the maximum subscriber's moving speed according to the band used must be taken into account, which causes the value of fd to vary.

The equation for fd is shown in Equation 1.

fd = v / l cos q

Here, v is the moving speed of the terminal, l is the wavelength of the frequency, q is the angle between the terminal and the base station.

Considering this Doppler effect, the frequency offset error distribution of a cell of a base station or a cell of a repeater is changed. In particular, in the case of a repeater, the Doppler frequency due to the Doppler effect may vary depending on the position where the repeater is installed. For example, in the case of in-building with low mobility, the frequency offset error due to the Doppler effect is distributed small, whereas in the macro cell and micro cell shapes including the movement of the vehicle, the frequency offset error should be greatly distributed in consideration of mobility. will be. On the other hand, the 1006 region is a guard band for preventing a mistake in the cell due to the value of the frequency offset error, which is shown in more detail at 1010.

The value of the frequency offset error that is actually measured is not a fixed value but a value that represents a probability distribution. In an ideal case where there is no mobility at all, the frequency offset error will appear as 0 Hz for the base station, but it is rarely present in the real world. The distribution due to the frequency synchronization error probability of the actual terminal modem and the frequency synchronization error probability of the base station modem is represented, which is 1012.

If the frequency synchronization error probability distribution is fe based on each frequency offset, the value of the frequency offset error measured by the actual base station shows the distribution of nfo (+/-) fe around the value of each frequency offset. fe is defined as the maximum frequency synchronization error value that can be considered in consideration of fading environments, and the frequency of each repeater in consideration of the Doppler frequency and the maximum frequency synchronization error considering the maximum moving speed of the terminal to distinguish each frequency offset error. You can set the offset error. The guard band that must be set to distinguish frequency offset errors can be set to 2fe or more, which is twice the minimum frequency synchronization error value.

Doppler frequency can be set differently when the environment is different. Ie 1014, 1016 and 1018 need not all be the same. That is, 1014 is determined based on the maximum moving speed of the subscriber directly connected to the base station in consideration of the base station Doppler frequency, and 1016 and 1018 are applied in consideration of the Doppler frequency value of the repeater. That is, since the maximum Doppler frequency value will be different according to the installation environment of the repeater, for example, whether it is an outdoor repeater, an in-building system, or a subway system, it may be set according to each environment. Therefore, the frequency offset and the frequency offset error for each repeater can be set and used in a variable manner depending on the application situation, without setting a constant.

FIG. 11 is a diagram for describing frequency offset setting when a value of a frequency offset provided to a base station modem is an average value of actual frequency offsets of each finger according to a preferred embodiment of the present invention.

FIG. 11 illustrates a base station area, a repeater area, and an overlapping area of the base station and the repeater. When the value of the frequency offset provided to the base station modem according to the preferred embodiment of the present invention is an average value of actual frequency offsets of each finger, FIG. This graph shows the frequency offset setting. In FIG. 11, it is assumed that the Doppler frequency and the frequency synchronization error probability for setting the frequency offset of each repeater are the same.

In FIG. 11, the overlapping areas of the base station area 1100, the repeater 1 area 1102, the repeater 2 area 1104, and the repeater 3 area 1106 are indicated by 1110, 1112, 1114, 1116, and 1118. As shown in the graph of FIG. 11, when the value of the frequency offset provided to the base station modem is an average value of the multiple frequency offsets, the average frequency offset appearing in the overlapping area and the error thereof are considered when setting the frequency offset value in each repeater. Must be set. This is because the average value of the multiple frequency offsets, which are offset values of the overlapped regions, is also applied as a frequency offset value for distinguishing cells (overlapping regions).

The present invention is adapted to adjust the frequency synchronization by the correction by the frequency error of the base station and the mobile station on the basis of the base station signal in the mobile communication system, the present invention is applicable to any mobile communication system using the same. This is because, in order to communicate with each other in a synchronous or asynchronous mobile communication system, it is a general technique to adjust frequency synchronization by correcting an initial frequency error based on one place.

On the other hand, within the range of applicable frequency offset error, even if the present invention is applied does not affect the voice call and data transmission and reception quality of the existing system due to the arbitrarily set frequency offset. That is, it is not necessary to modify the basic hardware and software of the terminal and the base station used previously, but there may be a modification requesting the frequency offset information.

Meanwhile, the present invention can be used in all types of mobile communication systems, such as Code Division Multiple Access (CDMA), Global System for Mobile Communications (GSM), CDMA2000 1X, 3X, EV-DO, EV-DV, WideBand CDMA (WCDMA), It can be applied without limitation to methods such as Portable Internet (PI), Wireless Local Loop (WLL), and digital TRS (Trunked Radio System). This is because mobility considerations are applied in all systems in the mobile communication system. Since there may be a difference in the allowable range of the frequency offset for each system, there is a limit as much as the corresponding value. If the base station does not provide the information of the frequency offset, a device that can provide the information may be added. Can be. Therefore, when the existing system does not provide the information of the frequency offset smoothly, the form of adding a separate device for detecting the information of the frequency offset also does not depart from the scope of the present invention.

On the other hand, the present invention can be applied to all kinds of repeaters, for example distributed antenna system, optical repeater, RF repeater, multidrop optical repeater, wave repeater, microwave repeater or digital optical repeater. However, the most widely applied applications are optical repeaters or in-building distributed antenna systems. However, RF repeaters, etc. may be restricted depending on the number of uses, or laws and regulations that regulate radio waves.

In addition, according to a preferred embodiment of the present invention, it is possible to identify the incoming call through the repeater, it is possible to provide a method useful for cell engineering using repeater call characterization. In other words, by using the number of calls, call success rate, disconnection rate, access call failures, handoff failure rate, etc. introduced through the repeater, it is optimized for cell optimization and engineering by extending the cell engineering method provided only in the base station to the relay area. Can provide a solution.

The above description is merely illustrative of the present invention, and those skilled in the art to which the present invention pertains may various modifications without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed herein are not intended to limit the present invention but to describe the present invention, and the spirit and scope of the present invention are not limited by these embodiments. It is intended that the scope of the invention be interpreted by the following claims, and that all descriptions within the scope equivalent thereto shall be construed as being included in the scope of the present invention.

As described above, according to the present invention, it is possible to recognize a repeater in a cell and provide a method for identifying a location of each repeater or a mobile communication terminal in an in-building final remote area in an in-building environment. As the accuracy can be increased, various location-based services can be provided using the same. For example, it may be usefully applied to mobile payment services such as M-Commerce, location-based billing services, emergency rescue services, advertisements, push-type advertisements, traffic information provision services, and / or logistics services.

On the other hand, according to the present invention, since the position detection is possible to the repeater and the mobile communication terminal in each final remote area of the inbuilding, engineering and optimization using call statistics information (call origination, drop, call origination failure, etc.) for each The effect is that the work can be performed smoothly.

On the other hand, according to the present invention, within the range of applicable frequency offset error, even if the present invention is applied, the randomly set frequency offset does not affect the voice call and data transmission / reception quality of service of the existing system. That is, there is an advantage that the effective location detection can be performed without modifying the basic hardware and software of the terminal and base station used.

Claims (47)

In a mobile communication system, a method for providing a location detection service for a mobile communication terminal using a forward frequency offset for detecting a position of the mobile communication terminal by giving a frequency offset to a forward signal transmitted in a forward path from a base station to a mobile communication terminal. , (a) generating the offset applying signal by applying the frequency offset to the forward signal when the forward signal passes through the frequency offset generator installed in the forward path, and transmitting the offset applying signal to the mobile communication terminal. ; (b) transmitting a modulated signal modulated in synchronization with the offset applying signal to the base station; (c) extracting the frequency offset from the modulated signal and generating position information including the frequency offset; And (d) transmitting the location information to a location determination server and calculating the location of the mobile communication terminal using the location information; Method for providing a location detection service of a mobile communication terminal using a forward frequency offset, characterized in that it comprises a. The method of claim 1, The location detection of the mobile communication terminal is performed by dividing the terminal into the last stage of the mobile communication system, and the final stage is a portion which is directly connected to the mobile communication terminal as the lowest part of the mobile communication system. Method for providing a location detection service of a mobile communication terminal using an offset. The method of claim 1, The frequency offset generator is a method for providing a location detection service of a mobile communication terminal using a forward frequency offset, characterized in that installed in the repeater or in-building environment. The method of claim 3, wherein The subscriber location information of the mobile communication system using the frequency offset is used as call statistics information of the last remote that is directly connected to the mobile communication terminal as the lowest part of the mobile communication system in the repeater or the in-building environment. Method for providing a location detection service of a mobile communication terminal using a forward frequency offset. delete The method of claim 1, When the mobile communication terminal exists in an overlapping area of the base station or the plurality of repeaters and one or more signals transmitted from the base station have multiple frequency offsets, the mobile communication terminal performs frequency synchronization with an average value of the multiple frequency offsets. And transmitting the modulated signal to the base station by using a forward frequency offset. The method of claim 6, The location of the mobile communication terminal is determined by the overlapping area of the plurality of cells identified by the frequency offset, the method of providing a location detection service of the mobile communication terminal using a forward frequency offset. The method of claim 6, And said average value is recognized as a frequency offset of said overlapping region. The method of claim 1, The frequency offset may be set in consideration of the maximum moving speed of the mobile communication terminal subscriber in the cell, the maximum Doppler frequency, the maximum frequency synchronization error probability of the mobile communication terminal modem, and / or the installation situation of the base station or repeater. A method for providing location detection service of a mobile communication terminal using forward frequency offset. delete A method of providing a location detection service for a mobile communication terminal using a reverse frequency offset for detecting a position of the mobile communication terminal by giving a frequency offset to a reverse signal transmitted from a mobile communication terminal to a base station in a mobile communication system, (a) generating the offset applying signal by applying the frequency offset to the reverse signal when the reverse signal passes through the frequency offset generator installed on the reverse path, and transmitting the offset applying signal to the base station; (b) extracting the frequency offset from the offset application signal and generating position information including the frequency offset; And (c) transmitting the location information to a location determination server and calculating the location of the mobile communication terminal using the location information; Method for providing a location detection service of a mobile communication terminal using a reverse frequency offset comprising a. The method of claim 11, The location detection of the mobile communication terminal is performed by dividing the terminal into the last stage of the mobile communication system, and the final stage is the lowest frequency part of the mobile communication system, the reverse frequency offset characterized in that the portion directly connected to the mobile communication terminal Method of providing a location detection service of a mobile communication terminal using a. The method of claim 11, The frequency offset generator is located in a repeater or in-building environment location service providing method of a mobile communication terminal using a reverse frequency offset. The method of claim 13, The subscriber location information of the mobile communication system using the frequency offset is used as call statistics information of the last remote that is directly connected to the mobile communication terminal as the lowest part of the mobile communication system in the repeater or the in-building environment. Method of providing a location detection service of a mobile communication terminal using a reverse frequency offset. delete The method of claim 11, When the mobile communication terminal exists in an overlapping area of the base station or the plurality of repeaters, and one or more signals transmitted from the mobile communication terminal have multiple frequency offsets, the base station is frequency synchronized with an average value for the multiple frequency offsets. And detecting the position of the mobile communication terminal using the average value provided by operating a routine. The method of claim 16, And the average value is recognized as a frequency offset of the overlapping region. The method of claim 11, When the mobile communication terminal exists in an overlapping area of the base station or a plurality of repeaters and one or more signals transmitted from the mobile communication terminal have multiple frequency offsets, the base station performs a frequency synchronization routine with each of the multiple frequency offsets. And detecting the position of the mobile communication terminal by using the frequency offset value of each finger provided to operate. The method of claim 16 or 18, The location of the mobile communication terminal is determined by the overlapping area of the plurality of cells identified by the frequency offset, the method of providing a location detection service of the mobile communication terminal using a reverse frequency offset. The method of claim 11, Method for providing a location detection service of a mobile communication terminal using a reverse frequency offset, characterized in that the strength (Energy) and / or time delay information of the offset application signal is provided with the frequency offset. The method of claim 11, The frequency offset may be set in consideration of the maximum moving speed of the mobile communication terminal subscriber in the cell, the maximum Doppler frequency, the maximum frequency synchronization error probability of the mobile communication terminal modem, and / or the installation situation of the base station or repeater. A method for providing a location detection service of a mobile communication terminal using reverse frequency offset. delete In a mobile communication system of an in-building environment, which is an indoor space including a plurality of remotes directly connected to a mobile communication terminal, a frequency offset is given to a forward signal transmitted in a forward path from a base station to a mobile communication terminal to locate a location of the mobile communication terminal. In the system for providing a location detection service of a mobile communication terminal using a forward frequency offset for detecting a, A divider which receives a signal transmitted from a base station, divides the signal into a plurality of distributed signals, and distributes the distributed signals to one or more paths; A frequency offset generator which receives the divided signal and gives the frequency offset to the divided signal to generate an offset application signal; A base station configured to receive a modulated signal modulated in synchronization with the offset application signal from the mobile communication terminal, extract the frequency offset, and generate position information including the frequency offset; And A location determination server for receiving the location information and calculating a location of the mobile communication terminal using the location information; System for providing a location detection service of the mobile communication terminal using the forward frequency offset in the mobile communication system of the in-building environment comprising a. The method of claim 23, wherein Location detection service of the mobile communication terminal using the forward frequency offset in the mobile communication system of the in-building environment, characterized in that the location detection of the mobile communication terminal is divided by the remote end of the mobile communication system of the in-building environment System to provide. The method of claim 23, wherein The frequency offset may be set in consideration of the maximum moving speed of the mobile communication terminal subscriber in the cell, the maximum Doppler frequency, the maximum frequency synchronization error probability of the mobile communication terminal modem, and / or the installation situation of the base station or repeater. A system for providing a location detection service of a mobile communication terminal using a forward frequency offset in a mobile communication system in an in-building environment. delete In a mobile communication system of an in-building environment, which is an indoor space including a plurality of remotes directly connected to a mobile communication terminal, a frequency offset is given to a reverse signal transmitted in a reverse path from a mobile communication terminal to a base station, thereby positioning the mobile communication terminal. In the position detection service providing system of a mobile communication terminal using a reverse frequency offset for detecting the, A frequency offset generating device for generating an offset application signal by giving the frequency offset to the path signal of the remote received from a mobile communication terminal; A base station receiving the offset application signal to extract the frequency offset and to generate location information including the frequency offset; And A location determination server for receiving the location information and calculating a location of the mobile communication terminal using the location information; System for providing a location detection service of a mobile communication terminal using the reverse frequency offset in the mobile communication system of the in-building environment comprising a. The method of claim 27, The location detection of the mobile communication terminal is divided by the remote, which is the last end of the mobile communication system of the in-building environment, and the location detection service of the mobile communication terminal using the reverse frequency offset in the mobile communication system of the in-building environment. System to provide. The method of claim 27, The location of the mobile communication terminal using the reverse frequency offset in the mobile communication system of the in-building environment characterized in that the strength (Energy) and / or time delay information of the offset applied signal is provided with the frequency offset. system. The method of claim 27, The frequency offset may be set in consideration of the maximum moving speed of the mobile communication terminal subscriber in the cell, the maximum Doppler frequency, the maximum frequency synchronization error probability of the mobile communication terminal modem, and / or the installation situation of the base station or repeater. A system for providing a location detection service of a mobile communication terminal using a reverse frequency offset in a mobile communication system in an in-building environment. delete In a mobile communication system in a repeater environment for extracting and amplifying a signal transmitted from a base station when the mobile communication terminal is located in a shadowed area, a frequency offset is given to a forward signal transmitted in a forward path from the base station to the mobile communication terminal. A system for providing a location detection service for a mobile communication terminal using a forward frequency offset for detecting a location of the mobile communication terminal, A divider which receives a signal transmitted from a base station, divides the signal into a plurality of distributed signals, and distributes the distributed signals to one or more paths; A repeater including a frequency offset generator for receiving the divided signal and giving the frequency offset to the divided signal to generate an offset application signal; A base station configured to receive a modulated signal modulated in synchronization with the offset application signal from the mobile communication terminal, extract the frequency offset, and generate position information including the frequency offset; And A location determination server for receiving the location information and calculating a location of the mobile communication terminal using the location information; A system for providing a location detection service of a mobile communication terminal using a forward frequency offset in a mobile communication system of a repeater environment comprising a. The method of claim 32, When the mobile communication terminal exists in an overlapping area of the base station or the plurality of repeaters and one or more signals transmitted from the base station have multiple frequency offsets, the mobile communication terminal is frequency synchronized with an average value for the multiple frequency offsets. The system for providing a location detection service of a mobile communication terminal using a forward frequency offset in a mobile communication system of a repeater environment, characterized in that for transmitting the modulated signal to the base station. The method of claim 33, wherein The location of the mobile communication terminal is detected as the overlapping area of the plurality of cells identified by the frequency offset to provide a location detection service of the mobile communication terminal using the forward frequency offset in the mobile communication system of the repeater environment system. The method of claim 33, wherein And the average value is recognized as a frequency offset of the overlapped region. The system for providing a location detection service of a mobile communication terminal using a forward frequency offset in a mobile communication system of a repeater environment. The method of claim 32, The repeater is an optical repeater, RF repeater, multi-drop optical repeater, wave repeater, microwave repeater, or a digital optical repeater, characterized in that the position detection service of the mobile communication terminal using the forward frequency offset in the mobile communication system of the repeater environment System. In a mobile communication system in a repeater environment for extracting and amplifying a signal transmitted from a base station when the mobile communication terminal is located in a shadowed area, a frequency offset is given to a reverse signal transmitted in a reverse path from the mobile communication terminal to the base station. A system for providing a location detection service for a mobile communication terminal using a reverse frequency offset for detecting a location of the mobile communication terminal, A repeater including a frequency offset generator for generating an offset application signal by applying the frequency offset to the path signal of the remote terminal received from the mobile communication terminal; A base station receiving the offset application signal to extract the frequency offset and to generate location information including the frequency offset; And A location determination server for receiving the location information and calculating a location of the mobile communication terminal using the location information; System for providing a location detection service of a mobile communication terminal using a reverse frequency offset in a mobile communication system of a repeater environment comprising a. The method of claim 37, When the mobile communication terminal exists in an overlapping area of the base station or the plurality of repeaters, and one or more signals transmitted from the mobile communication terminal have multiple frequency offsets, the base station uses a frequency value as an average value for the multiple frequency offsets. A system for providing a location detection service of a mobile communication terminal using a reverse frequency offset in a mobile communication system in a repeater environment, wherein the location of the mobile communication terminal is detected using the average value provided by operating a synchronization routine. The method of claim 38, And the average value is recognized as a frequency offset of the overlapping region. The system for providing a location detection service of a mobile communication terminal using a reverse frequency offset in a mobile communication system in a repeater environment. The method of claim 37, When the mobile communication terminal exists in an overlapping area of the base station or a plurality of repeaters and one or more signals transmitted from the mobile communication terminal have multiple frequency offsets, the base station performs a frequency synchronization routine with each of the multiple frequency offsets. A system for providing a location detection service of a mobile communication terminal using a reverse frequency offset in a mobile communication system in a repeater environment using the frequency offset value of each finger provided to operate. . 41. The method of claim 38 or 40, The location of the mobile communication terminal is detected as the overlapping area of the plurality of cells identified by the frequency offset providing a location detection service of the mobile communication terminal using the reverse frequency offset in the mobile communication system of the repeater environment system. The method of claim 37, The repeater is an optical repeater, RF repeater, multi-drop optical repeater, wave repeater, microwave repeater, or a digital optical repeater, characterized in that for providing a location detection service of a mobile communication terminal using a reverse frequency offset in a mobile communication system in a repeater environment System. In the frequency offset generator for detecting the position of the mobile communication terminal by giving a frequency offset to the signal transmitted and received in a mobile communication system, An oscillator for generating a reference frequency; A direct digital synthesizer for generating an offset application reference frequency from the reference frequency; And Local oscillator for providing the frequency offset by performing an up or down frequency conversion to the reference frequency and the offset application reference frequency Frequency offset generating device comprising a. In the frequency offset generating device to detect the position of the mobile communication terminal by giving a frequency offset to the signal transmitted and received in a mobile communication system, using only one local oscillator, An oscillator for generating a reference frequency; A direct digital synthesizer which generates an offset-applied reference frequency from the reference frequency to perform an upward or downward frequency conversion to provide the frequency offset; And A local oscillator for converting the reference frequency up or down to provide the frequency offset Frequency offset generating device comprising a. The method of claim 43 or 44, The subscriber location information of the mobile communication system using the frequency offset is used as call statistics information of a final remote that is directly connected to the mobile communication terminal as the lowest part of the mobile communication system in a repeater and an in-building environment. Offset generator. The method of claim 43 or 44, The frequency offset generator is installed at the last end connected to the mobile communication terminal, the last end is a frequency offset, characterized in that the lowest part of the mobile communication system is directly connected to the mobile communication terminal Generating device. The method of claim 43 or 44, The frequency offset is set in consideration of the maximum moving speed of the mobile communication subscriber in the cell, the maximum Doppler frequency, the maximum frequency synchronization error probability of the mobile communication terminal modem, and / or the installation situation of the base station or repeater. Generating device.

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