KR101247992B1 - Optic Extension Equipment for RF Relay - Google Patents

Abstract

The present invention relates to an optical expansion device for RF relay in mobile communication.

According to the present invention, in the case where the base station and the RF repeater in the radio shadow area are linked by extension, the RF signal can be linked in various ways according to the communication environment and link-linked with other generations of mobile communication RF signals. By using optical expansion device of various types, link connection is made in various ways and mobile communication RF signals of different generations are linked together, so that the efficiency of installation and maintenance of expansion device can be enhanced, so that RF signal can be economically relayed. Done.

Mobile communication, RF signal, repeater, RF repeater

Description

Optical Extension Equipment for RF Relay {Optic Extension Equipment for RF Relay}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical expansion device for relaying RF signals in mobile communications. In particular, the present invention relates to an RF signal linking a base station and an RF repeater in a radio shadow area to link RF signals in a variety of communication environments. The present invention relates to an optical expansion device for RF relay, which economically relays an RF signal by linking together another generation of RF signals for mobile communication.

In general, mobile communication provides a communication service by transmitting and receiving an RF signal. In order to provide a good quality communication service, it is necessary to maintain a good reception sensitivity of an RF signal for a mobile terminal. As an effort to maintain the sensitivity of the RF signal to the mobile terminal as described above, an RF repeater is installed in a radio shadow area where the influence of the RF signal provided by the base station is not affected. Extends the communication area, and transmits the RF signal transmitted from the base station to the RF repeater, and also transmits the RF signal transmitted from the RF repeater to the base station, thereby allowing the RF repeater to transmit the RF signal to the mobile terminal located in the radio shadow area. It is being relayed.

In mobile communication, in case of extending the communication area by linking the base station and the RF repeater in the radio shadow area, the RF signal is transmitted in various ways by relaying the RF signal to the RF repeater through RF link, RF cable, or optical link according to the communication environment. There is a need to relay. However, in case of extending the communication area by linking the base station and the RF repeater in the radio shadow area, since the link is connected by using an extension device that transmits one of the RF link, the RF cable, or the optical link, depending on the communication environment, Since various expansion devices in various ways for linking by RF link, RF cable or optical link must be installed separately, the installation and maintenance of expansion devices in various ways decreases the efficiency of installation and maintenance of the expansion device. There is a problem.

In the related art, when the communication area is extended by linking an RF repeater in a radio shadow area with a base station, other generations of mobile communication RF signals such as 2G (second generation) and 3G (generation) mobile communication RF signals may be used. It is not possible to expand by link connection at the same time, and it is necessary to install and maintain various types of expansion devices due to link connection expansion of different generations of mobile communication RF signals. Therefore, the efficiency of installation and maintenance of expansion devices is deteriorated. There is this.

The present invention has been proposed to solve the conventional problems as described above, and its purpose is to link-connect RF signals in a variety of communication environments when the base station and the RF repeater in the radio shadow area are linked by extension. In addition, the present invention provides an optical expansion device for RF relay, which economically relays an RF signal by linking together another generation of RF signals for mobile communication.

The present invention for achieving the object as described above, in the optical expansion device for the RF relay for relaying the RF signal transmitted and received between the base station and the RF repeater, the base station and the RF repeater connected to the Donor equipment for relaying the N-generation and N-first generation RF signals of mobile communication together through an RF link, an RF cable, or an optical cable; And a remote device connected to the donor device through an optical cable and connected to the RF repeater through an RF cable to relay the RF signal transmitted and received between the donor device and the RF repeater.

According to the present invention, the donor equipment includes: an RF module connected to the base station through an RF link, and relaying the RF signal transmitted and received between the base station and the RF repeater through an RF link or an RF cable; The optical module is connected to the base station and the RF link through the RF module, characterized in that it comprises an optical module for relaying the RF signal to the remote device via the optical cable.

In addition, according to the present invention, the RF module demultiplexes the signal received from the base station, divides the N generation and N-1 generation RF signals, and transmits the N generation and N-1 generation RF signals transmitted to the base station. A first multiplexing / demultiplexing unit to multiplex; An N-generation RF signal transceiver for processing the N-generation RF signal transmitted and received between the first multiplexer / demultiplexer and the second multiplexer / demultiplexer to maintain and maintain a constant gain and frequency; An N-1 generation RF signal transceiver for processing the N-1 generation RF signal transmitted / received between the first multiplexer / demultiplexer and the second multiplexer / demultiplexer to maintain a constant gain and frequency; The N-generation RF signal received from the N-generation RF signal transceiver and the N-1 generation RF signal received from the N-1 generation RF signal transceiver is multiplexed and transmitted to the RF link, RF cable or optical module, By demultiplexing the signals received through the RF link, RF cable or optical module, and separating them into N generation and N-1 generation RF signals, the N generation RF signal is transmitted to the N generation RF signal transceiver and the N-1 generation The RF signal may include the second multiplexer / demultiplexer which transmits the N-1th generation RF signal transceiver.

In addition, according to the present invention, the optical module, the first generation signal processing unit in addition to the N-generation and N-1 generation RF transmission signal is separated from the multiplexed signal transmitted from the RF module to the first transmission signal processing unit A first signal transmitting unit for transmitting the N generation and N-1 generation RF reception signals inputted from the RF module together; The first transmission signal processor for combining the Nth and N-1th generation RF transmission signals inputted from the first signal transmission unit, controlling the gain, converting the optical signal to an optical signal, and outputting the optical signal to a first WDM (Wavelength Division Multiplexer); ; The first reception signal processor for converting an optical signal input through the first WDM into an electrical signal and separating gain into N generation and N-1 generation RF reception signals to control gain and outputting the gain to the first signal transmission unit; ; Wavelength division multiplexing the optical signal input from the first transmission signal processor to transmit to the remote device through an optical cable, and receiving the optical signal transmitted through the optical cable from the remote device by wavelength division demultiplexing and receiving the first reception signal. And the first WDM output to a processing unit.

According to the present invention, the remote device separates the N generation and N-1 generation RF transmission signals from the multiplexed signal transmitted from the RF repeater and transfers them to the second reception signal processing unit and the second transmission signal processing unit. A second signal transmitting unit which transmits the N generation and N-1 generation RF receiving signals inputted from the RF repeater together; A second reception signal processing unit for combining the Nth generation and N-1th generation RF transmission signals inputted from the second signal transmission unit, adjusting the gain, converting the optical signal into an optical signal, and outputting the optical signal to a second WDM; The second transmission signal processor for converting an optical signal input through the second WDM into an electrical signal, separating the N and N-1 generation RF received signals into gain control and outputting the gains to the second signal transmission unit; ; Wavelength division multiplexing the optical signal input from the second reception signal processing unit to transmit to the donor equipment through the optical cable, and receiving the optical signal transmitted through the optical cable from the donor equipment through wavelength division demultiplexing to receive the second transmission signal. And the second WDM output to a processing unit.

According to the present invention, in the case where the base station and the RF repeater in the radio shadow area are linked by extension, the RF signal can be linked in various ways according to the communication environment and link-linked with other generations of mobile communication RF signals. By using optical expansion device of various types, link connection is made in various ways and mobile communication RF signals of different generations are linked together, so that the efficiency of installation and maintenance of expansion device can be enhanced, so that RF signal can be economically relayed. Done.

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

The optical expansion device for RF signal relay according to the present invention comprises a donor equipment 10 and a remote equipment 40 as shown in FIG. The donor equipment 10 includes an RF module 20 and an optical module 30. The RF module 20 is connected to an RF link with a base station, through an RF link or an RF cable to an RF repeater in a radio shadow area. The signal is relayed, or the signal is relayed to the RF repeater in the radio shadow area through an optical link connected to the optical module 30.

In this way, the donor equipment 10 shades the RF signal transmitted from the base station by link connection by linking an RF repeater in a radio shadow area with an RF link, an RF cable, or an optical link to a base station connected to the RF link. By transmitting the RF signal transmitted from the RF repeater in the shaded area to the base station by link connection, it transmits the RF signal to the base station by link connection, thereby maintaining the good RF sensitivity for the RF repeater located in the shaded area. Eliminate

That is, as shown in FIG. 2, the donor equipment 10 may connect the base station and the RF repeater in the radio shadow area through various link connections such as an RF link, an RF cable, or an optical link according to a communication environment. The donor equipment 10 is linked with the base station through the antenna ANT1, and relays the transmission and reception signals between the base station and the RF repeater, but in the case of connecting the RF repeater 60a in the radio shadow area by the RF link, the service antenna ANT2. Through wireless communication with the service antenna (ANT3) provided in the RF repeater (60a) through, and when connecting the RF repeater (60a) through the RF cable can be directly connected to the RF repeater (60a) through the RF cable In addition, when the RF repeater 60b is connected to the optical link, the remote device 40 and the RF repeater 60b are connected to the remote device 40 with the optical cable.

The RF module 20 of the donor equipment 10 is wirelessly connected to the base station through the antenna ANT1, and when the RF repeater 60a is connected to the donor equipment 10 through an RF link, the donor equipment 10 The RF module 20 of the wireless communication with the service antenna ANT3 of the RF repeater 60a through the service antenna ANT2 performs a signal relay to the RF repeater 60a in the radio shadow area, and the donor equipment 10 When the RF repeater 60a is connected to the RF repeater 60a through the RF cable, the RF module 20 of the donor equipment 10 is connected to the RF repeater 60a through the RF cable to the RF repeater 60a of the radio wave shadow area. Perform signal relay for

When the RF repeater 60b is connected to the donor equipment 10 through an optical link, the remote device 40 and the RF repeater 60b are connected to the remote device 40 through an optical cable. The optical module 30 converts the electrical RF signal received through the RF module 20 into a light signal and transmits the light to the remote device 40 through the optical cable. ) Converts an optical signal received through the optical cable into an electrical RF signal and transmits it to the RF module 20, the remote device 40 transmits the optical signal received from the donor equipment 10 through the optical cable to the electrical RF signal The optical module of the donor equipment 10 converts the electrical RF signal transmitted from the RF repeater 60b to the RF repeater 60b through the RF cable and converts the signal into an optical signal. Transfer to 30.

As described above, the donor equipment 10 simultaneously relays other N generation and N-1 generation mobile communication RF signals when the RF signal is relayed between the base station and the RF repeater (for example, If 3G (3rd generation), N-1 generation corresponds to 2G (2nd generation), if N generation is 4G (4th generation), N-1 generation corresponds to 3G (3rd generation)). Similarly, when the RF module 20 and the optical module 30 provided in the donor equipment 10 transmit and receive an RF signal to an RF repeater in a radio shadow region as described above, another generation of mobile communication RF signals are transmitted and received together. Process.

Meanwhile, as shown in FIG. 3, the RF module 20 provided in the donor equipment 10 includes a multiplexing / demultiplexing unit 21, an N generation RF signal transceiver 23, and an N-1 generation RF signal transceiver 25 and a multiplexing / demultiplexing unit 27.

When the multiplexer / demultiplexer 21 receives the multiplexed RF signal from the base station through the antenna ANT1, the multiplexed / demultiplexed RF signal is demultiplexed into N-generation and N-1 generation RF signals, so that the N-generation RF signal is In addition to transmitting to the N generation RF signal transceiver 23, the N-1 generation RF signal is transmitted to the N-1 generation RF signal transceiver 25, and the N generation RF signal from the N generation RF signal transceiver 23 Receiving and receiving the N-1 generation RF signal from the N-1 generation RF signal transmission and reception unit 25 and multiplexing the corresponding N-generation and N-1 generation RF signal to the base station through the antenna ANT1.

In addition, the N generation RF signal transceiver 23 performs gain correction and filtering on the N generation RF signal received from the multiplexer / demultiplexer 21 to maintain a constant gain and frequency, thereby multiplexing / demultiplexer 27. The N generation RF signal received from the multiplexing / demultiplexing unit 27 is processed to gain correction and filtering to maintain a constant gain and frequency, and is transmitted to the multiplexing / demultiplexing unit 21.

In addition, the N-1 generation RF signal transceiver 25 performs gain correction and filtering on the N-1 generation RF signal received from the multiplexer / demultiplexer 21 to maintain a constant gain and frequency, thereby multiplexing / demultiplexing. And the N-1th generation RF signal received from the multiplexing / demultiplexing unit 27 is processed to gain correction and filtering to maintain a constant gain and frequency, and is transmitted to the multiplexing / demultiplexing unit 21. do.

The multiplexer / demultiplexer 27 multiplexes the N-generation RF signal received from the N-generation RF signal transceiver 23 and the N-1 generation RF signal received from the N-1 generation RF signal transceiver 25. Transmit to the above-described service antenna ANT2, the RF cable or the optical module 30, and receives the multiplexed RF signal from the above-described service antenna ANT2, the RF cable or the optical module 30, and receives the corresponding received RF signal. Demultiplexed and separated into N generation and N-1 generation RF signals to transmit the N generation RF signal to the N generation RF signal transceiver 23 and the N-1 generation RF signal to the N-1 generation RF signal transceiver ( 25).

Meanwhile, as shown in FIG. 4, the optical module 30 provided in the donor equipment 10 may include a signal transmitter 31, a transmission signal processor 33, a reception signal processor 35, and a wavelength division multiplexer (WDM). (37).

The signal transfer unit 31 separates the N generation and N-1 generation RF transmission signals for transmission to the remote device 40 from the multiplexed signal transmitted from the multiplexing / demultiplexing unit 27 of the RF module 20. Multiplexing / demultiplexing of the RF module 20 together with the N-generation and N-first generation RF reception signals received from the remote device 40 input from the reception signal processing unit 35 while being transmitted to the transmission signal processing unit 33. It passes to part 27.

Then, the transmission signal processor 33 combines the N generation and N-1 generation RF transmission signals input from the signal transmission unit 31 to adjust the gain, converts them into optical signals, and outputs them to the WDM 37.

In addition, the WDM 37 divides the channel of the optical fiber provided in the optical cable into a plurality of channels by the wavelength of the light and can be used as a plurality of communication paths. The optical signal input from the transmission signal processing unit 33 When transmitting to the remote device 40 through the optical signal by the wavelength division multiplexed transmission through the optical cable, and when receiving the optical signal transmitted through the optical cable from the remote device 40, the optical signal applied through the corresponding optical cable The signal is received by the wavelength division demultiplexing and output to the reception signal processor 35.

In addition, the reception signal processing unit 35 converts an optical signal received from the remote device 40 input through the WDM 37 into an electrical signal, and separates the gain into N generation and N-1 generation RF reception signals to adjust gain. The signal is then output to the signal transmission unit 31.

On the other hand, the remote device 40 is connected to the optical module 30 of the donor equipment 10 through an optical cable to transmit and receive a signal through the optical cable is WDM (41), the receiving signal processing unit 43 as shown in FIG. And a transmission signal processing unit 45 and a signal transmission unit 47.

The signal transmission unit 47 separates the N-generation and N-1 generation RF transmission signals for transmission from the RF repeater to the optical module 30 of the donor equipment 10 in the multiplexed signal transmitted through the RF cable and receives the received signal. In addition to the transmission to the processing unit 43 and transmits the N generation and N-1 generation RF reception signals received from the optical module 30 of the donor equipment 40 input from the transmission signal processing unit 45 to the RF repeater.

The reception signal processor 43 combines the N generation and N-1 generation RF transmission signals input from the signal transmission unit 47 to adjust the gain, converts the signal into an optical signal, and outputs the result to the WDM 41.

In addition, the WDM 41 divides the channel of the optical fiber provided in the optical cable into a plurality of channels by the wavelength of the light to be used as a plurality of communication paths, but the optical signal input from the receiving signal processor 43 When transmitting to the donor equipment 10 through the optical signal by wavelength division multiplexing the corresponding optical signal, and when receiving the optical signal transmitted through the optical cable from the donor equipment 10 is applied through the corresponding optical cable The optical signal is received by the wavelength division demultiplexing and output to the transmission signal processor 45.

In addition, the transmission signal processing unit 45 converts the optical signal received from the donor equipment 10 input through the WDM 41 into an electrical signal, and separates it into N generation and N-1 generation RF reception signals to adjust gain. The signal is then output to the signal transmission unit 47.

The optical expansion device for RF relay according to the present invention having the function as described above connects the RF repeater to the donor equipment 10 by various link connections according to the communication environment as shown in FIG. It can be relayed to the RF repeater in the radio shadow area, but it can simultaneously relay the N generation RF signal and the N-1 generation RF signal together. The donor equipment 10 is connected to the base station through the antenna ANT1, and relays the transmission and reception signals between the base station and the RF repeater, but when the RF repeater 60a of the radio wave shadow area to the donor equipment 10 by an RF link. The RF signal is relayed to the service antenna ANT3 provided in the RF repeater 60a through the service antenna ANT2 connected to the multiplexing / demultiplexing unit 27 of the RF module 20 to relay the RF signal. When the RF repeater 60a is connected to the equipment 10 through an RF cable, an RF signal is connected by connecting the RF repeater 60a to the multiplexer / demultiplexer 27 of the RF module 20 directly through an RF cable. In the case of connecting the RF repeater 60b to the donor equipment 10 through an optical link, the remote device 40 is connected to the optical module 30 provided in the donor equipment 10 through an optical cable, and the optical cable is connected through the optical cable. In addition to relaying the RF signal to the remote device (40) to the corresponding remote device (40) The RF signal is connected to the RF repeater 60b by connecting the RF repeater 60b through the RF cable.

The RF module 20 of the donor equipment 10 is wirelessly connected to the base station through the antenna ANT1, and when the RF repeater 60a is connected to the donor equipment 10 through an RF link, the donor equipment 10 The RF module 20 of the RF antenna 20 is wirelessly connected to the service antenna ANT3 of the RF repeater 60a through the service antenna ANT2 to perform the relay of the RF signal to the RF repeater 60a in the radio shadow region, and the donor equipment When the RF repeater 60a is connected to the RF repeater 60a through the RF cable, the RF module 20 of the donor equipment 10 is connected to the RF repeater 60a through the RF cable, thereby RF repeater 60a of the radio wave shadow area. Repeats the RF signal for.

When the RF repeater 60b is connected to the donor equipment 10 through an optical link, the remote equipment 40 and the RF repeater are connected to the optical module 20 through an optical cable. 60b is connected to the RF cable, the optical module 30 converts the electrical RF signal received through the RF module 20 into an optical signal and transmits to the remote device 40 through the optical cable as well as the remote device The optical signal received from the 40 via the optical cable is converted into an electrical RF signal and transmitted to the RF module 20, the remote device 40 is received through the optical cable from the optical module 30 of the donor equipment 10 The optical signal is converted into an electrical RF signal and transmitted to the RF repeater 60b through the RF cable, and the electrical RF signal transmitted through the RF cable from the RF repeater 60b is converted into an optical signal through the optical cable. Optical module 30 of donor equipment 10 To be sent).

The present invention is not limited to the above description, and those skilled in the art can change the present invention in various forms without departing from the technical spirit of the present invention. Such modifications will fall within the technical scope of the present invention.

The present invention can be usefully applied to a system for relaying an RF signal to a radio wave shadow area. According to the present invention, in the case where the base station and the RF repeater in the radio shadow area are linked by extension, the RF signal can be linked in various ways according to the communication environment and link-linked with other generations of mobile communication RF signals. By using optical expansion device of various types, link connection is made in various ways and mobile communication RF signals of different generations are linked together, so that the efficiency of installation and maintenance of expansion device can be enhanced, so that RF signal can be economically relayed. Done.

1 is a view showing an optical expansion device for RF relay according to the present invention.

2 is a diagram illustrating an RF repeater connection method using an optical expansion device according to the present invention.

Figure 3 is a view showing an RF module provided in the donor equipment of the present invention.

4 is a view showing an optical module provided in the donor equipment according to the present invention.

5 illustrates a remote device in accordance with the present invention.

Explanation of symbols on the main parts of the drawings

10; Donor equipment 20; RF Module

30; Optical module 40; Remote equipment

60a, 60b; RF repeater

Claims (5)

delete delete In the optical expansion device for RF relay to relay the RF signal transmitted and received between the base station and the RF repeater, A donor device connected to the base station through an RF link and relaying generation N and generation N-1 RF signals of mobile communication together through an RF link, an RF cable, or an optical cable with respect to the RF repeater; A remote device connected to the donor device through an optical cable and connected to the RF repeater through an RF cable to relay the RF signal transmitted and received between the donor device and the RF repeater. Including, but the donor equipment, A first multiplexing / demultiplexing unit for demultiplexing the signal received from the base station to separate into generation N and generation N-1 RF signals, and multiplexing the generation N and generation N-1 RF signals transmitted to the base station; An N-generation RF signal transceiver for processing the N-generation RF signal transmitted and received between the first multiplexer / demultiplexer and the second multiplexer / demultiplexer to maintain and maintain a constant gain and frequency; An N-1 generation RF signal transceiver for processing the N-1 generation RF signal transmitted / received between the first multiplexer / demultiplexer and the second multiplexer / demultiplexer to maintain a constant gain and frequency; The N-generation RF signal received from the N-generation RF signal transceiver and the N-1 generation RF signal received from the N-1 generation RF signal transceiver is multiplexed and transmitted to the RF link, RF cable or optical module, By demultiplexing the signals received through the RF link, RF cable or optical module, and separating them into N generation and N-1 generation RF signals, the N generation RF signal is transmitted to the N generation RF signal transceiver and the N-1 generation The second multiplexer / demultiplexer transmits an RF signal to the N-1th generation RF signal transceiver. Optical expansion device for an RF relay comprising a. In the optical expansion device for RF relay to relay the RF signal transmitted and received between the base station and the RF repeater, A donor device connected to the base station through an RF link and relaying generation N and generation N-1 RF signals of mobile communication together through an RF link, an RF cable, or an optical cable with respect to the RF repeater; A remote device connected to the donor device through an optical cable and connected to the RF repeater through an RF cable to relay the RF signal transmitted and received between the donor device and the RF repeater. Including, but the donor equipment, Generation N and N-1 generation RF transmission signals are separated from the multiplexed signal transmitted from the provided RF module and transmitted to the first transmission signal processing unit, and N generation and N-1 generation RF inputted from the first reception signal processing unit. A first signal transmission unit for transmitting a received signal together to the RF module; A first transmission signal processor for combining the Nth and N-1th generation RF transmission signals inputted from the first signal transmission unit, converting the gains into optical signals and outputting the optical signals to a first wavelength division multiplexer (WDM); The first reception signal processor for converting an optical signal input through the first WDM into an electrical signal and separating gain into N generation and N-1 generation RF reception signals to control gain and outputting the gain to the first signal transmission unit; ; Wavelength division multiplexing the optical signal input from the first transmission signal processor to transmit to the remote device through an optical cable, and receiving the optical signal transmitted through the optical cable from the remote device by wavelength division demultiplexing and receiving the first reception signal. And the first WDM output to a processing unit. In the optical expansion device for RF relay to relay the RF signal transmitted and received between the base station and the RF repeater, A donor device connected to the base station through an RF link and relaying generation N and generation N-1 RF signals of mobile communication together through an RF link, an RF cable, or an optical cable with respect to the RF repeater; A remote device connected to the donor device through an optical cable and connected to the RF repeater through an RF cable to relay the RF signal transmitted and received between the donor device and the RF repeater. Including, but the remote device, Generation N and N-1 generation RF transmission signals are separated from the multiplexed signal transmitted from the RF repeater and transmitted to the second reception signal processing unit, and N generation and N-1 generation RF reception input from the second transmission signal processing unit is performed. A second signal transmission unit for transmitting a signal to the RF repeater together; A second reception signal processing unit for combining the Nth generation and N-1th generation RF transmission signals inputted from the second signal transmission unit, adjusting the gain, converting the optical signal into an optical signal, and outputting the optical signal to a second WDM; The second transmission signal processor for converting an optical signal input through the second WDM into an electrical signal, separating the N and N-1 generation RF received signals into gain control and outputting the gains to the second signal transmission unit; ; Wavelength division multiplexing the optical signal input from the second reception signal processing unit to transmit to the donor equipment through the optical cable, and receiving the optical signal transmitted through the optical cable from the donor equipment through wavelength division demultiplexing to receive the second transmission signal. And the second WDM output to a processing unit.

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