KR100899083B1 - Analog optical transmission system - Google Patents

Abstract

The present invention provides an optical transmission system through a heterogeneous base station to enable sharing of signals of heterogeneous base stations installed at different locations.

To this end, when the base station of the first mobile communication network and the base station of the second mobile communication network are not at the same position and are separated from each other by a predetermined distance or more, the present invention is installed in the base station of the first mobile communication network and is a base station of the first mobile communication network. After converting a plurality of RF signals received from each into an optical signal using a different wavelength, and then multiplexing the plurality of optical signals to output through one optical line, demultiplexing the optical signal received through the optical line A donor for converting each of the separated optical signals into RF signals and applying them to the base station of the first mobile communication network; It is installed in the base station of the second mobile communication network, receives the optical signal output from the donor through the optical line and separates into a plurality of optical signals through demultiplexing, and then convert each separated optical signal into an RF signal Applied to the optical line sharing device, and converts a plurality of RF signals received from the optical line sharing device into optical signals using different wavelengths, and then multiplexing the converted multiple optical signals through one optical line It comprises a remote to transmit to the donor.

Accordingly, the present invention can increase the utilization of the optical line, it is possible to reduce the installation cost, operating cost and track rental cost.

Service Area Extension, Donor, Remote, CWDM Multiplexer / Demultiplexer, Other Wavelength, Analog Optical Signals, Photoelectric Conversion, All Optical Conversion

Description

Optical transmission system through heterogeneous base station {ANALOG OPTICAL TRANSMISSION SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmission system through heterogeneous base stations. In particular, when base stations of different networks are installed at different locations, the base station of the first mobile communication network may be a base station of a second mobile communication network through an optical line. When the signal is transmitted, the base station of the second mobile communication network shares the RF signal received from the base station of the first mobile communication network and the RF signal output from the base station of the second mobile communication network so that it can be transmitted to each repeater. Relates to a transmission system.

In establishing a mobile communication network, it is preferable to service all service areas with a general base station, but since the base station is located at the most optimal place through cell analysis in consideration of economical efficiency, obstacles such as large buildings, hills, basements, and mountain areas Due to this, a number of shaded areas that do not propagate are generated.

As a result, a repeater is installed in the shaded area where the signal of the base station is hard to reach, thereby eliminating the shaded area.

Meanwhile, with the development of mobile communication technology, investments in systems for 3G mobile networks such as WCDMA and 3.5G mobile networks such as Wibro have increased, leading to an increase in base stations of 3G mobile networks and 3.5G mobile stations. In the related art, as shown in FIG. 1, a base station of a second generation mobile communication network, which is an existing system (hereinafter, referred to as a "CDMA base station") and a base station of a third generation mobile communication network, which is a new system (hereinafter, referred to as a "WCDMA base station"). If the same location is located, it is possible to transmit different base station signals to each repeater through a single optical line by using the optical line sharing device.

However, as shown in FIG. 2, when the CDMA base station and the WCDMA base station are not located at the same position and are separated from each other, the CDMA base station and the WCDMA base station transmit RF signals by connecting each repeater and an optical line. . Accordingly, when a CDMA base station transmits an RF signal to three synchronous repeaters and the WCDMA base station needs to transmit an RF signal to three asynchronous repeaters, a total of six optical lines are required.

As described above, when base stations of different networks are installed at a predetermined distance in the related art, each base station connects optical lines with each repeater individually, so that optical line utilization is lowered, and installation costs, operation costs, and line rental costs are reduced. There is a problem that increases.

The present invention has been made to solve the above-described problem, when the base stations of different networks are installed in different locations, the pre / optical conversion using different light wavelengths in the donors installed in the base station of the first mobile communication network RF signals from different sectors are transmitted to a remote installed in the base station of the second mobile communication network through a CWDM multiplexer using a CWDM multiplexer, and the optical path sharing apparatus installed in the base station of the second mobile communication network receives the remote signals. It is an object of the present invention to provide an optical transmission system through a heterogeneous base station that allows the RF signal of the first mobile communication network and the RF signal output from the base station of the second mobile communication network to be shared and transmitted to each repeater.

In the optical transmission system through a heterogeneous base station according to an embodiment of the present invention for achieving the above object, when the base station of the first mobile communication network and the base station of the second mobile communication network are not at the same position and are separated from each other by a predetermined distance or more. Installed in the base station of the first mobile communication network, and converting a plurality of RF signals received from the base station of the first mobile communication network into optical signals using different wavelengths, and then multiplexing the plurality of optical signals Outputting through a line, demultiplexing the optical signal received through the optical line into a plurality of optical signals, and converting each of the separated optical signals into RF signals and applying them to a base station of the first mobile communication network. Donor; It is installed in the base station of the second mobile communication network, receives the optical signal output from the donor through the optical line and separates into a plurality of optical signals through demultiplexing, and then convert each separated optical signal into an RF signal Applied to the optical line sharing device, and converts a plurality of RF signals received from the optical line sharing device into optical signals using different wavelengths, and then multiplexing the converted multiple optical signals through one optical line It is preferable to include a remote for transmitting to the donor.

Furthermore, the donor receives a plurality of RF signals applied from a base station of the first mobile communication network, and converts each of the input optical signals into RF signals by using different wavelengths. A plurality of optical transmission / reception processing units for applying to a base station of a first mobile communication network; The optical signals output from the plurality of optical transceivers are combined into one signal and transmitted to the remote through the optical line, and the optical signals received from the remote through the optical line are separated into a plurality of optical signals, respectively. It is preferable to include a CWDM multiplexer / demultiplexer input to the optical transmission and reception processing unit of.

The optical transmission and reception processing unit may further include: a forward processing unit converting an RF signal received from a base station of the first mobile communication network into an optical signal using different wavelengths and applying the same to the CWDM multiplexer / demultiplexer; And a reverse processor for converting an optical signal received from the CWDM multiplexer / demultiplexer into an RF signal and applying the RF signal to a base station of the first mobile communication network, wherein the forward processor is an RF received from a base station of the first mobile communication network. A first amplifier for amplifying the signal, an attenuator for attenuating the RF signal output from the first amplifier, a second amplifier for amplifying the RF signal applied from the attenuator, and an RF signal applied from the second amplifier And an all-optical converter for converting and outputting a signal, wherein the reverse processing unit includes: an opto-electric converter for converting an optical signal received from the CWDM multiplexer / demultiplexer into an RF signal, and applied from the optical / electric converter A first amplifier for amplifying the received RF signal, and attenuating the RF signal applied from the first amplifier An attenuator, a filter for passing only an RF signal of a desired frequency band among the RF signals applied from the attenuator, and a second amplifier for amplifying and outputting the RF signal applied from the filter to a base station of the first mobile communication network; It is preferable to make it.

The remote may receive a plurality of RF signals applied from the optical line sharing device, respectively, and convert the respective optical signals into RF signals using different wavelengths, and convert the respective optical signals into RF signals. A plurality of optical transmission / reception processing units for applying to a sharing device; The optical signals output from the plurality of optical transceivers are combined into one signal and transmitted to the donor through the optical line, and the optical signals received from the donor through the optical line are separated into a plurality of optical signals, respectively. It is preferable to include a CWDM multiplexer / demultiplexer input to the optical transmission and reception processing unit of.

The optical transmission and reception processing unit may further include: a forward processing unit converting an optical signal received from the CWDM multiplexer / demultiplexer into an RF signal and applying the RF signal to the optical line sharing device; And a reverse processor configured to convert the RF signal received from the optical line sharing device into an optical signal using different wavelengths and apply the CW signal to the CWDM multiplexer / demultiplexer, wherein the forward processor is applied from the CWDM multiplexer / demultiplexer. An optical / electric converter for converting the received optical signal into an RF signal, a first amplifier for amplifying the RF signal applied from the optical / electric converter, an attenuator for attenuating the RF signal applied from the first amplifier, and the attenuator And a second amplifier configured to amplify the RF signal applied from the optical line sharing device by amplifying the RF signal received from the optical line sharing device. The reverse processing unit includes an attenuator for attenuating the RF signal received from the optical line sharing device, and applied from the attenuator. An amplifier for amplifying the received RF signal, and an RF signal applied from the amplifier It comprises a front / optical converter for converting into an optical signal and outputting preferred.

The optical line sharing apparatus converts a plurality of RF signals output from the remote into an optical signal and converts the plurality of RF signals output from a base station of the second mobile communication network into an optical signal. It is preferable to multiplex the optical signal applied from the optical donor module to be output and transmit it to the optical line sharing device installed on the repeater side through one optical line.

According to the optical transmission system through the heterogeneous base station of the present invention, when base stations of different networks are installed in different locations, each of the pre / optical conversions using different optical wavelengths in donors installed in the base stations of the first mobile communication network RF signals of different sectors are transmitted to a remote installed in the base station of the second mobile communication network through a single optical line by using a CWDM multiplexer, and the RF signals of the first mobile communication network and the base station of the second mobile communication network received through the remote The output RF signal is shared by the optical line sharing device installed in the base station of the second mobile communication network and transmitted to each repeater, thereby increasing optical line utilization, and reducing installation cost, operation cost, and line rental cost.

Hereinafter, an optical transmission system through a heterogeneous base station according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 to 5 are views showing the configuration of an optical transmission system through a heterogeneous base station according to an embodiment of the present invention.

In FIG. 3, the donor 100 is installed in the base station 10 of the first mobile communication network, converts RF signals of different sectors received from the base station 10 into optical signals using different wavelengths, and then CWDM By using a multiplexer (Coarse Wavelength Division Multiplexing) multiplexer, a plurality of optical signals are bundled together and transmitted to a remote 200 installed in the base station 20 of the second mobile communication network through one optical line, and one optical line. After separating the optical signal received from the remote 200 through a plurality of optical signals through a CWDM type demultiplexer, and converts each optical signal into an RF signal to apply to the base station 10.

The remote 200 is installed in the base station 20 of the second mobile communication network located at a predetermined distance from the base station 10 of the first mobile communication network, and transmits the optical signal received from the donor 100 via the optical line to the CWDM type demultiplexer. After the separation into a plurality of optical signals through the conversion of each optical signal to the RF signal to the donor side optical line sharing device 300, a plurality of RF received from the donor side optical line sharing device 300 The signal is converted into an optical signal using different wavelengths, and then a plurality of optical signals are bundled together using a CWDM multiplexer and transmitted to the donor 100 through one optical line.

The donor side optical line sharing device 300 is located between the remote 200 and the donor side optical line sharing device 300 to convert an RF signal output from the remote 200 into an optical signal and outputs the optical donor module. (Not shown) and an optical donor module (not shown) positioned between the base station 20 and the donor side optical line sharing device 300 to convert a plurality of RF signals output from the base station 20 into optical signals. The optical signals received from the multiplexer are bundled into one and transmitted to the remote side optical line sharing apparatus 400 through one optical line, and the optical signal received from the remote side optical line sharing apparatus 400 through the optical line is demultiplexer. Through the optical signal of the first mobile communication network and the optical signal of the second mobile communication network is separated.

Meanwhile, as shown in FIG. 4, the donor 100 receives base station signals (RF signals) of different sectors from the base station 10 of the first mobile communication network and converts the RF signals into optical signals using different wavelengths. A plurality of optical transmit / receive units (OTRUs) for converting and converting an optical signal received from the remote 200 through the CWDM multiplexer / demultiplexer 120 to an RF signal and applying it to the base station 10. ) And the analog optical signals output from the plurality of optical transmission and reception processing units 110 are combined into one signal and transmitted to the remote 200 through one optical line, and the optical signals received from the remote 200 are separated from each other. The CWDM multiplexer / demultiplexer 120 is transmitted to the optical transmission / reception processing unit 110.

As described above, each of the optical transmission and reception processing unit 110 is configured to be detachable, and when only one sector is needed, only one optical transmission and reception processing unit 110 is used, and when only two sectors are required, the optical transmission and reception processing unit 110 is required. It is used to install two, it is preferable to use the additional transmission and reception processing unit 110 if additional expansion is required.

Each of the above-described optical transmission / reception processing units 110 receives base station signals of different sectors applied from the base station 10 and converts them into optical signals using different wavelengths, for example, the first signal. The base station signal of the sector is applied by the first optical transmission / reception processing unit 110a to be converted into an optical signal using a wavelength of 1310 nm, and the base station signal of the second sector is applied by the second optical transmission / reception processing unit 110b to obtain a 1330 nm The wavelength is converted into an optical signal, and the base station signal of the third sector is applied by the third optical transmission / reception processing unit 110c to convert into an optical signal using a wavelength of 1550 nm.

As shown in FIG. 5, each optical transmission and reception processor 110 converts an RF signal received from the base station 10 into an optical signal and transmits the optical signal to the remote 200 and the remote 200. And a reverse processor 140 for converting the optical signal received from the RF signal to the base station 10. The forward processor 130 includes a signal level measurer 131 and a first amplifier 133. , An attenuator 135, a second amplifier 137, and an all-optical converter 139.

In this configuration, the signal level measuring unit 131 couples the RF signal applied from the base station 10 to the first amplifier 133 to extract a portion of the RF signal applied from the base station 10. And a signal measuring unit 131b for receiving the coupler 131a and the RF signal extracted from the coupler 131a to measure the level of the RF signal applied from the base station 10.

The first amplifier 133 amplifies and outputs an RF signal applied from the base station 10 through the coupler 131a.

The attenuator 135 attenuates and outputs the RF signal output from the first amplifier 133 by using the attenuation value adjusted according to the level of the RF signal applied from the signal measuring unit 131b.

The second amplifier 137 amplifies and outputs an RF signal applied from the attenuator 135.

The pre / optical converter 139 converts the RF signal applied from the second amplifier 137 into an optical signal and outputs the converted optical signal.

The above-mentioned all-optical converter 139 is preferably implemented by a laser diode LD, converts an RF signal applied from the second amplifier 137 into an optical signal, and converts an inherent wavelength into the converted optical signal. Each is carried differently to the CWDM multiplexer / demultiplexer 120.

The reverse processor 140 includes an opto-electric converter 141, a first amplifier 143, an attenuator 145, a BPF 147, and a second amplifier 149.

In such a configuration, the photoelectric converter 141 converts the optical signal applied from the CWDM multiplexer / demultiplexer 120 into an RF signal and outputs the converted RF signal.

As described above, the photoelectric converter 141 is preferably implemented with a photodiode (PD), and converts an optical signal having a unique wavelength applied from the CWDM multiplexer / demultiplexer 120 into an RF signal to convert the first signal into an RF signal. Forward to 143.

The first amplifier 143 amplifies and outputs an RF signal applied from the photoelectric converter 141.

The attenuator 145 attenuates and outputs the RF signal output from the first amplifier 143.

The BPF 147 outputs only an RF signal of a desired frequency band among the RF signals applied from the attenuator 145.

The second amplifier 149 amplifies an RF signal applied from the BPF 147 and outputs the amplified RF signal to the base station 10.

Meanwhile, as illustrated in FIG. 4, the remote 200 separates an optical signal received from the donor 100 through one optical line and transmits the optical signal to each optical transmission / reception processing unit 210, and a plurality of optical transmission / reception processing units. CWDM multiplexer / demultiplexer 220 which combines the optical signal output from 210 into one signal and transmits it to donor 100 via one optical line, and from donor 100 through CWDM multiplexer / demultiplexer 220. The received optical signal is converted into an RF signal and applied to the donor side optical line sharing device 300, and the RF signal is applied from the donor side optical line sharing device 300 to convert the RF signal into an optical signal using different wavelengths. It includes a plurality of optical transmission and reception processing unit 210 to convert and transmit to the donor 100 through the CWDM multiplexer / demultiplexer 220.

As illustrated in FIG. 5, each optical transmission / reception processor 210 converts an optical signal received from the donor 100 into an RF signal and transmits the RF signal to the donor side optical line sharing device 300 or to the base station 20. A forward processor 230 for transmitting and a reverse processor 240 for converting an RF signal received from the donor side optical line sharing device 300 into an optical signal and transmitting the optical signal to the donor 100 are provided. 230 includes an opto-electric converter 231, a first amplifier 233, an attenuator 235, and a second amplifier 237.

In such a configuration, the opto-electric converter 231 converts an optical signal applied from the CWDM multiplexer / demultiplexer 220 into an RF signal and outputs the RF signal.

As described above, the photoelectric converter 231 is preferably implemented by a photodiode (PD), and converts an optical signal having a unique wavelength applied from the CWDM multiplexer / demultiplexer 220 into an RF signal to convert the optical signal into an RF signal. Forward to (233).

The first amplifier 233 amplifies and outputs an RF signal applied from the photoelectric converter 231.

The attenuator 235 attenuates and outputs the RF signal output from the first amplifier 233.

The second amplifier 237 amplifies the RF signal applied from the attenuator 235 and outputs the amplified RF signal to the donor side optical line sharing device 300.

The reverse processor 240 includes an attenuator 241, an amplifier 243, and a pre / optical converter 245.

In such a configuration, the attenuator 241 attenuates and outputs the RF signal applied from the donor side optical line sharing device 300.

The amplifier 243 amplifies and outputs an RF signal applied from the attenuator 241.

The pre / optical converter 245 converts the RF signal applied from the amplifier 243 into an optical signal and outputs the converted optical signal.

As described above, the all-optical converter 245 is preferably implemented by a laser diode LD, and converts an RF signal applied from the amplifier 243 into an optical signal and different wavelengths unique to the converted optical signal. It delivers to the CWDM multiplexer / demultiplexer 220.

Meanwhile, the donor side optical line which multiplexes the optical signal received from the remote 200 and the optical signal received from the base station 20 and transmits the multiplexed optical signal to the remote side optical line sharing device 400 located in the repeater through one optical line. The sharing device 300 is configured as shown in FIG. 6, converts an optical signal received from the remote 200 into an RF signal through an optical / pre conversion unit, and converts the converted RF signal into an appropriate signal through the RF matching unit. After amplification, the light signal is converted into an optical signal through an all-optical conversion unit and output to the optical line.

The optical transmission system through the heterogeneous base station of the present invention is not limited to the above-described embodiment, and can be implemented in various modifications within the range allowed by the technical idea of the present invention.

According to the present invention, when the base stations of different networks are installed in different locations, the CWDM multiplexer uses RF signals of different sectors pre- and optically converted using different optical wavelengths in donors installed in the base stations of the first mobile communication network. And transmits the RF signal of the first mobile communication network and the RF signal output from the base station of the second mobile communication network received through the remote to the remote installed in the base station of the second mobile communication network through one optical line. By sharing in the optical line sharing device installed in the base station and transmitting to each repeater, it is possible to increase the optical line utilization, and to reduce the installation cost, operating cost and line rental cost.

1 and 2 are views showing the configuration of an optical transmission system according to the prior art.

3 to 5 are views showing the configuration of an optical transmission system through a heterogeneous base station according to an embodiment of the present invention.

6 is an exemplary view schematically showing a configuration of an optical line sharing device applied to the present invention.

*** Explanation of symbols for the main parts of the drawing ***

10, 20. base station, 100. donor,

110, 210. Optical transmission / reception processing unit, 120, 220. CWDM multiplexer / demultiplexer,

130, 230. Forward processing unit, 131. Signal level measuring unit,

133, 143, 233. First amplifier, 135, 145, 235, 241. Attenuator,

137, 149, 237. Secondary amplifier, 139, 245. Electro-optical converter,

140, 240. Reverse processing section, 141, 231. Opto-electric converter,

147, BPF, 200. Remote,

243. Amplifier, 300. Donor side optical line sharing device,

400. Remote optical line sharing device

Claims (6)

When the base station of the first mobile communication network and the base station of the second mobile communication network are not in the same position and are separated from each other by a predetermined distance or more, Installed in the base station of the first mobile communication network, converts a plurality of RF signals received from the base station of the first mobile communication network into optical signals using different wavelengths, and multiplexes them and outputs them through one optical line A donor for demultiplexing the optical signal received through the optical line, separating the optical signal into a plurality of optical signals, and converting the separated optical signals into RF signals and applying them to the base station of the first mobile communication network; It is installed in the base station of the second mobile communication network, receives the optical signal output from the donor through the optical line and separates into a plurality of optical signals through demultiplexing, and then convert each separated optical signal into an RF signal A remote unit for outputting and converting a plurality of RF signals received from the outside into optical signals using different wavelengths, and then multiplexing them and transmitting them to the donor through one optical line; Optical donor module for converting and outputting a plurality of RF signals output from the remote to the optical signal and the optical donor module for converting and outputting a plurality of RF signals output from the base station of the second mobile communication network to the optical signal The signal is multiplexed and transmitted to the optical line sharing device installed on the repeater side through one optical line, and the optical signal received from the optical line sharing device installed on the repeater side is demultiplexed to provide the optical signal and the second signal of the first mobile communication network. Optical transmission system through a heterogeneous base station comprising an optical line sharing device for separating into an optical signal of a mobile communication network. The method of claim 1, wherein the donor is, The base station of the first mobile communication network receives a plurality of RF signals applied from the base station of the first mobile communication network and converts the received optical signals into optical signals using different wavelengths, and converts each input optical signal into an RF signal. A plurality of optical transmission / reception processing units for applying to the network; The optical signals output from the plurality of optical transceivers are combined into one signal and transmitted to the remote through the optical line, and the optical signals received from the remote through the optical line are separated into a plurality of optical signals, respectively. Optical transmission system through a heterogeneous base station comprising a CWDM multiplexer / demultiplexer input to the optical transmission and reception processing unit. According to claim 2, wherein each of the optical transmission and reception processing unit, A forward processor for converting an RF signal received from a base station of the first mobile communication network into an optical signal using different wavelengths and applying the same to the CWDM multiplexer / demultiplexer; A reverse processing unit converting an optical signal received from the CWDM multiplexer / demultiplexer into an RF signal and applying it to a base station of the first mobile communication network; The forward processor may further include a first amplifier for amplifying an RF signal received from a base station of the first mobile communication network, an attenuator for attenuating an RF signal output from the first amplifier, and amplifying an RF signal applied from the attenuator. And a second amplifier and an all-optical converter for converting the RF signal applied from the second amplifier into an optical signal and outputting the optical signal. The reverse processor may include an optical / electric converter for converting an optical signal received from the CWDM multiplexer / demultiplexer into an RF signal, a first amplifier for amplifying an RF signal applied from the optical / electric converter, and the first amplifier from the first amplifier. An attenuator for attenuating the applied RF signal, a filter for passing only an RF signal of a desired frequency band among the RF signals applied from the attenuator, and amplifying the RF signal applied from the filter to a base station of the first mobile communication network Optical transmission system through a heterogeneous base station comprising a second amplifier for outputting. The method of claim 1, wherein the remote, A plurality of RF signals applied from the optical line sharing device are respectively received and converted into optical signals using different wavelengths, and each of the input optical signals is converted into RF signals and applied to the optical line sharing devices. Two optical transmission and reception processing units; The optical signals output from the plurality of optical transceivers are combined into one signal and transmitted to the donor through the optical line, and the optical signals received from the donor through the optical line are separated into a plurality of optical signals, respectively. Optical transmission system through a heterogeneous base station comprising a CWDM multiplexer / demultiplexer input to the optical transmission and reception processing unit. According to claim 4, wherein each of the optical transmission and reception processing unit, A forward processing unit converting an optical signal received from the CWDM multiplexer / demultiplexer into an RF signal and applying the same to the optical line sharing device; It is provided with a reverse processing unit for converting the RF signal received from the optical line sharing device to the optical signal using different wavelengths to apply to the CWDM multiplexer / demultiplexer, The forward processor may include an optical / electric converter for converting an optical signal applied from the CWDM multiplexer / demultiplexer into an RF signal, a first amplifier for amplifying an RF signal applied from the optical / electric converter, and the first amplifier from the first amplifier. An attenuator for attenuating the applied RF signal, and a second amplifier for amplifying the RF signal received from the attenuator and outputting the amplified RF signal to the optical line sharing device, The reverse processor may include an attenuator for attenuating the RF signal received from the optical line sharing device, an amplifier for amplifying the RF signal applied from the attenuator, and an amplifier for converting the RF signal applied from the amplifier into an optical signal and outputting the optical signal. Optical transmission system via a heterogeneous base station comprising a / optical converter. delete

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