KR20110078019A - Lightpath establishment apparatus and wavelength division multiplexing passive optical network system for the same - Google Patents

Abstract

PURPOSE: An optical path setting apparatus and a WDM-PON(Wavelength Division Multiplexing Passive Optical Network) system therefor are provided to reduce a number of required optical devices. CONSTITUTION: A broadband optical source(11) outputs optical signals from a downstream channel and an upstream channel. An optical circulator(12) transmits the optical signal of the downstream channel and the upstream channel that include multiple wavelengths from the broadband optical source by using a rotation phenomenon of a signal. An interleaver(13) performs a channel interleaving in the downstream channel and the upstream channel from the optical circulator.

Description

LIGHTPATH ESTABLISHMENT APPARATUS AND WAVELENGTH DIVISION MULTIPLEXING PASSIVE OPTICAL NETWORK SYSTEM FOR THE SAME}

The present invention relates to a wavelength division multiplexing passive optical network (WDM-PON), and more particularly, to an optical path setting device that can improve transmission quality and transmission distance by minimizing optical loss. .

Recently, various data services including the Internet are rapidly increasing, and the appearance of various multimedia services such as high definition (HD) -class digital broadcasting, high-quality on-demand audio and video, video conferencing, telemedicine, and distance education are rapidly increasing. have. In addition, with the development of home network technology, the demand for more convenient home network is increasing according to consumer's demand for various high quality high quality multimedia services and consumer's awareness of convenience of home network.

In order to satisfy this problem, the communication bandwidth per subscriber that must be provided by the subscriber network is increasing at a rapid rate, and a broadband subscriber network (BcN) is being established. Therefore, unlike the existing ADSL or VDSL, there is a need for a new optical subscriber network considering the limitation of transmission distance and the transmission speed that can be stably provided per subscriber. Such optical subscriber networks are classified into active optical network (AON) and passive optical network (PON) technologies, which are again divided into time division (TDM) and wavelength division (WDM) methods. Can be broken down into

A wavelength division multiplexing optical transmission apparatus using wavelength locking injects a narrow band of non-coherent light into a Febry-Perot laser diode from the outside, thereby injecting light among several oscillation modes of the Fabry-Perot laser diode. By suppressing modes with different wavelengths and fixing the output wavelength of the Fabry-Perot laser diode to the same wavelength as the injected light, a new light source can be used for the wavelength division multiplex optical transmission device. In particular, it is characterized by economically generating a plurality of wavelength division multiplexed light sources by using one non-coherent light source by spectral division.

In the wavelength division multiplex optical transmission apparatus, each channel connecting the transmitter and the receiver is distinguished by the wavelength of the light source. Therefore, the light source providing the output at a specific wavelength is a key element of the wavelength division multiplex optical transmission device. The light source used in the wavelength division multiplex optical transmission device must have a stable output wavelength and have a large side mode suppression ratio (SMSR) to minimize crosstalk with adjacent channels. In addition, the output power should be large, and the line width should be small to minimize the effects of color dispersion.

WDM-PON (WDM-PON) is considered as the ultimate broadband subscriber network because of its advantages such as large bandwidth, high security, easy scalability, and transmission speed and protocol transparency.

WDM-PON (WDM-PON), which can extend the transmission capacity by simultaneously using several wavelengths in one optical fiber, is a central office (CO), optical subscribers, and a central office (CO). And an optical distribution network connecting each optical subscriber. The central management office (CO) corresponds to the bureau within the telephone office or the operating station of the MSO (Multi System Operator), and provides the necessary information to subscribers through interworking with external wired and wireless networks through OLT (Optical Line Termination), and maintains the entire subscriber network. It plays an overall role in maintenance, surveillance control and operation. The optical distribution network is composed of a local node (RN) and an optical cable, which are composed of passive optical elements such as a wavelength division optical multiplexer / demultiplexer and an optical splitter for splitting an optical signal without power supply. The RN is located outside of the subscriber (electric pole, outdoor terminal box) or in a manhole or building. ONT (Optical Network Termination) is located in the subscriber's home, the subscriber terminal is connected thereto. The wavelength division multiplexed optical signal is transmitted between the central management station (CO) and the local node (RN) through one optical cable, and a specific wavelength per optical subscriber is allocated by the local node (RN). Wavelength division multiplexing passive optical subscriber networks require multiple light sources of different wavelengths to allocate one or more wavelengths per subscriber.

In wavelength-division multiplex passive passive subscriber network, natural emission light (e.g., the downward signal from the central office to the optical subscriber is the B-band natural emission light, and the upward signal from the photo subscriber side to the central office is the A-band natural emission light). The loss in the injection should be minimized. In addition, the optical loss experienced until the signal transmitted from the optical transmitter reaches the optical receiver greatly affects the transmission quality or scalability. Therefore, it is necessary to set an optimal optical path for minimizing optical loss, and in particular, by reducing the number of optical elements required (minimum network elements), the optical communication cost is reduced and the volume is reduced. There should be no loss of communication quality, and further improvement of communication quality should be made.

An object of the present invention is to minimize the optical loss, by reducing the number of optical elements required (minimum network elements used), an optical path setting device that can improve the communication quality while having advantages such as optical communication cost reduction and volume reduction And a wavelength division multiple access passive optical subscriber network (WDM-PON) system for the same.

According to an aspect of the present invention, an optical path setting device capable of improving communication quality and a wavelength division multiplex passive optical subscriber network (WDM-PON) system therefor are disclosed. The routing apparatus of the present invention separates an optical signal into channels and interleaves between transmission and reception channels. The three-terminal optical path setting device includes a broadband light source for outputting uplink and downlink optical signals, and a rotation phenomenon of signals for uplink and downlink optical signals including a plurality of optical wavelengths output from the broadband light source. And an interleaver for channel interleaving and outputting uplink and downlink optical signals output from the optical circulator, and outputting downlink optical signals input from the broadband light source to the first terminal. Output to the second terminal to provide the injection light source to the central management station (CO) side, and outputs the optical signal of the upstream channel input from the broadband light source to the first terminal to the third terminal to provide to the injection light source of the local node (RN) And an uplink input to the third terminal by outputting an optical signal of a down channel input to the second terminal to the third terminal. A null optical signal is output to the second terminal.

In addition, the five-terminal optical path setting device, the first broadband light source for outputting the odd and even channel optical signals of the A-band down channel, and the odd and even channels of the B-band upstream channel to output optical signals First and second optical circulators for transmitting optical signals of uplink channels and downlink channels including a second broadband light source and a plurality of optical wavelengths output from the first and second broadband light sources by using a rotation of a signal; And channel interleaving the downlink optical signal output from the first optical circulator, the downlink optical signal input from the central management station (CO), and the uplink optical signal output from the second optical circulator. From the interleaver, the downlink optical signal output from the first optical circulator, the uplink optical signal output from the second optical circulator, and the local node RN. And a filter for band-filtering the optical signal of the upstream channel, wherein the odd- and even-channel optical signals of the A-band downlink channel, which are input from the first broadband light source to the first terminal, to the second and third terminals. Outputs the divided channels and provides them to the first and second injection light sources on the central management station (CO) side. The optical signals of the odd and even channels of the B-band uplink channel input from the second broadband light source to the fourth terminal are output. It outputs to the terminal 5 to the injection light source of the local node (RN), and outputs the optical signal of the odd-channel and even-channel of the A-band downlink channel input to the second and third terminals to the terminal 5, The optical signals of odd and even channels of the B-band uplink channel input to the fifth terminal are divided into channels and output to the second and third terminals.

According to the present invention, while the prior art requires injection light sources of different bands for up-down light sources, one injection light source can be used, which not only reduces the device cost but also transmits / receives multiplex / demultiplexers. Since inter-channel interleaving is possible to reduce inter-channel interference, there is an advantage in that signal quality can be expected to be improved. In addition, by adjusting the filter bandwidth of the interleaver, it is possible to adjust the bandwidth of the injection light source or the signal used in wavelength multiplexing / demultiplexing, thereby improving signal quality and inter-signal interference.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions will not be described in detail if they obscure the subject matter of the present invention.

Prior to describing the WDM-PON 3-terminal or 5-terminal optical path setting device of the present invention, the WDM-PON 4-terminal light path setting device will be described with reference to FIG.

Referring to FIG. 1, the 4-terminal optical path setting device includes an optical multiplexer / demultiplexer 101, 106, an A-band optical circulator 103, and a B-band optical circulator that combine / separate A-bands and B-bands. 104. The A-band spontaneous emission light source 102 is a natural emission light for the downlink signal from the central office CO to the photon-side regional node RN, and the B-band spontaneous emission light source 105 is RN) is the natural emission light for upward signal from the central office (CO).

The 4-terminal optical path setting device outputs the A-band optical signal input to terminal 1 to terminal 3. Specifically, the A-band optical signal input to terminal 1 of the 4-terminal optical path setting device is output to terminal 3 through the A-band optical circulator 103 and the optical multiplexer / demultiplexer 106.

In addition, the four-terminal optical path setting device outputs the optical signal of the A-band input to the third terminal to the fourth terminal. Specifically, the A-band optical signal input to the third terminal of the 4-terminal optical path setting device includes the optical multiplex / demultiplexer 106, the A-band optical circulator 103, and the optical multiplex / demultiplexer 101. Pass through and output to terminal 4.

In addition, the 4-terminal optical path setting device outputs the optical signal of the B-band input to the second terminal to the fourth terminal. Specifically, the B-band optical signal input to the second terminal of the 4-terminal optical path setting device is output to the fourth terminal through the B-band optical circulator 104 and the optical multiplexer / demultiplexer 101.

In addition, the 4-terminal optical path setting device outputs the optical signal of the B-band input to the fourth terminal to the third terminal. Specifically, the B-band optical signal inputted to terminal 4 of the 4-terminal optical path setting device includes the optical multiplexer / demultiplexer 101, the B-band optical circulator 104, and the optical multiplexer / demultiplexer 106. Pass through and output to terminal 3.

Having such a configuration causes problems such as an increase in device cost, an increase in volume, and a complexity of the configuration due to a complicated configuration.

2 is a diagram showing the configuration of a three-terminal optical path setting device according to an embodiment of the present invention.

In the optical path setting apparatus of the present invention, an interleaver for separating and filtering an optical signal input for interleaving of channels into different terminals according to channels (uplink channel and downlink channel) is used. In the embodiment, a 2x2 interleaver 13 is used.

The characteristic of the 2x2 interleaver 13 is that when the light of the odd channel (e.g., uplink channel) and the even channel (e.g., down channel) is input to port 1 as shown in FIG. Outputs port 1 and outputs even channel light through port 4. In addition, when light of an odd channel (for example, an uplink channel) and an even channel (for example, a downlink channel) is input to port 2, the light of the odd channel is output to port 4, and the light of the even channel is output to port 3. In addition, when light of odd channel (for example, upstream channel) and even channel (for example, downlink channel) is input to port 3, light of odd channel is output to port 1, and light of even channel is output to port 2. In addition, when light of an odd channel (for example, an uplink channel) and an even channel (for example, a downlink channel) is input to port 4, light of an odd channel is output to port 2, and light of an even channel is output to port 1. Hereinafter, it is assumed that the downlink channel output from the CO side is set to the odd channel, and the uplink channel output from the RN side is set to the even channel. However, the present invention is not limited thereto, and it is also possible to set the downlink channel to the even channel and the uplink channel to the odd channel.

Using the 2x2 interleaver 13 having such characteristics, the 4-terminal optical path setting device is set to a three-terminal optical path including one circulator 12 and one 2x2 interleaver 13 as shown in FIG. You can configure the device.

Referring back to Figure 2, the three-terminal optical path setting apparatus according to the present invention, the broadband light source (BLS: Broadband Light Source) (BLS) 11 for outputting the uplink and downlink optical signals, output from the broadband light source 11 One three-port optical circulator 12 which transmits uplink and downlink optical signals including a plurality of optical wavelengths using a rotation phenomenon of the signal, and uplink and downlink output from the optical circulator 12. And a 2x2 interleaver 13 for channel interleaving and outputting the optical signals of the channel, and outputs the downlink optical signal input from the broadband light source 11 to the first terminal 201 to the second terminal 202. To provide the injection light source to the central management station (CO) side and output the optical signal of the upstream channel input from the broadband light source 11 to the first terminal 201 to the third terminal 203 to supply the injection light source to the local node RN side. And input to the second terminal 202. Outputs the optical signal of the downlink channel to the third terminal 203, and outputs the optical signal of the upstream channel that is input to the third terminal 203 to second terminal 202. The

In the first embodiment, the downlink channel is any one of an odd channel of the A-band, an odd channel of the B-band, an odd channel of the A-band and a B-band, and the uplink channel is an even channel of the A-band. Is an even channel of the B-band, an even channel of the A-band and the B-band.

In the second embodiment, the downlink channel is any one of an even channel of the A-band, an even channel of the B-band, an even channel of the A-band and a B-band, and the uplink channel is an odd channel of the A-band. , Odd-channel of B-band, odd-channel of A-band and B-band.

Internally, the first terminal 201 is a port 1 of the optical circulator 12, the second terminal 202 is connected to a port 3 of the 2 × 2 interleaver 13, and the third terminal 203 is connected. Has a structure connected to port 4 of the 2 × 2 interleaver 13. In addition, port 2 of the optical circulator 12 is connected to port 1 of the 2 × 2 interleaver 13, and port 3 of the optical circulator 12 is connected to port 2 of the 2 × 2 interleaver 13. It has a connected structure.

Here, the optical circulator 12 is a three-port optical circulator that operates simultaneously in the A-band and the B-band. The optical circulator 12 uses the signal rotation to move from port 1 to port 2 and from port 2 to port 3. It rotates with the direction of signal from port 3 to port 1.

The interleaver 13 is an element that separates into different ports according to the wavelength of the input signal (wavelength dividing function) and combines the wavelength of the input signal into the same port (wavelength combining function). In an embodiment, the 4-port 2x2 interleaver 13 outputs downlink optical signals to port 3 for the input of port 1 and uplink optical signals to port 4 for the input of port 1. Outputs the downlink optical signals to port 1 for the input of port 3, and outputs the uplink optical signals to port 1 for the input of port 4. Looking at the characteristics of the 4-port 2 × 2 interleaver 13, when the A-band, or B-band, or the uplink and downlink optical signals of the A-band and B-band are input to the port 1, the uplink channel And wavelength-dividing the down channel light, and outputs the down channel optical signal to port 3 and outputs the up channel optical signal to port 4. The downlink optical signal is used as the CO side injection light source, and the upstream optical signal is used as the RN side injection light source. In addition, when the downlink optical signal is input to port 3, the downlink optical signal is output to port 1. In addition, when the uplink optical signal is input to port 4, the uplink optical signal is output to port 1.

Externally, the first terminal 201 simultaneously outputs (generates the spectrum of the broadband) the A-band, the B-band, or the uplink and downlink optical signals of the A-band and the B-band simultaneously. It is connected to the light source (BLS) 11, the second terminal 202 is connected to the central management station (CO) side, the third terminal 203 has a structure connected to the local node (RN) side. Here, the broadband light source 11 is a non-intrusive and wide line width natural emission light source, Fabry-Perot laser, semiconductor rare earth addition optical fiber light source, rare earth addition optical waveguide light source, semiconductor optical amplifier light source, optical ratio of optical fiber One of the broadband light sources, such as the optical fiber light source using linearity, is used.

The operation of the three-terminal optical path setting device having the above configuration will be described in detail as follows.

The optical signal outputted from the A / B-band broadband light source 11 (the A-band, or the B-band, or the uplink and downlink optical signals of the A- and B-bands) is the optical circulator 12. To port 1 (first terminal 201 of the 3-terminal optical path setting device), and to port 1 of the 2x2 interleaver 13 via port 2 of the optical circulator 13. . At this time, the downlink (odd channel) optical signal input to port 1 of the 2x2 interleaver 13 is the second terminal 202 of the port 3 (3-terminal optical path setting device) of the 2x2 interleaver 13. )) Is used as the injection light source on the CO side, and the optical signal of the upstream channel (even channel) input to the port 1 of the 2x2 interleaver 13 is port 4 of the 2x2 interleaver 13 ( Output to the third terminal 203 of the three-terminal optical path setting device and used as the injection light source on the RN side.

In addition, the downlink optical signal transmitted from the CO side and the uplink signal transmitted from the RN side are respectively connected to port 3 (the second terminal 202 of the 3-terminal optical path setting device) of the 2 × 2 interleaver 13. It is input to port 4 (third terminal 203 of the 3-terminal optical path setting device), and is wavelength-coupled by the 2x2 interleaver 13 (the downlink optical signal is odd channel, and the uplink optical signal is Set to even channel) Output to port 1. Thereafter, the uplink and downlink optical signals input to the second port of the optical circulator 12 are input to the second port of the 2 × 2 interleaver 13 through the third port of the optical circulator 12. The wavelength is divided by the 2 × 2 interleaver 13 so that the downlink signal is transmitted to the RN through port 4, and the uplink signal is transmitted to the CO through port 3.

More specifically, as shown in Fig. 4A, the A-band, or B-band, or the down-channel light of the A-band and B-band output from the broadband light source (A / B-band BLS) 11 The signal 401 is inputted through port 1 and port 2 of the optical circulator 12 to port 1 of the 2 × 2 interleaver 13 (402) and output to port 3 (403). CO) is injected into the light source. In addition, the signal (A-band, or B-band, or the down-channel optical signal of A-band and B-band) output from the central management station (CO) side is routed to port 3 of the 2x2 interleaver 13. Input (404) and output to port 1 (405), passing through port 2 and port 3 of the optical circulator 12 (406), and port 2 and port 4 of the 2x2 interleaver 13 407 is transmitted to the local node (RN) side.

As shown in FIG. 4B, the optical signal 411 of the A-band, or B-band, or the up-channel of the A-band and B-band output from the broadband light source (A / B-band BLS) 11 Is inputted through port 1 and port 2 of the optical circulator 12 to port 1 of the 2 × 2 interleaver 13 (412) and output to port 4 (413). Is injected into. In addition, the signal (A-band, or B-band, or the downlink channel of the A-band and B-band) output from the local node RN side is connected to port 4 of the 2 × 2 interleaver 13. Input (414) and output to port 1 (415), passing through port 2 and 3 of the optical circulator 12 (416) port 2 and port 3 of the 2 × 2 interleaver 13 417 is transmitted to the central management station (CO) side.

5 is a diagram showing the configuration of a five-terminal optical path setting device according to an embodiment of the present invention.

In the optical path setting apparatus of the present invention, the optical signals input for interleaving of the channels are mutually divided according to channels (odd and even channels of the A-band downlink channel, odd and even channels of the B-band downlink channel). Use an interleaver to separate and filter to other terminals. In the embodiment, a 2x2 interleaver 55 is used. The interference of the signal can be prevented by dividing into odd and even channels of the up and down channels.

Referring to FIG. 3, the characteristics of the 2 × 2 interleaver 55 are described. When the odd and even channels of the B-band uplink channel or the A-band downlink channel are input to port 1, the odd-channel light is input. To port 3, and to output even channel light to port 4. In addition, when the odd channel and even channel light of the B-band uplink channel or the A-band down channel is input to port 2, the light of the odd channel is output to port 4, and the light of the even channel is output to port 3 do. In addition, when the odd channel and even channel light of the B-band uplink channel or the A-band down channel is input to port 3, the light of the odd channel is output to port 1, and the light of the even channel is output to port 2. do. In addition, when the odd channel and even channel light of the B-band uplink channel or the A-band down channel is input to port 4, the odd channel light is output to port 2, and the even channel light is output to port 1. do. It should be noted that the characteristics of the odd and even channels of the uplink channel or the downlink channel may be mutually changed.

Referring to FIG. 5, the configuration of the 5-terminal optical path setting apparatus includes an odd-channel (eg, 1,3,5,7,9 channels of 10 downlink channels) and an even channel (eg, 10 downlinks) of an A-band downlink channel. An A-band broadband light source 51 for outputting optical signals of 2, 4, 6, 8, and 10 channels, and an odd channel (for example, 1, 3, 5, of 10 upstream channels) of the B-band upstream channel; B-band broadband light source 52 for outputting optical signals of 7,9 channels) and even channels (e.g., 2,4,6,8,10 channels of 10 uplink channels), A-band and B-band broadband First and second optical circulators 53 and 54 which transmit uplink and downlink optical signals including a plurality of optical wavelengths output from the light sources 51 and 52 using a rotation phenomenon of the signal, and a first Downlink optical signals (that is, downlink odd and even channels) output from the optical circulator 53 and downlink channels input from the central management station (CO). Channel interleaving of optical signals (i.e., odd and odd channels of downlink channels) and uplink optical signals (i.e., odd and odd channels of upstream channels) output from second optical circulator 54 2x2 interleaver 55 and the downlink optical signal output from the first optical circulator 53 and the uplink optical signal and local node RN output from the second optical circulator 54 A filter 56 for band-filtering an optical signal of an uplink channel inputted from the A-band, and an odd- and even-numbered channel of an A-band downlink channel input from the A-band broadband light source 51 to the first terminal 501. And outputs the optical signal of the channel to the second and third terminals 502 and 503 to be output to the first and second injection light sources on the central management station (CO) side, and from the B-band broadband light source 52 to the fourth terminal 504. O-channel and odd-channel optical signals of B-band uplink channel Output to the 5 terminal 505 to provide the injection light source of the local node (RN) side, the 5 terminal to the odd- and odd-channel optical signal of the A-band down channel input to the second and third terminals (502, 503) And outputs the optical signals of the odd and even channels of the B-band upstream channel input to the fifth terminal 505 to the second and third terminals 502 and 503.

The first optical circulator 53 is a three-port optical circulator operating in the A-band, and using the rotation of the signal from port 1 to port 2, port 2 to port 3, port 3 Rotate with the direction of signal from port 1 to. In addition, the second optical circulator 54 is a three-port optical circulator operating in the B-band, using the rotation of the signal from port 1 to port 2, port 2 to port 3, port 3 Rotating from the port to port 1 with the direction of the signal.

Here, the first terminal 501 is a port 1 of the first optical circulator 53, and an A-band broadband light source (BLS) 51 for outputting optical signals of odd and even channels of the A-band downlink channel. Connected with In addition, the second terminal 502 is a port 3 of the 2 × 2 interleaver 55, and is connected to the first AWG on the side of the central management station (CO), and the third terminal 503 is connected to 4 of the 2 × 2 interleaver 55. Port 1, which is connected to the second AWG on the central management station (CO) side. In addition, the fourth terminal 504 is the first port of the second optical circulator 54, and the B-band broadband light source (BLS) 52 which outputs the odd and even channel optical signals of the B-band uplink channel. Connected with In addition, the fifth terminal 505 is a port 1 of the filter 56 and is connected to the local node RN side.

Port 2 of the first optical circulator 53 is connected to port 1 of the 2 × 2 interleaver 55, and port 3 of the first optical circulator 53 is connected to port 3 of the filter. . In addition, the second port of the second optical circulator 54 is connected to the second port of the filter 56, and the third port of the second optical circulator 54 is the second port of the 2 × 2 interleaver 55. It has a structure connected with

In particular, the interleaver 55 is a 4-port 2x2 interleaver that splits wavelengths and / or combines wavelengths according to the wavelength of an input signal. Outputs the signal and outputs the optical signal of the even channel of the A-band down channel to port 4 for the input of port 1, and the odd channel of the A-band down channel to the port 1 for the input of port 3. Outputs the optical signal and outputs the optical signal of the even channel of the B-band downstream channel to port 1 for the input of port 4, and the odd channel of the B-band upstream channel to the port 4 for the input of port 2. It outputs the optical signal of and outputs the optical signal of even channel of B-band upstream channel to port 3 with respect to input of port 2.

The operation of the 5-terminal optical path setting device having the above configuration will now be described in detail.

The A-band downlink optical signal output from the A-band broadband light source 51 is input to the first terminal (port 1 of the first optical circulator 53) 501 of the 5-terminal optical path setting device. The first optical circulator 53 is input to the first port of the 2 × 2 interleaver 55 via the second port. At this time, the optical signal of the odd channel (for example, 1,3,5,7,9 channel) of the downlink channel (for example, 10 channels) is the 3rd port (5 terminal optical path setting device) of the 2x2 interleaver 55. 2 terminal 502) is used as the injection light source of the odd-numbered channel of CO, the optical signal of the even channel (for example, 2, 4, 6, 8, 10 channel of the 10 down-channel) is 2 × 2 interleaver 55 Is output to port 4 (third terminal 503 of the 5-terminal optical path setting device) and used as an injection light source for an even channel of CO.

In addition, the optical signal of the B-band uplink channel output from the B-band broadband light source 52 is input to the fourth terminal (port 1 of the second optical circulator 54) 504 of the 5-terminal optical path setting device. Through the port 2 of the second optical circulator, and is input to the port 2 of the filter 56 which combines / separates the A-band and the B-band, and is output to the port 1 to be used as an injection light source on the RN side. do.

In addition, the downlink odd-numbered optical signal and the third terminal (2x2 interleaver 55) input to the second terminal (port 3 of the 2x2 interleaver 55) 502 of the 5-terminal optical path setting device. The optical signal of the even channel of the downlink channel inputted to port 4 of the port 503 is input to the port 2 of the first optical circulator 53 through the port 1 of the 2 × 2 interleaver 55, It is input through port 3 of the first optical circulator 53 to port 3 of the filter 56, output to port 1, and transmitted to the RN side.

In addition, the uplink optical signal input to the fifth terminal (port 1 of the filter 56) 505 of the 5-terminal optical path setting device passes through the port 2 of the filter 56, and the second optical circulator ( 54) is input through port 2 of the second optical circulator 54 through port 3 of the 2 x 2 interleaver 55, and the optical signal of the even channel of the uplink channel is 2 Port 3 of the x2 interleaver 55 (second terminal 502 of the 5-terminal optical path setting device) is output, and the optical signal of the odd channel of the upstream channel is port 4 of the 2x2 interleaver 55 ( Third terminal 503 of the 5-terminal optical path setting device).

Hereinafter, an example in which the three-terminal optical path setting device of FIG. 2 according to the present invention is applied to a wavelength division multiplex passive optical subscriber network system will be described.

As shown in FIG. 6, the odd-numbered optical signals (downlink optical signals) output from the A / B-band broadband light source (BLS) 11 are port 1 and port 2 of the optical circulator 12. It is input through the port 1 of the 2x2 interleaver 13, and is output through the port 3 and injected into the CO side light source. The downlink optical signal output from the CO side is input to port 3 of the 2 × 2 interleaver 13, and is output to port 1 through ports 2 and 3 of the optical circulator 12, and It is transmitted to the RN side through ports 2 and 4 of the x2 interleaver 13.

On the other hand, the even-numbered optical signal (uplink channel optical signal) output from the A / B-band broadband light source (BLS) 11 passes through the 1st and 2nd ports of the optical circulator 12 and is a 2x2 interleaver. Inputted to port 1 of (13), output to port 4 and injected into the light source of the RN side. The uplink optical signal output from the RN side is input to port 4 of the 2 × 2 interleaver 13, and is output to port 1 through ports 2 and 3 of the optical circulator 12, and It is transmitted to the CO side through ports 2 and 3 of the x2 interleaver 13.

The process of transmitting the optical signal of the odd channel (optical signal of the down channel) transmitted from the CO side and the optical signal of the even channel (optical signal of the upstream channel) transmitted from the RN side, respectively, of the interleaver 13 Ports 3 and 4 are input, and the wavelength is combined with the 2x2 interleaver 13 to be output to port 1. Optical signals of odd and even channels input to the second port of the optical circulator 12 are input to the second port of the 2x2 interleaver 13 through the third port of the optical circulator 12, The wavelength is separated (divided) by the 2x2 interleaver 13 so that signals of odd channels are transmitted to the RN side, and signals of even channels are transmitted to the CO side.

Meanwhile, in the wavelength division multiplexing passive optical subscriber network system of FIG. 6, an interleaver 71 may be added to the RN side multiplexer / demultiplexer as shown in FIG. 7.

Since the RN side subscriber unit ONT # n uses an odd channel (down channel) for reception and an even channel (upstream channel) for transmission, two optical lines are required for transmission and reception, respectively, as shown in FIG. Likewise, when the interleaver 71 is added in front of the RN side multiplexing / demultiplexing device, transmission and reception can transmit and receive through the same path. For example, the optical signal of channel 1 input to port 1 of the RN side interleaver 71 is output to port 3 of the interleaver 71, and the 2 × N multiplex / demultiplexer (AWG) of the RN side is output. It is input to the second input port and output to the second output port of the AWG. On the other hand, the optical signal of channel 2 input to the port 1 of the RN side interleaver 71 is output to the port 4 of the interleaver 71, and the number 1 of the 2 × N multiplex / demultiplexer (AWG) side of the RN side. Since it is input to the input port, it has the characteristic of being output to the second output port of the AWG like the first channel. Due to such an operation characteristic, two adjacent even / odd channels have the same optical path, and thus, optical transmission and reception can be performed through one optical line at the subscriber end.

Meanwhile, as shown in FIG. 8, a multiple / demultiplexer having a double channel spacing may be installed on the RN side. That is, by installing the 100G 32 channel multiplexer / demultiplexer 81 on the CO side and the 200G 16 channel multiplexer / demultiplexer 82 on the RN side, the configuration of the RN side multiplexer / demultiplexer 82 is achieved. Can be simplified.

The odd-numbered optical signal (the downlink optical signal) output from the broadband light source (BLS) 11 passes through the first and second ports of the optical circulator 12 and the first of the 2x2 interleaver 13. It is input to the port and output to port 3 and injected into the CO side light source. The optical signal of the odd channel output from the CO side is input to port 3 of the 2 × 2 interleaver 13, and is output to port 1 through port 2 and port 3 of the optical circulator 12, It is transmitted to the RN side through ports 2 and 4 of the x2 interleaver 13. At this time, the N-th odd channel optical signal inputted to the RN (the optical signal of the 2N-1th channel by combining both odd and even channels) has twice the channel spacing compared to the CO side multiplex / demultiplexer (AWG) 81. The branches are output on channel N of the RN side multiplex / demultiplexer (AWG) 82.

The even-numbered optical signal (uplink channel optical signal) output from the broadband light source (BLS) 11 passes through the first and second ports of the optical circulator 12 and the first of the 2x2 interleaver 13. Input through port, output through port 4, and injected into RN light source. At this time, the N-th even channel optical signal (the optical signal of the 2N-th channel combined with both odd and even channels) input to the RN has an RN having twice the channel spacing as compared to the CO side multiplex / demultiplexer (AWG) 81. It is output to channel N of the multiplex / demultiplexer (AWG) 82. The optical signal of the even channel output from the RN side is again input to port 4 of the 2 × 2 interleaver 13, and output to port 1 through ports 2 and 3 of the optical circulator 12, The port 2 and 3 of the 2x2 interleaver 13 are transmitted to the CO side.

In addition, since the optical signal of the odd channel output from the CO side and the optical signal of the even channel received are both transmitted to the same RN side transceiver, the subscriber equipment can transmit and receive with the CO side equipment through one optical path.

Now, an example in which the 5-terminal optical path setting device of FIG. 5 according to the present invention is applied to a wavelength division multiplex passive optical subscriber network system will be described. As shown in FIG. 9, two CO-side multiplexing / demultiplexing devices (AWGs) 91 and 92 are connected to the interleaver 55 of the 5-terminal optical path setting device.

The A-band optical signal output from the A-band broadband light source 51 is input to the first terminal (port 1 of the first optical circulator 53) of the 5-terminal optical path setting device, and the first optical circuit It is input to the port 1 of the 2x2 interleaver 55 via the port 2 of the radar 53. At this time, the optical signal of the odd channel is output to port 3 of the 2 × 2 interleaver 55 (the second terminal of the 5-terminal optical path setting device) and used as the injection light source of the odd channel of the CO side, and the optical signal of the even channel is It is output to port 4 of the 2x2 interleaver 55 (third terminal of the 5-terminal optical path setting device) and used as an injection light source of the even-side CO channel. In addition, the B-band optical signal output from the B-band wideband light source 52 is input to the fourth terminal (port 1 of the second optical circulator 54) of the 5-terminal optical path setting device, thereby providing a second optical signal. It is input to the second port of the filter 56 which combines / separates the A band and the B band via the second port of the curator 54, and is output to the first port to be used as an injection light source on the RN side. In addition, the odd-channel downlink optical signal input to the second terminal of the 5-terminal optical path setting device and the even-channel downlink optical signal input to the third terminal pass through the first port of the 2 × 2 interleaver 55, and the first optical circuit Port 2 of the radar 53 → port 3 of the first optical circulator 53 → port 3 of the A / B filter 56 → transmitted to the RN via port 1 of the A / B filter 56 do. In addition, the uplink optical signal inputted to the fifth terminal of the 5-terminal optical path setting device is port 2 of the A / B filter 56 → port 2 of the second optical circulator 54 → second optical circulator 54. Input port 2 of the 2 × 2 interleaver 55 via port 3 of the terminal), the uplink optical signal of the even channel is output to the second terminal of the 5-terminal optical path setting device, the uplink optical signal of the odd channel It is output to the 3rd terminal of a 5-terminal optical path setting device.

Through this, optical signals received on adjacent channels of the CO side multiplex / demultiplexer (AWG) 91 and 92 may be received across one channel to minimize crosstalk of adjacent channels.

On the other hand, it may be configured as shown in Figure 10a to configure a wavelength division multiplex passive optical subscriber network system. In the configuration of FIG. 9, since the CO side TX and RX communicating with one RN side subscriber unit are set to different AWGs and paths, both multiplexing / demultiplexing apparatuses (AWGs) should always be installed on the CO side. However, if the present configuration is applied, since both TX and RX are connected to one multiplex / demultiplexer (AWG) 91, one AWG 91 is installed on the CO side to enter the market at low cost, and the subscriber When the side line is increased, the CO side AWG 92 can be additionally installed as shown in FIG. 10B, and the initial cost can be reduced. In the configuration of Figs. 10A and 10B, an A / B filter 93 for coupling / separating the A-band and the B-band in front of the RN side multiplexing / demultiplexing apparatus (AGW) is provided.

In addition, as shown in FIG. 11, the wavelength division multiplexing passive optical subscriber network system may be configured. In the configuration of FIG. 9, the interleaver 55 is an A-band and a port 1 of the CO multiplex / demultiplexer 91 And the B-band to port 2 of the CO multiplexer / demultiplexer (AWG) 91, which not only enables transmission and reception on the same channel (one optical path), but without additional configuration on the RN side. Therefore, the loss of the entire network can be reduced.

In addition, as shown in FIG. 12, a broadband light source can be divided into two WDM-PONs using an interleaver. Thus, by distributing an injection source supplied to the WDM-PON through the interleaver, each WDM Adjacent channel interference of the PON can be minimized and device cost can be reduced because two injection light sources per band are shared by two WDM-PONs.

In addition, as shown in FIG. 13, a wavelength division multiplexing passive optical subscriber network system may be configured using one interleaver and two A / B filters.

Although the present invention has been described in connection with some embodiments thereof, it should be understood that various changes and modifications may be made therein without departing from the spirit and scope of the invention as understood by those skilled in the art. something to do. It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

1 is a diagram showing the configuration of a four-terminal optical path setting device.

Fig. 2 is a diagram showing the configuration of a three-terminal optical path setting device according to an embodiment of the present invention.

3 is a view showing operation characteristics of the 2x2 interleaver of FIG.

Figures 4a and 4b is a view showing the operation of the three-terminal optical path setting device according to an embodiment of the present invention.

Fig. 5 is a diagram showing the configuration of a 5-terminal optical path setting device according to an embodiment of the present invention.

6 to 13 are views showing the configuration of a wavelength division multiplex passive optical subscriber network system to which an optical path setting device according to an embodiment of the present invention is applied.

* Explanation of symbols for the main parts of the drawings

11: A / B band broadband light source 12,53,54: optical circulator

13,55: 2 × 2 interleaver 51: A-band broadband light source

52: B-band broadband light source 56: A / B filter

Claims (14)

As a light path setting device, Optical path setting device for separating the optical signal into channels and interleaving between transmission and reception channels. The method of claim 1, A broadband light source for outputting uplink and downlink optical signals, an optical circulator for transmitting uplink and downlink optical signals including a plurality of optical wavelengths output from the broadband light source using a rotational signal; And an interleaver for channel interleaving and outputting uplink and downlink optical signals output from the optical circulator, Outputs the downlink optical signal input from the broadband light source to the first terminal to the second terminal to provide to the injection light source on the central management station (CO) side, and the uplink optical signal input from the broadband light source to the first terminal It outputs to the third terminal to provide to the injection light source of the local node (RN) side, and outputs the downlink optical signal input to the second terminal to the third terminal, the optical signal of the upstream channel input to the third terminal And an optical path setting device for outputting a signal to the second terminal. The method of claim 2, The downlink channel is any one of an odd channel of an A-band, an odd channel of a B-band, an odd channel of an A-band and a B-band, The uplink channel is any one of an even channel of the A-band, an even channel of the B-band, an even channel of the A-band and the B-band, optical path setting device. The method of claim 2, The downlink channel is any one of an even channel of A-band, an even channel of B-band, an even channel of A-band and B-band, The uplink channel is any one of an odd channel of an A-band, an odd channel of a B-band, an odd channel of an A-band and a B-band. The method according to claim 3 or 4, The optical circulator is a three-port optical circulator operating simultaneously in the A-band and B-band, The interleaver is a four-port 2x2 interleaver that wavelength-divisions and / or combines wavelengths according to the wavelength of the input signal. The interleaver outputs downlink optical signals to port 3 with respect to the input of port 1 and It outputs uplink optical signals to port 4 for input, outputs downlink optical signals to port 1 for input of port 3, and upstream to port 1 for input of port 4. An optical path setting device for outputting optical signals. The method of claim 5, The first terminal is a port 1 of the optical circulator, and is connected to the broadband light source (BLS) that outputs uplink and downlink optical signals of A-band or B-band or A-band and B-band. Become, The second terminal is a port 3 of the 2 × 2 interleaver and is connected to the central management station (CO) side. The third terminal is a port 4 of the 2 × 2 interleaver and is connected to the local node (RN) side. Port 2 of the optical circulator is connected to the port 1 of the 2 × 2 interleaver, port 3 of the optical circulator has a structure connected to the port 2 of the 2 × 2 interleaver, optical path setting device . The method of claim 1, A first broadband light source for outputting the odd and even channels of the A-band downlink optical signals, a second broadband light source for outputting the odd and even channels of the B-band upstream channels; First and second optical circulators for transmitting the uplink and downlink optical signals including a plurality of optical wavelengths output from the second broadband light source using a signal rotation phenomenon, and the output from the first optical circulator An interleaver for channel interleaving and outputting the downlink optical signal, the downlink optical signal input from the central management station (CO), and the uplink optical signal output from the second optical circulator, and the first optical document The downlink optical signal output from the curator, the upstream optical signal output from the second optical circulator, and the upstream optical signal input from the local node RN are compared. Include filters to reverse filter, Optical signals of odd and even channels of the A-band downlink channel, which are input from the first broadband light source to the first terminal, are classified and output to the second and third terminals so that the central management station (CO) side first and second signals are output. It is provided as an injection light source, and outputs the odd-numbered and even-channel optical signals of the B-band upstream channel input from the second broadband light source to the fourth terminal to the fifth terminal to provide the injection light source to the local node (RN) side. And outputs an odd channel and an even channel optical signal of an A-band downlink channel input to the second and third terminals to the fifth terminal, an odd channel of an B-band uplink channel input to the fifth terminal, and And an optical path setting device for dividing the optical signal of an even channel into the second and third terminals. The method of claim 7, wherein The first optical circulator is a three-port optical circulator operating in the A-band, The second optical circulator is a three-port optical circulator operating in the B-band, The interleaver is a four-port 2x2 interleaver for wavelength division or / and wavelength combining according to the wavelength of an input signal. Outputs the optical signal of the even channel of the A-band downlink channel to port 4 for the input of port 1, and the odd number of the A-band downlink channel to port 1 for the input of port 3 and port 4. Outputs optical signal of channel and even channel, and outputs optical signal of odd channel of B-band up channel to port 4 for input of port 2 and B-band to port 3 for input of port 2 And an optical path setting device for outputting an even channel of an uplink channel. The method of claim 8, The first terminal is a port 1 of the first optical circulator, and is connected to the first broadband light source BLS for outputting optical signals of odd and even channels of an A-band downlink channel. The second terminal is a port 3 of the 2 × 2 interleaver, and is connected to the first AWG on the side of the central management station (CO), The third terminal is a port 4 of the 2 × 2 interleaver, and is connected to a second AWG on the side of the central management station (CO), The fourth terminal is a port 1 of the second optical circulator, and is connected to the second broadband light source BLS for outputting optical signals of odd and even channels of a B-band uplink channel. The fifth terminal is a port 1 of the filter and is connected to the local node (RN) side. Port 2 of the first optical circulator is connected to port 1 of the 2 × 2 interleaver, port 3 of the first optical circulator is connected to port 3 of the filter, An optical path having a structure in which port 2 of the second optical circulator is connected to port 2 of the filter, and port 3 of the second optical circulator is connected to port 2 of the 2 × 2 interleaver Setting device. A wavelength division multiplex passive optical subscriber network system comprising the three-terminal optical path setting device according to any one of claims 1 to 4 on a CO side. The method of claim 10, An interleaver is further provided in front of the RN side multiplexing / demultiplexing apparatus so that two adjacent even / odd channels have the same optical path, and the RN side multiplexing / demultiplexing apparatus is a 2 × N multiplexing / demultiplexing apparatus. Passive optical subscriber network system. The method of claim 11, A wavelength division multiplex passive optical subscriber network system capable of transmitting and receiving light through one optical line. The method of claim 10, A wavelength division multiplexing passive optical subscriber network system in which the RN side multiplexing / demultiplexing device has twice the channel spacing as compared to the CO side multiplexing / demultiplexing device. A wavelength division multiplex passive optical subscriber network system comprising the 5-terminal optical path setting device of any one of claims 1 and 7 on a CO side.

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