KR20100012218A - Ultrahigh frequency band combiner and network system using the same - Google Patents

Abstract

PURPOSE: An ultrahigh frequency band combiner and a network system using the same are provided to reduce loss of a data signal between a first data transceiving unit and a second data transceiving unit by using a frequency band combiner and a band combiner. CONSTITUTION: A light source unit(110) outputs a beam in a first wave length band and a beam in a second wave length band. A first combiner(130a) combines the output beam from a second port of a second circulator(150a) and the beam in the first wave length band. The first combiner inputs the combination beam on a third port of a first circulator(150b). A second combiner(130b) combines the output beam from a second port of the first circulator and the beam in the second wave length band.

Description

ULTRAHIGH FREQUENCY BAND COMBINER AND NETWORK SYSTEM USING THE SAME}

The present invention relates to an ultra-high frequency band coupler and a network system using the same. In particular, the first data and the second circulator beams of the first wavelength band and the second wavelength band are divided by the erbium-doped optical fiber. The present invention relates to an ultra-high frequency band combiner capable of reducing data signal loss by transmitting to a transceiver and a second data transceiver.

As network traffic continues to increase, interest in Fiber To The Home (FTTH) technology increases.

The FTTH system is configured based on a passive optical network (PON) structure that does not require power at a remote node (RN).

The multiplexed data applied to the remote node end is routed by power division or wavelength division to a designated optical network unit (ONU) through an all optical router.

Accordingly, the passive optical network uses a time division multiplexing (TDM) or a wavelength division multiplexing (WDM).

Previously, the TDM method was mainly used due to problems of installation cost and operation cost, but a technology for implementing a WDM method using a single light source has emerged.

1 is a schematic diagram illustrating a network system according to the prior art.

Referring to FIG. 1, a network system according to the prior art includes a central base station 10, a single mode optical fiber 20, and a subscriber network 30.

The single light source 11 used in the central base station 10 according to the prior art may be an erbium fiber ASE-based supercontinuum light source, which has a wavelength band of about 1510 nm to 1650 nm.

The wavelength emitted from the single light source 11 is divided into a plurality of wavelength bands through a Wave Division Multiplexer (WDM) 12. Specifically, the plurality of wavelength bands include a C-band light source, an L-band light source and a U-band light source, wherein the C-band light source has a wavelength band of about 1530-1565 nm, and an L-band light source has about 1565-1610 nm. In the wavelength band, the U-band light source may be a wavelength band of about 1610 ~ 1650nm.

The split wavelength is transmitted through the 50:50 coupler 13 to the C-band light source to the central base station 10 and the L-band light source to the subscriber network 40.

 The C-band light source is divided in the cyclic AWG (15) and transmitted to the transmitting end of the central base station 10, the C-band light source transmitted to the transmitting end of the central base station 10 is loaded with data and reflected to the subscriber network (30) It is a downlink signal sent to).

The L-band light source is split in the cyclic AWG 31 through the 25Km single mode optical fiber 20 and transmitted to the transmitting end of the subscriber network 30. The L-band light source transmitted to the transmitting end of the subscriber network 30 is an uplink signal carrying data and being reflected to the central base station 10.

In addition, the U-band light source is a signal for monitoring whether the signals transmitted from the C-band light source and the L-band light source are operating normally.

That is, the network system according to the prior art divides the single light source 11 into a C-band light source and an L-band light source through the wavelength division multiplexer 12 and the central base station 10 through the 50:50 coupler 13. And two-way communication between the subscriber network (30).

However, the 50:50 coupler 13 has a characteristic that only 50% of the input signal output is transmitted, resulting in signal loss. For example, the split wavelength, that is, the L-band light source split through the wavelength division multiplexer 12 is primarily transmitted through the 50:50 coupler 13 to the transmitting end of the central base station 10, It is modulated and secondarily passed through the 50:50 coupler 13 to the transmitting end of the subscriber network 30.

Therefore, there is a disadvantage in that a signal loss of 3 dB each occurs through the 50:50 coupler 13, resulting in a total signal loss of 6 dB.

In order to solve the above problems, the present invention provides a first data transmitting and receiving unit and a second data through the first circulator and the second circulator the beam of the first wavelength band and the beam of the second wavelength band divided from the erbium-doped optical fiber It is an object of the present invention to provide an ultra-high frequency band combiner and a network system using the same which can reduce data signal loss by transmitting to a transceiver.

The band combiner according to the present invention includes a light source unit for outputting a beam of a first wavelength band and a beam of a second wavelength band; A first circulator having a first port connected to the first data transceiver; A second circulator having a first port connected to a second data transceiver; A first combiner for combining the beam of the first wavelength band and the beam output from the second port of the second circulator and inputting the beam to the third port of the first circulator; And a second combiner configured to combine the beam of the second wavelength band with the beam output from the second port of the first circulator and input the beam to the third port of the second circulator.

The light source unit according to the present invention, the light source for emitting light; And a first beam splitter configured to split the light into beams of the first wavelength band and beams of the second wavelength band, wherein the light source includes: an optical amplifier configured to generate a seed ASE beam; An Er-Yb amplifier for amplifying the seed ASE beam; A nonlinear optical fiber unit converting the amplified seed ASE beam into a nonpolar wideband beam; And a spectral flattening filter for flattening the nonpolar wideband beam output from the nonlinear optical fiber portion.

The optical amplifier may include an erbium-added optical amplifier, and the nonlinear optical fiber part preferably includes a highly nonlinear dispersion-shifted fiber (HNL-DSF). In addition, the spectral flattening filter may comprise a spatial-light modulator.

The first wavelength band of the band combiner according to the present invention is preferably 1565 nm to 1610 nm, and the second wavelength band is preferably 1530 nm to 1565 nm.

A network system using a band combiner according to the present invention includes a first data transceiver; A second data transceiver connected to the first data transceiver through an optical fiber cable; And a band combiner for communicating communication between the first data transceiver and the second data transceiver, wherein the band combiner comprises: a light source for emitting light; A first beam splitter for splitting the light into a beam of a first wavelength band and a beam of a second wavelength band; A first circulator having a first port connected to the first data transceiver; A second circulator having a first port connected to the second data transceiver; A first combiner for combining the beam of the first wavelength band and the beam output from the second port of the second circulator and inputting the beam to the third port of the first circulator; And a second combiner configured to combine the beam of the second wavelength band with the beam output from the second port of the first circulator and input the beam to the third port of the second circulator.

The light source according to the invention, the optical amplifier for generating a seed ASE beam; An Er-Yb amplifier for amplifying the seed ASE beam; And a nonlinear optical fiber unit converting the amplified seed ASE beam into a nonpolar wideband beam.

Preferably, the optical amplifier includes an erbium-doped optical amplifier, and the nonlinear optical fiber part may include a highly nonlinear dispersion-shifted fiber (HNL-DSF).

The first wavelength band of the network system using the band combiner according to the present invention is preferably 1565 nm to 1610 nm, and the second wavelength band is 1530 nm to 1565 nm.

In a network system using a band combiner according to the present invention, the first data transceiver and the second data transmitter are at least one first data transmitter and at least one first data receiver, at least one second data transmitter, and at least one second data, respectively. The receiver may further include a first cyclic AWG between the first port of the first circulator, the one or more first data transmitters, and the one or more first data receivers. The apparatus may further include a second cyclic AWG between the first port of the second circulator, the one or more second data transmitters, and the one or more second data receivers.

The first data transceiver and the second data transceiver according to the present invention may further include at least one first data transmitter and at least one second data transceiver, respectively, the first port and the first port of the first circulator Preferably, a second beam splitter and a third beam splitter are included between the data transceiver and the second data transceiver. The apparatus may further include a first cyclic AWG between the second beam splitter and the at least one first data transmitter, and a second cyclic AWG between the third beam splitter and the at least one second data transmitter. It is preferable to further include.

According to the present invention, the ultra-high frequency band combiner and the network system using the same according to the present invention is a process of transmitting and receiving between the first data transceiver and the second data transceiver compared to the network system using a coupler according to the prior art by using a band coupler An advantage is that the loss of the data signal generated in the system can be reduced.

In addition, as the loss of the data signal is reduced, there is an advantage that the transmission distance can be increased.

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

2 is a schematic diagram illustrating a band combiner 100 according to the present invention.

2, the band combiner 100 according to the present invention includes a light source unit 110, a first coupler 130a, a second coupler 130b, a first circulator 150a and a second circulator. 150b.

The light source unit 110 outputs a beam of a first wavelength band and a beam of a second wavelength band. Specifically, the light source unit 110 splits and outputs the light emitted from the light source 111 into a beam of the first wavelength band and a beam of the second wavelength band through the first beam splitter 113.

The configuration of the light source 111 will be described in detail with reference to FIG. 3.

3 is a schematic view showing a light source 111 according to the present invention.

The light source 111 includes an optical amplifier 111-1, an Er-Yb amplifier 111-3, and a nonlinear optical fiber unit 111-5.

The optical amplifier 111-1 generates a seed amplified spontaneous emission (ASE) beam. The optical amplifier 111-1 is preferably an erbium doped fiber amplifier.

The Er-Yb amplifier 111-3 amplifies the seed ASE beam output from the optical amplifier 111-1. The seed ASE beam may be amplified up to 29 dBm by the Er-Yb amplifier 111-3.

The nonlinear optical fiber 111-5 converts the amplified seed ASE beam into a nonpolar wideband beam. The nonlinear optical fiber 111-5 preferably includes about 2 km of a highly nonlinear dispersion-shifted fiber (HNL-DSF). The amplified seed ASE beam may be converted into a nonpolar wideband beam having a bandwidth of 130 nm by the nonlinear optical fiber 111-5.

Referring back to FIG. 2, the first beam splitter 113 splits the light output from the light source 111 into a beam of a first wavelength band and a beam of a second wavelength band. Specifically, the first wavelength band may be an L-band band (about 1530 nm to 1565 nm), and the second wavelength band may be a C-band band (about 1565 nm to 1610 nm).

The first combiner 130a combines the beam of the first wavelength band and the beam output from the second port of the second circulator 150b and inputs it to the third port of the first circulator 150a.

The first circulator 150a transmits the beam input to the third port to the first data transceiver 200. Preferably, the data transmitted through the beam of the first wavelength band is demodulated by the first data receiver 230b (shown in FIG. 4), and the first data transmitter 230a (shown in FIG. 4). Modulates a response signal to the data and inputs the first port of the first circulator 150a through the beam of the first wavelength band. The signal input to the first port is output to the second port.

The second combiner 130b combines the beam output from the first circulator 150a and the beam of the second wavelength band and inputs the same to the third port of the second circulator 150b. Specifically, the beam output from the second port of the first circulator 150a, that is, the beam of the first wavelength band output through the first data transmitter 230a and the first beam splitter 113 are divided. The beam of the second wavelength band is combined and input to the third port of the second circulator 150b.

The second circulator 150b transmits the beam input to the third port to the second data transceiver 400. Preferably, the data transmitted through the beam of the second wavelength band is demodulated by a second data receiver 430b, and the first data transmitter 430a modulates a response signal for the data to the second wavelength. Input to the first port of the second circulator 150b through the beam of the band. The signal input to the first port is output to the second port.

4 is a schematic diagram illustrating a network system using a band combiner according to an embodiment of the present invention.

Since the network system using the band combiner according to the present invention is configured using the band combiner 100 shown in FIG. 2, the same reference numerals are used for the same components.

Referring to FIG. 4, the network system using the band combiner according to the present invention includes a band combiner 100, a first data transceiver 200, and a second data transceiver 400.

The band combiner 100 includes a light source unit 110, a first coupler 130a, a second coupler 130b, a first circulator 150a, and a second circulator 150b.

The light source unit 110 outputs a beam of a first wavelength band and a beam of a second wavelength band. Specifically, the light source unit 110 divides and outputs the light emitted from the light source 111 into a beam of the first wavelength band and a beam of the second wavelength band through the first beam splitter 113.

The light source unit 110 includes a light source 111 and a first beam splitter 113.

The light source 111 emits light. Since the detailed description of the light source 111 has been described with reference to FIG. 3, the detailed description thereof will be omitted.

The first beam splitter 113 splits the light output from the light source 111 into a beam of a first wavelength band and a beam of a second wavelength band. Specifically, the first wavelength band may be an L-band band (about 1530 nm to 1565 nm), and the second wavelength band may be a C-band band (about 1565 nm to 1610 nm). Preferably, the beam of the first wavelength band output from the first beam splitter 113 is input to the first combiner 130a, and the beam of the second wavelength band is input to the second combiner 130b.

The first combiner 130a combines the beam of the first wavelength band and the beam output from the second port of the second circulator 150b and inputs it to the third port of the first circulator 150a.

The first circulator 150a transmits the beam input to the third port to the first data transceiver 200. Preferably, the data transmitted through the beam of the first wavelength band is demodulated by the first data receiver 230b, and the first data transmitter 230a modulates a response signal to the data to the first wavelength. Input to the first port of the first circulator 150a through the beam of the band. The signal input to the first port is output to the second port.

The second combiner 130b combines the beam output from the first circulator 150a and the beam of the second wavelength band and inputs the same to the third port of the second circulator 150b. Specifically, the beam output from the second port of the first circulator 150a, that is, the beam of the first wavelength band output through the first data transmitter 230a and the first beam splitter 113 are divided. The beam of the second wavelength band is combined and input to the third port of the second circulator 150b.

The second circulator 150b transmits the beam input to the third port to the second data transceiver 400. Preferably, the data transmitted through the beam of the second wavelength band is demodulated by a second data receiver 430b, and the first data transmitter 430a modulates a response signal for the data to the second wavelength. Input to the first port of the second circulator 150b through the beam of the band. The signal input to the first port is output to the second port.

The first data transceiver 200 receives the beam of the first wavelength band and the beam of the second wavelength band output from the first port of the first circulator 150a. Specifically, the first data receiver 230b demodulates the data transmitted through the beam of the first wavelength band, and the first data transmitter 230a modulates the response signal to the data to the first wavelength band. Re-enter the first port of the first circulator 150a through the beam. The signal input to the first port of the first circulator 150a is output through the second port and input to the third port of the second circulator 150b through the second coupler 130b.

In addition, the first data transceiver 200 transmits the beam of the second wavelength band input through the second data transmitter 430a to the first data receiver 230b through the band combiner 100. Specifically, when the response signal modulated by the second data transmitter 430a through the beam of the second wavelength band is input to the first port of the second circulator 150b, through the first beam combiner 130a The beam is coupled to the beam of the first wavelength band divided by the first beam splitter 113 and input to the third port of the first circulator 150a. The beam input to the third port of the first circulator 150a is transmitted to the first data receiver 230b through the first port.

The first data transceiver 200 may be, for example, a base station network, and may further include one or more first data transmitters 230a and one or more first data receivers 230b as shown in FIG. 5.

In this case, the first data transceiver 200 may include a first cyclic arrayed waveguide (AWG) between the first circulator 150a, the one or more first data transmitters 230a, and the one or more first data receivers 230b. Grating) 270.

The first cyclic AWG 270 demultiplexes the beam output from the first port of the first circulator 150a to be input to the one or more first data receivers 230b, and the first data transmitter 230a. Multiplexing the beam output from the () is input to the first port of the first circulator (150a).

The second data transceiver 400 receives the beam of the second wavelength band and the beam of the first wavelength band output from the first port of the second circulator 150b. Specifically, the second data receiver 430b demodulates the data transmitted through the beam of the second wavelength band, and the second data transmitter 430a modulates the response signal for the data to the second wavelength band. Re-enter the first port of the second circulator 150b through the beam. The signal input to the first port of the second circulator 150b is output through the second port and input to the third port of the first circulator 150a through the first coupler 130a.

In addition, the second data transceiver 400 transmits the beam of the first wavelength band input through the first data transmitter 230a to the second data receiver 430b through the band combiner 100. Specifically, when the response signal modulated by the first data transmitter 230a through the beam of the first wavelength band is input to the first port of the first circulator 150a, through the second beam combiner 130b. The beam is coupled to the beam of the second wavelength band divided from the first beam splitter 113 and input to the third port of the second circulator 150b. The beam input to the third port of the second circulator 150b is output to the first port and transmitted to the second data receiver 430b through the optical fiber cable 300.

The second data transceiver 400 may be, for example, a subscriber network, and may further include one or more second data transmitters 430a and one or more second data receivers 430b as shown in FIG. 5.

In this case, the second data transceiver 400 may connect the second cyclic AWG 470 between the second circulator 150b, the one or more second data transmitters 430a, and the one or more first data receivers 430b. It may include.

The second cyclic AWG 470 demultiplexes the beam output from the first port of the second circulator 150b and inputs it to one or more second data receivers 430b, and the second data transmitter 430a. The multiplexed beams output from the N-th beam are input to the first port of the second circulator 150b.

6 is a schematic diagram illustrating a network system using a band combiner according to another embodiment of the present invention.

Referring to FIG. 6, a configuration of a network system using a band combiner according to another embodiment of the present invention may include a first data transceiver 200 and a second data transceiver of the network system using the band combiner illustrated in FIG. 5. Only the configuration of 400 is different, and the other configurations are the same. Therefore, only the configuration of the first data transceiver 200 and the second data transceiver 400 will be described in detail.

The first data transceiver 200 may include at least one first data transmitter 230a and a first data receiver 230b.

The first data transmitter / receiver 200 transmits the beam of the first wavelength band and the beam of the second wavelength band output from the first port of the first circulator 150a through the second beam splitter 250. 1 is transmitted to the data transmitter 230a.

Preferably, the first cyclic AWG 270 may further include a second cyclic AWG 270 between the second beam splitter 250 and the one or more first data transmitters 230a. The beam output from the first data transmitter 230a is multiplexed and input to the first port of the first circulator 150a.

Specifically, the first data receiver 230b demodulates the data transmitted through the beam of the first wavelength band, and the one or more first data transmitters 230a modulate a response signal to the data to the first signal. The signal is input again to the first port of the first circulator 150a through the beam of the wavelength band. The beam of the first wavelength band input to the first port of the first circulator 150a is output through the second port and input to the third port of the second circulator 150b through the second coupler 130b. do.

In addition, the first data transceiver 200 transmits a beam having a second wavelength band input through at least one second data transmitter 430a to the first data receiver 230b through the band combiner 100. Specifically, when the response signal modulated by the second data transmitter 430a through the beam of the second wavelength band is input to the first port of the second circulator 150b, the first beam combiner 130a may be connected. Through the first beam splitter 113 is coupled to the beam of the first wavelength band divided by the first beam splitter 113 through the input to the third port of the first circulator (150a). The beam input to the third port of the first circulator 150a is output to the first port and transmitted to the first data receiver 230b through the second beam splitter 250. Preferably, the beam output from the second beam splitter 250 may be transmitted to the first data receiver 230b through a band pass filter (not shown).

The second data transceiver 400 may include at least one second data transmitter 430a and a second data receiver 430b.

The second data transceiver 400 transmits the beam of the second wavelength band and the beam of the first wavelength band output from the first port of the second circulator 150b through one or more third beam splitters 450. 2 is transmitted to the data transmitter 430a.

Preferably, the second cyclic AWG 470 may further include a second cyclic AWG 470 between the third beam splitter 450 and the one or more second data transmitters 430a. 2 The beam output from the data transmitter 430a is multiplexed and input to the first port of the second circulator 150b.

Specifically, the second data receiver 430b demodulates the data transmitted through the beam of the second wavelength band, and the one or more second data transmitters 430a modulate a response signal to the data to the second. The signal is input again to the first port of the second circulator 150b through the beam of the wavelength band. The signal input to the first port of the second circulator 150b is output through the second port and input to the third port of the first circulator 150a through the first coupler 130a.

In addition, the second data transceiver 400 transmits the beam of the first wavelength band input through at least one first data transmitter 230a to the second data receiver 430b through the band combiner 100. Specifically, when the response signal modulated by the first data transmitter 230a is input to the first port of the first circulator 150a through the beam of the first wavelength band, through the second beam combiner 130b. The beam is coupled to the beam of the second wavelength band divided from the first beam splitter 113 and input to the third port of the second circulator 150b. The beam input to the third port of the second circulator 150b is output to the first port, input to the third beam combiner 450 through the optical fiber cable 300, and input to the third beam combiner 450. The beam is transmitted to the second data receiver 430b. Preferably, the beam output from the third beam combiner 450 passes through a bandpass filter (not shown) and is transmitted to the second data receiver 430b.

Although the preferred embodiment according to the present invention has been described above, this is merely exemplary and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the protection scope of the present invention will be defined by the following claims.

Therefore, the embodiments disclosed herein are not intended to limit the present invention but to describe the present invention, and the spirit and scope of the present invention are not limited by these embodiments. It is intended that the scope of the invention be interpreted by the following claims, and that all descriptions within the scope equivalent thereto will be construed as being included in the scope of the present invention.

1 is a schematic diagram illustrating a network system according to the prior art;

2 is a schematic diagram illustrating a band combiner in accordance with the present invention.

3 is a schematic view showing a light source according to the present invention;

4 is a schematic diagram illustrating a network system using a band combiner according to an embodiment of the present invention.

5 is a schematic diagram illustrating another embodiment of a network system using the band combiner shown in FIG.

6 is a schematic diagram illustrating a network system using a band combiner according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: band combiner 110: light source

111: light source 111-1: optical amplifier

111-3: Er-Yb amplifier 111-5: Nonlinear optical fiber part

113: first beam splitter 130a: first combiner

130b: second coupler 150a: first circulator

150b: second circulator 200: first data transceiver

230a: first data transmitter 230b: first data receiver

250: second beam splitter 270: first cyclic AWG

300: optical fiber cable 400: second data transceiver

430a: second data transmitter 430b: second data receiver

450: third beam splitter 470: second cyclic AWG

Claims (21)

A light source unit configured to output a beam of a first wavelength band and a beam of a second wavelength band; A first circulator having a first port connected to the first data transceiver; A second circulator having a first port connected to a second data transceiver; A first combiner for combining the beam of the first wavelength band and the beam output from the second port of the second circulator and inputting the beam to the third port of the first circulator; And A second combiner for combining the beam of the second wavelength band and the beam output from the second port of the first circulator and inputting the beam to the third port of the second circulator Band combiner comprising a. The method of claim 1, The light source unit, A light source emitting light; And a first beam splitter for splitting the light into beams in the first wavelength band and beams in the second wavelength band. The method of claim 2, The light source is, An optical amplifier for generating a seed ASE beam; An Er-Yb amplifier for amplifying the seed ASE beam; A nonlinear optical fiber unit converting the amplified seed ASE beam into a nonpolar wideband beam; And And a spectral flattening filter for flattening the nonpolar wideband beam output from the nonlinear optical fiber portion. The method of claim 3, And said optical amplifier comprises an erbium-doped optical amplifier. The method of claim 3, And said nonlinear fiber portion comprises a highly nonlinear dispersion-shifted fiber (HNL-DSF). The method of claim 3, And said spectral flattening filter comprises a spatial-light modulator. The method of claim 1, And said first wavelength band is 1565 nm to 1610 nm. The method of claim 1, And said second wavelength band is 1530 nm to 1565 nm. A first data transceiver; A second data transceiver connected to the first data transceiver through an optical fiber cable; And Band combiner for mediating communication between the first data transceiver and the second data transceiver Including but not limited to: The band combiner, A light source emitting light; A first beam splitter for splitting the light into a beam of a first wavelength band and a beam of a second wavelength band; A first circulator having a first port connected to the first data transceiver; A second circulator having a first port connected to the second data transceiver; A first combiner for combining the beam of the first wavelength band and the beam output from the second port of the second circulator and inputting the beam to the third port of the first circulator; And A second combiner for combining the beam of the second wavelength band and the beam output from the second port of the first circulator and inputting the beam to the third port of the second circulator Network system comprising a. The method of claim 9, The light source is, An optical amplifier for generating a seed ASE beam; An Er-Yb amplifier for amplifying the seed ASE beam; And a nonlinear optical fiber unit for converting the amplified seed ASE beam into a nonpolar wideband beam. The method of claim 10, Wherein said optical amplifier comprises an erbium doped optical amplifier. The method of claim 10, And wherein the nonlinear optical fiber portion comprises a highly nonlinear dispersion-shifted fiber (HNL-DSF). The method of claim 9, The first wavelength band is a network system, characterized in that 1565nm to 1610nm. The method of claim 9, The second wavelength band is 1530nm to 1565nm network system, characterized in that. The method of claim 9, The first data transceiver and the second data transmitter further comprise one or more first data transmitters, one or more first data receivers, one or more second data transmitters, and one or more second data receivers, respectively. . The method of claim 15, And a first cyclic AWG between the first port of the first circulator and the one or more first data transmitters and the one or more first data receivers. The method of claim 15, And a second cyclic AWG between the first port of the second circulator and the one or more second data transmitters and the one or more second data receivers. The method of claim 9, And the first data transceiver and the second data transceiver further comprise one or more first data transmitters and one or more second data transceivers, respectively. The method of claim 18, And a second beam splitter and a third beam splitter between the first port of the first circulator and the first data transceiver and the second data transceiver. The method of claim 19, And a first cyclic AWG between the second beam splitter and the one or more first data transmitters. The method of claim 19, And a second cyclic AWG between the third beam splitter and the one or more second data transmitters.

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