KR100651488B1 - Wavelength division multiplexing passive optical network - Google Patents

Abstract

The optical subscriber network of the wavelength division multiplexing method according to the present invention multiplexes the wired first downlink optical signals and the wireless second downlink optical signals, and demultiplexes and detects the multiplexed first uplink and second uplink optical signals. A decentralized first and second downlink optical signals connected to the central base station and the central base station through an optical fiber and multiplexed to output the first and second uplink optical signals to the central base station; A plurality of subscribers connected to a local base station and the local base station, respectively, for receiving a first downlink optical signal having a corresponding wavelength among the demultiplexed first downlink optical signals and generating a first uplink optical signal; A plurality of second downlink optical signals of a corresponding wavelength among the demultiplexed second downlink optical signals, respectively, for receiving the second downlink optical signal and generating the second uplink optical signal And a plurality of wireless relay stations and a plurality of wired / wireless integrated subscribers connected to said local base station, for receiving first and second downlink optical signals of a corresponding wavelength and for generating said first and second uplink optical signals.

Wavelength division, wireless, wired

Description

Wavelength Division Optical Subscriber Network {WAVELENGTH DIVISION MULTIPLEXING PASSIVE OPTICAL NETWORK}             

1 is a view showing the configuration of a passive optical subscriber network according to the prior art;

2 is a view showing the configuration of a passive optical subscriber network according to a preferred embodiment of the present invention;

3 is a graph for explaining a relationship between wavelength bands used in the passive optical subscriber network shown in FIG.

The present invention relates to a passive optical subscriber network, and more particularly to a passive optical subscriber network capable of wireless communication.

The wavelength division multiplexing method provides a unique wavelength to each of a plurality of subscribers, thereby providing a high-speed broadband communication service to the subscribers, and by assigning a unique wavelength to each subscriber, an optical communication that maintains communication security and facilitates line expansion. That's how it is.

In particular, the wavelength division multiplexing passive optical subscriber network has a central base station providing a service, a subscriber receiving the service, and a local base station located at a location adjacent to each of the subscribers between the subscribers and the central base station. It is easy to bury and maintain the optical path.

1 is a view showing the configuration of a passive optical subscriber network according to the prior art. Referring to FIG. 1, a conventional passive optical subscriber network 100 includes a central base station 110 for providing wired service, broadcast service, and high-speed Internet service, and an area linked by the central base station 110 and a single optical fiber. And a plurality of subscribers 130 connected to the base station 120 and the local base station 120, respectively, and receiving communication services from the central base station 110.

The passive optical subscriber network 100 described above is linked between the central base station 110 and the local base station 120 by a single independent optical fiber, so that the cost required for installation from the central base station 110 to each of the subscribers 130 is established. Can be minimized.

The central base station 110 detects a plurality of downlink light sources 111 for generating respective downlink optical signals for providing to each subscriber 130 and uplink optical signals received from the respective subscribers 130. The plurality of uplink photodetectors 113 and the downlink optical signals are multiplexed and output to the local base station 120, and the multiplexed uplink optical signals are demultiplexed and output to the uplink photodetector 113. Multiplexer / demultiplexer 114. Each downward light source 111 and each upward photodetector 113 are connected to the multiplexer / demultiplexer 114 by a wavelength selective combiner 112.

That is, the central base station 110 generates the above-described PSTN wired data, broadcast, and high-speed Internet data into respective downlink optical signals carried on light of a wavelength allocated to each subscriber 130, and generates the downlink optical signals. The signals are multiplexed and output to the local base station 120.

The local base station 120 demultiplexes the multiplexed downlink optical signals and outputs the demultiplexed downlink optical signals to the corresponding subscriber 130, and multiplexes the uplink optical signals received from the subscribers 130 to the central base station 110. .

Each of the subscribers 130 includes a downward photodetector 131 for detecting a downlink optical signal, an upward light source 132 for generating an upward optical signal, the downward photodetector 131, and the upward light source 132. ) And a wavelength selective combiner 133 for connecting the local base station 120 to the local base station 120.

Each subscriber 130 detects the downlink optical signal received from the local base station 120 through the corresponding home appliance. For example, a voice signal can be detected through a telephone or the like, and an internet signal can be detected through a computer or the like. Other broadcast signals can be received via a television or the like.

However, the passive optical subscriber network has a problem in that it provides only subscribers with limited mobility services such as high speed internet, telephone, and broadband television.

 It is an object of the present invention to provide a passive optical subscriber network capable of providing a broadband wireless access service with mobility.

Passive optical subscriber network according to the present invention,

 A central base station for multiplexing the wired first optical signals and the wireless second optical signals;

A local base station connected to the central base station through an optical fiber and configured to demultiplex multiplexed optical signals received from the central base station;

A plurality of subscribers connected to the local base station and configured to receive a first optical signal of a corresponding wavelength among the demultiplexed first optical signals, respectively;

A plurality of wireless relay stations connected to the local base station and configured to wirelessly transmit the converted wireless electrical signal by converting a second optical signal having a corresponding wavelength among the demultiplexed second optical signals into a wireless electrical signal;

A plurality of wireless relay stations connected to the local base station and configured to wirelessly transmit the converted wireless electrical signal by converting a second optical signal having a corresponding wavelength among the demultiplexed second optical signals into a wireless electrical signal;

And a plurality of wired / wireless integrated subscribers connected to the local base station and receiving the second optical signal of the wavelength and the first optical signal of the wavelength.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention; In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

2 is a view showing the configuration of a passive optical subscriber network according to a preferred embodiment of the present invention. 2, a passive optical subscriber network 200 according to a preferred embodiment of the present invention includes a central base station 210 for generating wired first downlink optical signals and wireless second downlink optical signals; Subscribers 250, a plurality of wireless relay stations 260, a plurality of wired and wireless integrated subscribers 240 for generating first and second uplink optical signals, and the central base station 210 with a single optical fiber And includes a regional base station 230 linked by. The local base station 230 may include an optical waveguide grating.

The central base station 210 includes a first multiplexer / demultiplexer 211 and a plurality of optical transmission / reception modules 220-1 to 220-n.

The first multiplexer / demultiplexer 211 multiplexes the first and second downlink optical signals to the local base station 230 and outputs the first and second uplink optical multiplexed at the local base station 230. Demultiplex the signals.

Each of the optical transceiver modules 220-1 to 220-n includes first and second downward light sources 222 to 221-n, and 224-1 to 224-n, and first and second upward photodetectors 221-. 1 to 221-n, 223-1 to 223-n, first wavelength selective couplers 227 to 227-n, circulators 225-1 to 225-n, and second wavelength selective coupler 226 226-n).

The first downward light sources 224-1 to 224-n generate the first downward optical signal, and the second downward light sources 222-1 to 222-n generate the second downward optical signal. The first and second downward light sources may include a semiconductor light source and the like, wherein the first optical signal is used for wired transmission and the second optical signal is used for wireless transmission.

The first upward photodetectors 223-1 to 223-n detect the first upward optical signal, and the second upward photodetectors 221-1 to 221-n detect the second upward optical signal. . The first and second upward photodetectors 223-1 to 223-n and 221-1 to 221-n may include light-receivable elements such as photodiodes.

The first wavelength selective combiner 227 ˜ 227-n may perform the first multiplexing on the first downward light sources 224-1 ˜ 224-n and the first upward photodetectors 223-1 ˜ 223-n. It is connected to the demultiplexer 211.

The circulators 225-1 to 225-n output the second uplink optical signal received from the first multiplexer / demultiplexer 211 to the second uplink photodetectors 221-1 to 221-n. The second downlink optical signal is output to the first multiplexer / demultiplexer 211.

The second wavelength selective coupler 226 ˜ 226-n is positioned between the first wavelength selective coupler 227 ˜ 227-n and the first multiplexer / demultiplexer 211, and the circulator 225-nd. 1 to 225-n).

Each of the subscribers 250 includes a first downlink photodetector 252 for detecting a first downlink optical signal having a corresponding wavelength among the first and second downlink optical signals demultiplexed by the local base station 230. A first upward light source 253 for generating the first upward optical signal of a corresponding wavelength, and the first upward light source 253 and the first downward light detector 252 to the local base station 230. And a third wavelength selective coupler 251 to make it. That is, each of the subscribers 250 is connected to the local base station 230 and receives the first downlink optical signal having a corresponding wavelength among the demultiplexed first downlink optical signals and generates a first uplink optical signal. .

Each of the wireless relay stations 260 may include a first field absorption type optical modulator 262 (EAM) for converting the second downlink optical signal of a corresponding wavelength demultiplexed by the local base station 230 into a downlink wireless electric signal; An antenna 261 for wirelessly transmitting the wireless electrical signal, and a fourth wavelength selective combiner 263 for connecting the first field absorption type optical modulator 262 to the local base station 230. That is, each of the wireless relay stations 260 is connected to the local base station 230, and receives a second downlink optical signal of a corresponding wavelength among the demultiplexed second downlink optical signals, respectively, and receives the second uplink optical signal. Create

Each of the wired / wireless integrated subscribers 240 may detect a first downlink optical signal of a corresponding wavelength among the first and second downlink optical signals demultiplexed by the local base station 230. ), A second upward light source 245 for generating the first upward optical signal of a corresponding wavelength, and the second upward light source 245 and the second downward light detector 244 for the local base station 230. A fifth wavelength selective combiner 242 for coupling to a second antenna, a remote antenna unit 243 for wirelessly transmitting the second downlink optical signal, and connecting the remote antenna unit 243 to the local base station 230. And a sixth wavelength selective coupler 241 for the same.

The remote antenna unit 243 may include a second field absorption type optical modulator 243b for converting the second downlink optical signal of a corresponding wavelength demultiplexed by the local base station 230 into a downlink wireless electric signal; An antenna 243a for wirelessly transmitting wireless electrical signals. The remote antenna unit 243 is used for communication with portable wireless devices located within that range.

3 is a graph for explaining a relationship between wavelength bands used in the passive optical subscriber network shown in FIG. Referring to FIG. 3, the first downward and second downward optical signals and the first upward and second upward optical signals use different wavelength bands. That is, the respective optical signals are branched to each path by the wavelength selective combiner or the like and transmitted to the corresponding position.

The passive optical subscriber network according to the present invention can simultaneously provide mobile broadband wireless communication service and wired service, and can provide wired / wireless integrated service to subscribers. Furthermore, the passive optical subscriber network according to the present invention can implement a quadruple play service (QPS) required in the digital convergence era.

Claims (8)

In the optical subscriber network of the wavelength division multiplexing scheme, A central base station for multiplexing the wired first downlink optical signals and the wireless second downlink optical signals and demultiplexing and detecting the multiplexed first uplink and second uplink optical signals; A local base station connected to the central base station through an optical fiber and demultiplexed the multiplexed first and second downlink optical signals, and multiplexing the first and second uplink optical signals to output to the central base station; A plurality of subscribers connected to the local base station and configured to receive a first downlink optical signal having a corresponding wavelength among the demultiplexed first downlink optical signals and to generate a first uplink optical signal; A plurality of wireless relay stations connected to the local base station, each receiving a second downlink optical signal having a corresponding wavelength among the demultiplexed second downlink optical signals and generating the second uplink optical signal; A plurality of wired / wireless integrated subscribers connected to the local base station and receiving first and second downlink optical signals of a corresponding wavelength and generating the first and second uplink optical signals. Optical subscriber network. The method of claim 1, wherein the central base station, A first multiplexer / demultiplexer for multiplexing the first and second downlink optical signals to output to the local base station and demultiplexing the multiplexed first and second uplink optical signals; And a plurality of optical transmission / reception modules for detecting the demultiplexed first and second uplink optical signals, generating the first and second downlink optical signals, and outputting the first and second downlink optical signals to the first multiplexer / demultiplexer. An optical subscriber network of a wavelength division method. According to claim 2, wherein each optical transmission module, A first down light source for generating the first down light signal; A second downward light source for generating the second downward optical signal; A first upward photodetector for detecting the first upward optical signal; A second upward photodetector for detecting the second upward optical signal; A first wavelength selective combiner for coupling the first downward light source and the first upward photodetector to the first multiplexer / demultiplexer; A circulator for outputting the second uplink optical signal received from the first multiplexer / demultiplexer to the second uplink photodetector and outputting the second downlink optical signal to the first multiplexer / demultiplexer; And a second wavelength selective coupler located between the first wavelength selective coupler and the first multiplexer / demultiplexer and coupled to the circulator. According to claim 1, And the local base station includes an optical waveguide grating. The method of claim 1, wherein each subscriber: A first downlink photodetector for detecting a first downlink optical signal of a corresponding wavelength among the first and second downlink optical signals multiplexed at the local base station; A first upward light source for generating the first upward optical signal of a corresponding wavelength; And a third wavelength selective coupler for coupling the first upstream light source and the first downside photodetector to the local base station. The method of claim 1, wherein each radio relay station, A first field absorption type optical modulator for converting the second downlink optical signal having a corresponding wavelength demultiplexed by the local base station into a downlink wireless electric signal; An antenna for wirelessly transmitting the wireless electrical signal; And a fourth wavelength selective coupler for connecting the first field absorption type optical modulator with the local base station. According to claim 1, wherein each wired and wireless integrated subscriber, A second downlink photodetector for detecting a first downlink optical signal of a corresponding wavelength among the first and second downlink optical signals multiplexed at the local base station; A second upward light source for generating the first upward optical signal of a corresponding wavelength; A fifth wavelength selective combiner for coupling the second upward light source and the second downward photodetector to the local base station; A remote antenna unit for wirelessly transmitting the second downlink optical signal; And a sixth wavelength selective combiner located between the fifth wavelength selective coupler and the local base station, for coupling the remote antenna unit with the local base station. The method of claim 7, wherein the remote antenna unit, A second field absorption type optical modulator for converting the second downlink optical signal of a corresponding wavelength demultiplexed in the local base station into a downlink wireless electric signal; And an antenna for wirelessly transmitting the wireless electrical signal.

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