KR20020093357A - Mobile communication network system having a gps signal repeater - Google Patents

Abstract

PURPOSE: A mobile communication system having a GPS signal repeater is provided to further include the GPS signal repeater installed between a doner antenna and a service antenna of a mobile communication signal repeater, thereby resolving a shade area of a GPS signal. CONSTITUTION: A GPS signal repeater(200) comprises as follows. A filter(201) outputs a GPS signal with a predetermined frequency band corresponding to a GPS signal received through a doner antenna(A1). A linear amplifier(203) shapes an output signal of the filter(201). An amplifier(205) amplifies an output signal of the linear amplifier(203), and transmits the amplified signal to a terminal(300) through a service antenna(A2). The GPS signal received through the doner antenna(A1) is transmitted to the filter(201). The filter(201) outputs the GPS signal with the predetermined frequency band. The GPS signal is transmitted to the linear amplifier(203). The linear amplifier(203) linearly amplifies the signal. The linearly amplified GPS signal is supplied to the amplifier(205).

Description

Mobile communication system with GPS signal repeater {MOBILE COMMUNICATION NETWORK SYSTEM HAVING A GPS SIGNAL REPEATER}

The present invention relates to a mobile communication system having a GPS signal repeater, and more particularly, to a mobile communication system having a GPS signal repeater for solving a shadow area of a GPS signal, which is a position signal provided from a GPS satellite.

The mobile communication network has a predetermined condition for providing an incoming call service to a terminal. For example, the location of the terminal is transmitted to the network according to the period, area, power ON / OFF, distance to the base station, and the like. Here, the transmitted location information is stored in the visited subscriber location registration device (VLR) and the subscriber registration device (HLR) in the exchange, and this location information is used for the incoming call processing service.

In order to provide the incoming call service, it is necessary to know which base station area the registered terminal is currently in, so that the terminal transmits the moved location information through the base station, and the location information is transmitted through a signal relay device (STP). It is delivered to the subscriber registration device (HLR).

In the mobile communication terminal as described above, location registration consists of area reference location registration and user area location registration. The area reference location registration is currently described in the IS-95 standard, and is a fixed area of a wireless network portion. If the area where the mobile station is located on the basis of the change is an algorithm for performing location registration.

In addition, user area location registration is described in the TIA / EIA / IS-730 standard, which is an international standard technology, and is an algorithm that performs location registration when a terminal wants to provide a service for classifying call rates by base stations with which communication is performed. In this case, a fixed area is defined and managed by grouping base stations or sectors. If a terminal registers a location in this zone, the terminal receives a separate charge unit for calls in the corresponding zone.

When the location of the called party is confirmed through the location registration process, the exchange requests the called party's call, and the caller's terminal number is displayed as a text message on the called party's terminal and a ringing tone sounds.

However, when the called terminal is in a subway or a high-rise building, a shaded area is generated which cannot receive a call request signal, and the mobile station 11 moves as shown in FIG. 1 to solve the shaded area of the mobile communication signal. After receiving and amplifying a communication signal, a mobile communication signal repeater 15 for transmitting to a called party terminal 17 having a shaded area is installed.

FIG. 2 is a diagram illustrating the configuration of the mobile communication signal repeater 15 of FIG. 1. Referring to this, the repeater 15 of the mobile communication signal will be described as follows.

In other words, a first duplexer 21 which multiplexes the mobile communication signal transmitted and received by the donor antenna A1, and a reception linear amplifier connected to an output side of the first duplexer 21 to shape the received mobile communication signal. (23), a frequency converter (25) connected to the output side of the receiver linear amplifier (23) to convert the transmitted and received mobile communication signal frequencies, and a frequency converter received mobile communication signal connected to the output side of the frequency converter for high output. Multiplexed a high power amplified mobile communication signal connected to an output side of the receiving high power amplifier 27 and the amplifying high power amplifier 27 to be amplified and transmitted to the receiver terminal 17 through a service antenna A2. A second duplexer 29 connected to an output side of A2) for receiving and multiplexing a mobile communication signal received through the service antenna A2; On the output side of the second duplexer 29, a transmission linear amplifier 31 for shaping a multiplexed mobile communication signal and transmitting a shaped mobile communication signal to the frequency converter 25, and an output side of the frequency converter 25 And a high power amplifier 33 which is connected to the high power amplification of the mobile communication signal which is frequency-converted and transmitted to the first duplexer 21.

The high power amplified mobile communication signal of the transmission high power amplifier 33 is multiplexed through the first duplexer 21 and then transmitted to the base station 11 through the donor antenna A1.

In the general mobile communication signal repeater provided as described above, first, the mobile communication signal received through the base station 11 is provided to the duplexer 21, and the duplexer 21 receiving the mobile communication signal receives the mobile communication signal. After multiplexing, the signal is provided to the receiving linear amplifier 23.

The receiving shaping amplifier 23 which has received this multiplexed mobile communication signal shapes this mobile communication signal, and this shaped mobile communication signal is supplied to the frequency converter 25. The frequency converter 25 is supplied from the outside. The frequency of this shaped mobile communication signal is converted through the supplied intermediate frequency, and this frequency converted mobile communication signal is high output amplified through the high output amplifier 27 and then supplied to the second duplexer 29.

The second duplexer 29 multiplexes the high power amplified mobile communication signal, which is transmitted to the called party terminal 17 via the service antenna A2.

On the other hand, recently, one of the methods of finding the location of the terminal is to use the GPS satellite, in this case it can find the position of the terminal more accurately.

There are a total of 24 GPS satellites, which orbit the earth every 12 hours with the same distribution of six orbits at an altitude of 20,000 Km with an inclination of 55 degrees to the equator. Therefore, the location of the terminal is observed through at least six satellites. At this time, the GPS signal transmitted from the satellite needs at least four satellites to calculate three-dimensional information and time of X, Y, and Z.

Here, the location information transmitted from the base station is transmitted and received at about 800 MHz, and the location information of the GPS signal transmitted from the GPS satellite is received at about 1575.42 MHz, so that each frequency band is set differently.

However, as described above, the repeater for eliminating the shadow area of the mobile communication signal is installed so that only a single frequency can be relayed, but it is impossible to relay a GPS signal having a different frequency band. Therefore, when the called terminal is located in a specific area such as a basement of a high-rise building, it cannot receive GPS signals, which causes a problem of shadowed GPS signals.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a mobile communication system having a GPS signal repeater for further improving the call quality and location-based service quality by eliminating the shadow area of the GPS signal It is in a ship.

Mobile communication system having a GPS signal repeater according to the present invention for achieving the above object,

A mobile communication network capable of receiving a GPS signal supplied from a GPS satellite and a mobile communication signal transmitted from a base station, a donor antenna, and a service antenna, and includes a mobile communication signal repeater for eliminating the shadow area of the mobile communication signal of the mobile communication network. In a system that

The GPS signal repeater is further provided between the donor antenna and the service antenna of the mobile communication signal repeater to eliminate the shadow area of the GPS signal.

Preferably, in the mobile communication system having a GPS signal repeater according to the first embodiment of the present invention, the GPS signal repeater,

A filter for filtering a GPS signal of a predetermined frequency band among the GPS signals received through the donor antenna;

A linear amplifier for shaping the output signal of the filter; And

And an amplifier for amplifying the output signal of the linear amplifier.

Mobile communication system having a GPS signal repeater according to a second embodiment of the present invention,

In a system having a dual band transmit and receive antennas, and having a mobile communication signal repeater capable of transmitting and receiving mobile communication signals through the dual band transmit and receive antennas,

Filters respectively connected between the dual band transmit / receive antennas to output mobile communication signals and GPS signals of frequency bands corresponding to mobile communication signals and GPS signals, and transmit the mobile communication signals to the mobile communication signal repeaters;

An amplifier receiving the GPS signal of the filter and amplifying the filter to a predetermined size; And

Receiving the output signal of the amplifier and the output signal of the mobile communication signal repeater, respectively, and outputting the output signal of the amplifier and the output signal of the mobile communication signal repeater in a frequency band corresponding to the output signal of the amplifier and the output signal of the mobile communication signal repeater It characterized in that it comprises a filter for transmitting to the terminal via the dual band transmission and reception antenna.

Mobile communication system having a GPS signal repeater according to a third embodiment of the present invention,

In a system having a GPS receiver antenna and a dual band transmission antenna, and having an optical repeater capable of receiving mobile communication signals and GPS signals of the mobile communication network,

A filter connected to an output side of the GPS receiver antenna and outputting a frequency band GPS signal corresponding to the GPS signal;

An amplifier receiving the GPS signal of the filter and amplifying the filter to a predetermined size; And

A filter for transmitting an output signal of the amplifier of the predetermined frequency band, which is filtered among the output signals of the output signal of the amplifier, to the terminal through the dual band receiving antenna;

An optical filter for outputting a mobile communication signal of a predetermined frequency band corresponding to an optical communication network from the mobile communication signal received through the dual band receiving antenna;

And an optical repeater for amplifying a mobile communication signal of the optical filter to a predetermined size and transmitting the optical communication signal through an optical cable.

According to the present invention, it is possible to further improve the location-based service quality by eliminating the GPS signal shadow area by further including the GPS signal repeater in the mobile communication signal repeater of the existing mobile communication system.

1 is a diagram illustrating a mobile communication signal repeater of a general mobile communication system.

2 is a diagram illustrating a configuration of a mobile communication signal repeater of FIG. 1.

3 is a diagram illustrating a GPS signal repeater of a mobile communication system to which the present invention is applied.

4 is a diagram showing the configuration of a GPS signal repeater according to a first embodiment of the present invention.

5 is a diagram illustrating a configuration of a GPS signal repeater according to a second exemplary embodiment of the present invention.

6 is a diagram illustrating a configuration of a GPS signal repeater according to a third exemplary embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: mobile communication signal repeater 200: GPS signal repeater

201, 501, 503, 507, 509, 701, 705: first to seventh filters

203: linear amplifiers 205, 505, 703: first to third amplifiers

300: terminal 707: optical filter

709: optical repeater 711: optical cable

A1: donor antenna A2: service antenna

A3, A4, A6: dual band transmitting and receiving antenna A5: GPS receiving antenna

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a diagram showing the configuration of a mobile communication system applied to the present invention. Referring to FIG. 3, in the mobile communication system to which the present invention is applied, the mobile communication system amplifies the forward mobile communication signal received through the donor antenna A1 to the service antenna A2 to solve the shadow area of the mobile communication signal of the base station. A mobile communication signal repeater 100 to be transmitted and a GPS signal repeater 200 to filter and amplify the GPS signal received through the donor antenna A1 and then transmit the amplified GPS signal to the service antenna A2.

4 is a diagram showing the configuration of the GPS signal repeater 103 of the mobile communication system according to the first embodiment of the present invention. Referring to FIG. 4, the GPS signal repeater 200 of the mobile communication system according to the first embodiment of the present invention filters a GPS signal of a predetermined frequency band corresponding to the GPS signal received through the donor antenna. 201, a linear amplifier 203 for shaping the output signal of the filter 201, and an amplifier for amplifying the output signal of the linear amplifier 203 and transmitting it to the terminal 300 through the service antenna A2. 205 is provided.

In the first embodiment of the present invention provided as described above, first, the GPS signal received through the donor antenna A1 of the mobile communication signal repeater 100 of the mobile communication system is transmitted to the filter 201, and the filter ( 201) outputs a GPS signal of the predetermined frequency band. The GPS signal of the predetermined frequency band is transmitted to the linear amplifier 203, and the linear amplifier 203 receiving the GPS signal amplifies linearly. The linearly amplified GPS signal is provided to the amplifier 205.

The amplifier 205 receiving the GPS signal is amplified to a predetermined size, and the GPS signal amplified to the predetermined size is transmitted to the terminal 300 through the service antenna A2.

That is, since the received GPS signal is relayed from the donor antenna and the service antenna of the mobile communication signal repeater, the quality of the location-based service is further improved.

On the other hand, Figure 5 is a diagram showing the configuration of the GPS signal repeater according to a second embodiment of the present invention. Referring to FIG. 5, the GPS signal repeater 500 of the mobile communication system according to the second embodiment of the present invention is connected to a dual band antenna A3 for receiving the GPS signal and the mobile communication signal, and performs the mobile communication signal and the GPS. Filters 501 and 503 for outputting a mobile communication signal and a GPS signal of a frequency band corresponding to the signal, respectively, and transmitting the mobile communication signal to the mobile communication signal repeater 100, and the GPS of the filter 503. An amplifier 505 that receives a signal and amplifies the signal to a predetermined size, receives an output signal of the amplifier 505 and an output signal of the mobile communication signal repeater, respectively, and outputs the signal and the mobile communication signal repeater 100 of the amplifier 505. The output signal of the amplifier and the output signals of the mobile communication signal repeater 100 in the frequency band corresponding to the output signal of the through the dual-band transmit and receive antenna (A4) Is provided with a filter 507, 509 to be transmitted to the end 300.

In the second embodiment of the present invention provided as described above, first, the forward mobile communication signal received through the dual band antenna A3 of the mobile communication signal repeater 100 is provided to the filter 501, and this filter 501 ) Outputs a forward mobile communication signal of a predetermined frequency band, and the forward mobile communication signal is provided to the mobile communication signal repeater 100.

The mobile communication signal repeater 100 high frequency amplifies the forward mobile communication signal after frequency conversion, and the high output amplified forward mobile communication signal is supplied to the filter 507, and the filter 507 is a high power amplified mobile communication. The mobile communication signal of a predetermined band is output from the signal, and the output mobile communication signal is transmitted to the terminal 300 through the dual band antenna A4.

The filter 507, which is received through the dual band antenna A4 and receives the reverse mobile communication signal provided from the terminal 300, outputs a reverse mobile communication signal of a predetermined frequency band, and reversely moves the predetermined frequency band. The communication signal is supplied to the mobile communication signal repeater 100.

The mobile communication signal repeater 100 high frequency amplifies the reverse mobile communication signal after frequency conversion, and the high output amplified reverse mobile communication signal is supplied to the filter 501, and the filter 501 is a high output amplified mobile communication. A mobile communication signal of a predetermined band is output among the signals, and the output mobile communication signal is transmitted to the base station through the dual band antenna A3.

Meanwhile, the GPS signal received through the dual band antenna A3 is transmitted to the filter 503, and the filter 503 outputs the GPS signal of the predetermined frequency band. The GPS signal of the predetermined frequency band is provided to the amplifier 505. The amplifier 505 receiving the GPS signal amplifies to a predetermined size.

The GS signal amplified to the predetermined magnitude is supplied to the filter 509, and the filter 509 receiving the amplified GS signal outputs the GS signal of the predetermined frequency band, and the GS signal of the predetermined frequency band is dual. It is transmitted to the terminal 300 through the band antenna (A4).

In a mobile communication system having a dual band transmission and reception antenna, by installing a GPS signal repeater for eliminating the shadow area of the GPS signal, it is possible to further improve the quality of location-based services.

6 is a diagram illustrating a configuration of a GPS signal repeater according to a third exemplary embodiment of the present invention. Referring to FIG. 5, the GS signal repeater 700 of the mobile communication system according to the third embodiment of the present invention is connected to the output side of the GPS reception antenna A5 and outputs a GPS signal of a predetermined frequency band among the received GPS signals. A filter 701, an amplifier 703 connected to the output side of the filter 701 and amplifying the magnitude of the GPS signal of the predetermined frequency band, and a predetermined frequency among the amplified GPS signals connected to the output side of the amplifier 703. And a filter 705 for outputting the GPS signal of the band and transmitting the GPS signal of the predetermined frequency band to the terminal 100 through the dual band antenna A6.

The GPS signal repeater 700 of the mobile communication system is connected to a filter 707 for outputting a mobile communication signal of a predetermined frequency band among the mobile communication signals provided from the terminal 100, and connected to an output side of the filter 707. The apparatus further includes an optical repeater 709 for relaying the communication signal to the optical cable 711.

In the mobile communication system having the GPS signal repeater according to the third embodiment of the present invention provided as described above, the GPS signal received through the GPS reception antenna A5 is provided to the filter 701, and the GPS signal is transmitted. The received filter 701 outputs a GPS signal of a predetermined frequency band.

The amplifier 703 receiving the GPS signal of the predetermined frequency band amplifies the magnitude of the GPS signal of the predetermined frequency band, and the amplified GPS signal is supplied to the filter 705. The filter 705 receiving the amplified GPS signal outputs a GS signal of a predetermined frequency band among the amplified GPS signals, and the output GS signal is transmitted to the terminal 300 through the dual band antenna A6.

Meanwhile, the mobile communication signal provided from the terminal 300 is provided to the filter 707, and the filter 707 receiving the mobile communication signal provided from the terminal 300 receives the mobile communication signal of a predetermined frequency band among the mobile communication signals. The mobile communication signal of the predetermined frequency band is transmitted to the optical cable 711 through the optical repeater 709.

That is, in the mobile communication system having an optical repeater for transmitting the mobile communication signal provided from the terminal to the optical cable, it is possible to eliminate the shadow area of the GPS signal by relaying the GPS signal.

As described above, the mobile communication system having the GPS signal repeater according to the present invention is a mobile communication system in which the mobile communication signal repeater is installed in order to eliminate the shadow area of the mobile communication signal transmitted and received through the donor antenna and the service antenna. Therefore, by installing a GPS signal repeater for eliminating the shadow area of the GPS signal between the donor antenna and the service antenna, the location-based service quality can be further improved.

While the invention has been shown and described with respect to specific preferred embodiments thereof, the invention is not limited to the embodiments described above, and is commonly used in the art to which the invention pertains without departing from the spirit of the invention as claimed in the claims. Anyone with knowledge will be able to make various variations.

Claims (4)

It has a mobile communication network, a donor antenna and a service antenna capable of receiving the GPS signal supplied from the GPS satellite and the mobile communication signal transmitted from the base station, and the first base station and the first base station to solve the shadow area of the mobile communication signal of the mobile communication network. A system comprising a mobile communication signal repeater provided between two base stations, And a GPS signal repeater installed between the donor antenna and the service antenna of the mobile communication signal repeater to solve the shadow area of the GPS signal. The method of claim 1, wherein the GPS signal repeater, A first filter for outputting a GPS signal having a predetermined frequency band corresponding to the GPS signal received through the donor antenna; A linear amplifier for shaping the output signal of the filter; And The mobile communication system having a GPS signal repeater, characterized in that provided as a first amplifier for amplifying the output signal of the linear amplifier. In a system having a mobile communication signal repeater capable of transmitting and receiving mobile communication signals of a mobile communication network through a dual band transmission and reception antenna, Second and second signals respectively connected between the dual band transmit / receive antennas to output a mobile communication signal and a GPS signal of a frequency band corresponding to a mobile communication signal and a GPS signal, and transmit the mobile communication signal to the mobile communication signal repeater; 3 filters; A second amplifier receiving the GPS signal of the filter and amplifying the filter to a predetermined size; And Receiving the output signal of the amplifier and the output signal of the mobile communication signal repeater, respectively, and outputting the output signal of the amplifier and the output signal of the mobile communication signal repeater in a frequency band corresponding to the output signal of the amplifier and the output signal of the mobile communication signal repeater And a fourth and fifth filters for transmitting to the terminal through the dual band transmission / reception antenna. In a system having a GPS receiver antenna and a dual band transmission antenna, and having an optical repeater capable of receiving mobile communication signals and GPS signals of a mobile communication network, A sixth filter connected to an output side of the GPS receiver antenna and outputting a frequency band GPS signal corresponding to the GPS signal; A third amplifier receiving the GPS signal of the filter and amplifying the filter to a predetermined magnitude; And A seventh filter providing an output signal of the third amplifier of the predetermined frequency band, which is filtered among the output signals of the output signal of the third amplifier, to the terminal through the dual band receiving antenna; An optical filter for outputting a mobile communication signal of a predetermined frequency band corresponding to an optical communication network from the mobile communication signal received through the dual band receiving antenna; And an optical repeater which amplifies the mobile communication signal of the optical filter to a predetermined size and transmits the optical communication signal through an optical cable.