KR100595838B1 - Error detector and repeater using it in mobile telecommunication system - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a relay apparatus having a failure detection function in a mobile communication system.

2. The problem to be solved by the invention

The present invention provides a relay apparatus capable of providing a service to a terminal in a radio shading area at a low installation cost in a CDMA mobile communication system.

3. Summary of Solution to Invention

The present invention relates to a device for relaying a signal between a base station and a terminal located in a shaded area in a mobile communication system. The present invention converts a radio signal received from the base station into an optical signal and transmits the signal to a corresponding remote relay unit. Main relay means for converting the optical signal received from the radio signal to the base station; At least one remote relay means for converting an optical signal received from the main relay means into a radio signal and transmitting the radio signal received from a specific terminal to a main signal; And at least one bidirectional amplifying means for amplifying and transmitting the wireless signal converted by the remote relay means to the outside and amplifying and transmitting the wireless signal received from the terminal to the remote relay means. And a failure detection control means for determining that a failure has occurred if an optical signal is not received from the specific remote relay means and notifying the outside of the occurrence of the failure.

4. Important uses of the invention

The present invention is used in the mobile communication system of the code division multiple access method.

Code Division Multiple Access, Mobile Communication System, Failure Detection, Relay Device

Description

ERROR DETECTOR AND REPEATER USING IT IN MOBILE TELECOMMUNICATION SYSTEM}             

1 is a block diagram of a relay apparatus in a conventional mobile communication system.

2 is a block diagram of an embodiment of a relay apparatus in a mobile communication system according to the present invention;

3 is a block diagram of an embodiment of a failure detector of a relay device in a mobile communication system according to the present invention;

Explanation of symbols on the main parts of the drawings

210: main relay unit 221 to 22 m: remote relay unit

231 to 23j: bidirectional amplifier 311: radio frequency input unit

313 and 324 laser diodes 314 and 321 photodiodes

316: radio frequency output unit 317: fault detection control unit

325: duplexer 326: signal blocking control unit

312, 315, 322, 323: amplification section

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a relay apparatus in a mobile communication system using a code division multiple access (CDMA) scheme, and more particularly, to an error detector for detecting a transmission / reception occurrence, and a terminal in a radio shadow area by employing the same. It relates to a relay device capable of providing a service.

1 is a configuration diagram of a relay device in a conventional mobile communication system, which is a relay device for providing a service to a terminal located in a radio shade area.

As shown in FIG. 1, the conventional relay device includes a main relay 110 connected to the repeater 101 by wire and a remote relay 121 connected to the main relay 110 via an optical cable. 2)).

Here, only one main relay 110 is installed in a building having a shaded area, but the remote relay is installed in each floor of the building.

The operation of a conventional relay device having such a structure will be described below.

When the radio frequency signal transmitted from the base station is transmitted to the main relay unit 110 through the repeater 101, the main relay unit 110 converts the received radio frequency signal into an optical signal to remote relay unit 121 to 12 ( n + 2)), and then the remote repeaters 121 to 12 (n + 2) convert the transmitted optical signals into electrical radio frequency signals and transmit them to the terminal.

When the radio frequency signal is received from the terminal, the remote relays 121 to 12 (n + 2) convert the received radio frequency signals into optical signals and transmit the converted optical signals to the main relay 110, followed by the main relay. The unit 110 converts the transmitted optical signal into a radio frequency signal. In this way, the converted radio frequency signal is transmitted to the base station through the repeater (101).

However, in the case of the relay device in the conventional mobile communication system as described above, since expensive remote relay equipment is installed for each floor of a building, there is a problem that the installation cost is too high.

Accordingly, an object of the present invention is to provide a relay apparatus capable of providing a service to a terminal in a radio shading area with a small installation cost in a CDMA mobile communication system.

Another object of the present invention is to provide a failure detector provided in a relay device of a mobile communication system and capable of detecting a failure occurring during transmission and reception between a base station and a terminal.

An apparatus of the present invention for achieving the above object is a device for relaying a signal between a base station and a terminal located in a shadow area in a mobile communication system, the remote signal by converting a radio signal received from the base station to an optical signal Main relay means for transmitting to the base station, converting the optical signal received from a specific remote relay means into a radio signal; At least one remote relay means for converting an optical signal received from the main relay means into a radio signal and transmitting the radio signal received from a specific terminal to a main signal; And at least one bidirectional amplifying means for amplifying and transmitting the wireless signal converted by the remote relay means to the outside and amplifying and transmitting the wireless signal received from the terminal to the remote relay means. And a failure detection control means for determining that a failure has occurred if an optical signal is not received from the specific remote relay means and notifying the outside of the occurrence of the failure.
Meanwhile, another apparatus of the present invention is a device for relaying a signal between a base station and a terminal located in a shadow area in a mobile communication system, converting a radio signal received from the base station into an optical signal and transmitting the signal to a corresponding remote relay means. Main relay means for converting an optical signal received from a specific remote relay means into a radio signal and transmitting the radio signal to the base station; At least one remote relay means for converting an optical signal received from the main relay means into a radio signal and transmitting the radio signal received from a specific terminal to a main signal; And at least one bidirectional amplifying means for amplifying and transmitting the wireless signal converted by the remote relay means to the outside, and amplifying and transmitting the wireless signal received from the terminal to the remote relay means. It is characterized in that it comprises a signal blocking control means for blocking the optical signal to be transmitted to the main relay means to determine that the failure occurs if the optical signal is not received from the main relay means.

On the other hand, another apparatus of the present invention is a failure detector for use in a relay apparatus having a main relay means and a remote relay means connected through a forward link optical cable and a reverse link optical cable in a mobile communication system, transmitted from a base station and connected First pre / optical converting means for converting the radio frequency signal into an optical signal and transmitting the converted radio frequency signal to the remote relay means; First signal detection and conversion means for detecting the optical signal converted by the first pre / optical conversion means and converting the optical signal into a radio frequency signal; Second pre / optical conversion means for converting a radio frequency signal transmitted and connected from a terminal into an optical signal and transmitting the converted optical signal to the main relay means; Second signal detection and conversion means for detecting an optical signal converted by the second pre / optical conversion means and converting the optical signal into a radio frequency signal; Check the optical signal detection state of the first signal detection and conversion means to determine the occurrence of a failure, and control the transmission of the optical signal from the second pre / optical conversion means to the second signal detection and conversion means according to the determination result. Signal blocking control means; And failure detection control means for checking the optical signal detection state of the second signal conversion and detection means to determine the occurrence of a failure, and for displaying the failure on an external display means.

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

2 is a block diagram of an embodiment of a relay apparatus in a mobile communication system according to the present invention.

As shown in Figure 2, the relay device of the present invention, the main relay unit 210 for transmitting and receiving radio frequency signals to and from the external instrument 201 through a wire, and the main relay unit 210 through the optical cable and Remote repeaters 221-22m for transmitting and receiving optical signals, and bidirectional amplifiers 231-23j for amplifying radio frequency signals transmitted and received via coaxial cables connected to the remote repeaters 221-22m. Where j and m are one or more natural numbers.

Here, only one main relay 210 is installed in a building having a shaded area as in the prior art. However, unlike the prior art, the remote relay unit is not installed on each floor of the building, and is installed at a predetermined distance interval to provide a communication service to the terminal through the bidirectional amplification unit.

The bidirectional amplification unit may be installed on each floor of the building, and as shown in the drawing, only one may be installed on each floor, or a plurality of bidirectional amplifiers may be installed on each floor.

Meanwhile, the bidirectional amplification units 231 to 23j transmit and receive to and from a terminal located in a shaded area inside the building through the connected low power antennas.

As described above, the operation of the relay apparatus of the present invention will be described in detail as follows.

First, the transmission process from the base station to the terminal will be described.

When the radio frequency signal transmitted from the base station is transmitted to the main relay unit 210 through the repeater 201, the main relay unit 210 converts the received radio frequency signal into an optical signal to remote relay units (221 to 22 m). It converts into an optical signal in order to minimize the loss of the radio frequency signal.

Subsequently, the remote relay units 221 to 22m respectively convert the optical signal transmitted through the optical cable into an electrical radio frequency signal, and then transmit the optical signal to the bidirectional amplifier connected through the coaxial cable.

As such, the radio frequency signal transmitted through the coaxial cable is amplified by the bidirectional amplification units 231 to 23j and transmitted to a terminal located in a shaded area inside the building, where the bidirectional amplification units 231 to 23j are respectively connected to the coaxial cable. Compensate for the radio frequency signal as much as it is lost.

Next, a reception process from the terminal to the base station will be described.

The radio frequency signal transmitted from the terminal located in the shaded area inside the building is amplified by the bidirectional amplifiers 231 to 23j, and then transmitted to the corresponding remote relay unit through a coaxial cable. In this case, the bidirectional amplifiers 231 to 23j compensate for the signal loss due to the coaxial cable, respectively.

As such, when the amplified radio frequency signal is transmitted through the coaxial cable, the remote relay units 221 to 22 m respectively convert the radio frequency signals into optical signals and then transfer them to the main relay 210 in order to minimize signal loss. do.

Then, the main repeater 210 converts the transmitted optical signal into a radio frequency signal and transmits it to the repeater 201, and the repeater 201 transmits the transmitted radio frequency signal to the base station.

As described above, the present invention can reduce the installation cost by using a two-way amplification equipment capable of transmitting and receiving with the remote relay equipment, instead of installing expensive remote relay equipment for each floor as in the conventional method.

3 is a configuration diagram of an embodiment of a failure detector of a relay device in a mobile communication system according to the present invention, and substantially illustrates an exemplary configuration of a main relay unit and a remote relay unit of FIG. 2.

Referring to FIG. 3, the main relay unit of FIG. 2 includes a transmitter for converting a radio frequency signal transmitted from a base station through the repeater 201 to an optical signal and transmitting the optical signal to the remote relay unit, and optical signals received from the remote relay units. The receiver converts the signal into a radio frequency signal and transmits the signal to the base station through the repeater 201.

In addition, the remote repeater of FIG. 2 includes a transmitter for converting an optical signal transmitted from the main relay into a radio frequency signal and transmitting the radio signal to the bidirectional amplifier, and converting a radio frequency signal received from the bidirectional amplifier into an optical signal. It consists of a receiving end for transmitting to the main relay.

The transmitting end of the main relay unit includes a radio frequency input unit 311 for connecting a radio frequency signal transmitted from the repeater 201 and an amplifier 312 for amplifying a radio frequency signal connected through the radio frequency input unit 311. And an all-optical conversion unit 313 for converting the radio frequency signal amplified by the amplifying unit 312 into an optical signal and transmitting the converted optical signal to the remote relay unit. Here, the pre / light converter 313 is a laser diode.

The receiving end of the main relay unit includes a signal detection and conversion unit 314 for detecting and converting an optical signal received from the remote relay units into a radio frequency signal, and a radio frequency converted by the signal detection and conversion unit 314. An amplifier 315 for amplifying the signal, and a radio frequency output unit 316 for outputting a radio frequency signal amplified by the amplifier 315 to the repeater. Here, the signal detection and conversion unit 314 is a photodiode.

The transmitting end of the remote relay unit includes a signal detection and conversion unit 321 for converting an optical signal transmitted from the main relay unit into a radio frequency signal, and a radio frequency converted by the signal detection and conversion unit 321. Amplifying unit 322 for amplifying the signal and outputting the signal to the bi-directional amplifier through the duplexer 325. Here, the signal detection and conversion unit 321 is a photodiode.

The receiving end of the remote relay unit includes an amplifying unit 323 for amplifying a radio frequency signal received through the duplexer 325 from the bidirectional amplifying unit, and a radio frequency signal amplified by the amplifying unit 323 as an optical signal. It is provided with a front / light conversion unit 324 for converting and transmitting to the main relay. Here, the pre / light converter 324 is a laser diode.

Meanwhile, the main relay of FIG. 2 further includes a failure detection control unit 317 for detecting a failure occurring in transmission and reception and outputting it to an external display device (for example, a liquid crystal display such as an LCD). In addition, the remote repeater of FIG. 2 further includes a signal blocking control unit 326 which blocks transmission of an optical signal to the main relay unit when a failure occurs.

In the relay apparatus of the present invention having the above-described components, only the elements used for fault detection will be described. The front / light conversion unit 313, the signal detection and conversion unit 314, and the fault detection control unit 317 , The signal detection and conversion unit 321, the front / light conversion unit 324, and the signal blocking control unit 326.

Referring to the operation of the fault detector according to the present invention made of such components as follows.

When a failure occurs on the forward link optical cable 301 for transmitting the optical signal from the main relay to the remote relay unit, the signal conversion and detection unit 321 cannot detect the optical signal normally, and at this time, the signal blocking control unit 326 ) Detects a signal detection state of the signal conversion and detection unit 321 to determine the occurrence of a failure, and then blocks transmission of the optical signal from the pre / optical conversion unit 324 to the main relay unit.

As such, when the transmission of the optical signal from the remote relay unit to the main relay unit is interrupted, the signal detection and conversion unit 314 of the main relay unit does not normally detect the optical signal.

As such, when the optical signal is not detected, the error detection control unit 317 checks the signal detection state of the signal detection and conversion unit 314 to determine that a failure has occurred, and then displays the external display so that the user can confirm the failure. Indicate the fault on the device.

When a failure occurs on the reverse link optical cable 302 for transmitting the optical signal from the remote relay unit to the main relay unit, the signal detection and conversion unit 314 does not detect the optical signal normally. As described above, the failure detection control unit 317 allows the user to check the occurrence of the failure on the external display device.

Accordingly, the present invention enables the user to quickly identify and recover from failures occurring on the forward and reverse link optical cables, thereby greatly reducing the time required for recovery in the event of a failure, and quickly recovering a failed optical cable to provide stable communication services. Can provide.

Although the technical idea of the present invention has been described in detail according to the above preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

As described above, the present invention employs a low-cost bidirectional amplification equipment connected to a coaxial cable to provide a communication service to a terminal located in a shadow area, thereby significantly reducing installation costs while improving communication service quality, and also providing an optical cable. Users can easily check the faults that occur on the system, which can significantly reduce the time and cost required to recover the faults.

Claims (19)

An apparatus for relaying a signal between a base station and a terminal located in a shaded area in a mobile communication system, A main relay means for converting an optical signal received from the base station into an optical signal and transmitting the optical signal to a corresponding remote relay means, and converting an optical signal received from a specific remote relay means into a wireless signal and transmitting the optical signal to the base station; At least one remote relay means for converting an optical signal received from the main relay means into a radio signal and transmitting the radio signal received from a specific terminal to a main signal; And At least one bidirectional amplification means for amplifying the radio signal converted by the remote relay means for transmission to the outside, and amplifies the radio signal received from the terminal to pass to the remote relay means, The main relay means, And a failure detection control means for determining that a failure has occurred if an optical signal is not received from the specific remote relay means and notifying the fact that the failure has occurred to the outside. The method of claim 1, And the main relay means and the remote relay means are connected via an optical cable. The method of claim 1, And the remote relay means and the bidirectional amplification means are connected through a coaxial cable. The method according to any one of claims 1 to 3, The main relay means, A transmitter for converting a radio signal received from the base station into an optical signal and transmitting the optical signal to a corresponding remote relay unit; And Receiving end converts the optical signal received from a specific remote relay means to a radio signal and delivers it to the base station Relay apparatus comprising a. delete The method of claim 4, wherein The transmitting end, Radio frequency input means for receiving radio signals from the base station; Amplifying means for amplifying a radio signal received by the radio frequency input means; And All / optical conversion means for converting the radio signal amplified by the amplification means into an optical signal Relay apparatus comprising a. The method of claim 6, The all-optical conversion means is a relay device, characterized in that it comprises a laser diode. The method of claim 4, wherein The receiving end, Signal detecting and converting means for detecting and converting an optical signal received from a specific remote relay means into a wireless signal; Amplifying means for amplifying the radio signal converted by the signal detecting and converting means; And Radio frequency output means for transmitting the radio signal amplified by the amplification means to the base station Relay apparatus comprising a. The method of claim 8, And the signal detecting and converting means comprises a photodiode. An apparatus for relaying a signal between a base station and a terminal located in a shaded area in a mobile communication system, A main relay means for converting an optical signal received from the base station into an optical signal and transmitting the optical signal to a corresponding remote relay means, and converting an optical signal received from a specific remote relay means into a wireless signal and transmitting the optical signal to the base station; At least one remote relay means for converting an optical signal received from the main relay means into a radio signal and transmitting the radio signal received from a specific terminal to a main signal; And At least one bidirectional amplification means for amplifying the radio signal converted by the remote relay means for transmission to the outside, and amplifies the radio signal received from the terminal to pass to the remote relay means, The remote relay means, And a signal blocking control means for blocking an optical signal to be transmitted to the main relay means by determining that a failure has occurred when the optical signal is not received from the main relay means. The method of claim 10, The remote relay means, Signal connection means for wireless signal connection with specific bidirectional amplification means; A transmitter for converting the optical signal received from the main relay means into a wireless signal and transferring the optical signal to the bidirectional amplification means through the signal connection means; And Receiving end for converting the radio signal received through the signal connection means from a specific bi-directional amplification means into an optical signal and delivered to the main relay means Relay apparatus comprising a. The method of claim 11, The transmitting end, Signal detecting and converting means for detecting and converting the optical signal received from the main relay means into a wireless signal; And Amplifying means for amplifying the radio signal converted by the signal detecting and converting means Relay apparatus comprising a. The method of claim 12, And the signal detecting and converting means comprises a photodiode. The method of claim 11, The receiving end, Amplification means for amplifying a radio signal received through the signal connection means; And All / optical conversion means for converting the radio signal amplified by the amplification means into an optical signal Relay apparatus comprising a. The method of claim 14, The all-optical conversion means is a relay device, characterized in that it comprises a laser diode. A fault detector for use in a relay apparatus having a main relay unit and a remote relay unit connected through a forward link optical cable and a reverse link optical cable in a mobile communication system, First electric / optical conversion means for converting the radio frequency signal transmitted from the base station into the optical signal and transmitting the converted optical signal to the remote relay means; First signal detection and conversion means for detecting the optical signal converted by the first pre / optical conversion means and converting the optical signal into a radio frequency signal; Second pre / optical conversion means for converting a radio frequency signal transmitted and connected from a terminal into an optical signal and transmitting the converted optical signal to the main relay means; Second signal detection and conversion means for detecting an optical signal converted by the second pre / optical conversion means and converting the optical signal into a radio frequency signal; Check the optical signal detection state of the first signal detection and conversion means to determine the occurrence of a failure, and control the transmission of the optical signal from the second pre / optical conversion means to the second signal detection and conversion means according to the determination result. Signal blocking control means; And Obstacle detection control means for determining the occurrence of a failure by checking the optical signal detection state of the second signal conversion and detection means and displaying the occurrence of the failure on an external display means. Failure detector made, including. The method of claim 16, The signal blocking control means, The optical signal confirms that the optical signal is normally transmitted from the main relay means to the remote relay means through the forward link optical cable. Disturbance detector, characterized in that to block signal transmission. The method according to claim 16 or 17, The main relay means, The first all-optical conversion means, the second signal detection and conversion means, and the failure detection control means. Failure detector made, including. The method according to claim 16 or 17, The remote relay means, The second pre / optical conversion means, the first signal detection and conversion means, and the signal blocking control means Failure detector made, including.

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