KR101032483B1 - Optical line terminal for wavelength division multiplexing passive optical network - Google Patents

Abstract

An optical line terminal (OLT) according to an embodiment of the present invention outputs a first optical signal having a first wavelength to an Nth optical signal having an Nth wavelength, respectively, and is predetermined. A channel card unit including first channel cards to N-th channel cards for adjusting wavelengths of the optical signals based on reference wavelengths; A first flat optical multiplexer / demultiplexer (ODMX) for multiplexing the first to Nth optical signals output from the channel card unit into one optical signal; An optical coupler for coupling the multiplexed optical signal to a remote node (RN) and an optical wavelength transition tester; And an optical wavelength shift checker for demultiplexing the multiplexed optical signal received from the optical coupler into the first to Nth optical signals and feeding back to the first to Nth channel cards, respectively. Include.

WDM-PON, OLT, ONU, TRX, Optical, Optical, Wavelength, Stabilized, Locked

Description

OPTICAL LINE TERMINAL FOR WAVELENGTH DIVISION MULTIPLEXING PASSIVE OPTICAL NETWORK}

The present invention relates to a method for locking / stabilizing an optical signal wavelength of a wavelength division passive optical network (WDM-PON), and more particularly, to a structure of a wavelength division multiplexing-passive optical network (WDM-PON). , Tunable Optical Transceiver (T-TRX) and Tunable Optical Transceiver (T-TRX) of Optical Network Unit (ON-U) In the optical signal transmission / reception, wavelength lock in which the wavelength of the optical signal, which changes according to the external environment such as temperature change, is adjusted to the wavelength of the optical signal having the maximum optical intensity through the optical coupler, the optical wavelength inspector, and the channel card. By performing locking or wave length stabilization, it ensures stable communication channel through transmission and reception of optimized optical signal at all times regardless of external environment. The present invention relates to a wavelength lock / stabilization method of an optical signal of a wavelength division passive optical network (WDM-PON) capable of maximizing quality.

With the development of information technology, the increase of internet and multimedia communication traffic is required to improve the capacity of subscriber network. The wavelength division multiplexing-passive optical network (WDM-PON) has been in the spotlight as one of the methods for improving the subscriber network transmission capacity.

1 is a view showing the overall network configuration of a wavelength division passive optical network (WDM-PON) according to the prior art.

FIG. 2 is a diagram illustrating light transmission characteristics of an optical multiplexer / demultiplexer (ODMX) of an optical path terminator (OLT) and an optical multiplexer / demultiplexer (ODMX) of a remote node device RN according to the related art.

The wavelength division passive optical network (WDM-PON) includes an optical line terminal (OLT) 100, a remote node 150, and an optical network, as shown in FIG. 1. Devices (ONU: Optical Network Units 161, 162, 163).

The optical fiber terminator (OLT) 100 includes N channel cards. For convenience of description, in FIG. 1, a case consisting of six channel cards and six optical network devices ONU will be described as an example. That is, the first channel card 111 to the sixth channel card 113 is included. In addition, the optical path terminator (OLT) 100 includes a first optical multiplexer / demultiplexer (ODMX) 120.

The remote node device (RN) 150 is connected to the optical ray terminator (OLT) 100 through a single optical line 130 and includes a second optical multiplexer / demultiplexer (ODMX) 151. The first optical network device (ONU) 161 to the sixth optical network device (ONU) 163 are the second optical multiplexer / demultiplexer of the remote node device (RN) 150 via a single optical line 140. Respectively connected to the (ODMX) 151.

The wavelength division passive optical network (WDM-PON) uses different optical wavelengths for each channel, and thus can be implemented based on the principle that the individual optical signals are not affected or influenced by the same optical path. In FIG. 1, a first optical multiplexer / demultiplexer (ODMX) 120 of an optical path terminator (OLT) 100 and a second optical multiplexer / demultiplexer (ODMX) 151 of a remote node device (RN) 150 are shown. Assuming that the optical transmission characteristics of the?) Are the same as those of FIG. 2, the optical path ends (OLT) 100 are transmitted from the first optical network device (ONU) 161 to the sixth optical network device (ONU) 163, respectively. The wavelength of the downlink optical signal to be referred to as λ1d to λ6d, and transmitted from the first optical network device (ONU) 161 to the sixth optical network device (ONU) 163 to the optical path terminator (OLT) 100, respectively. When the wavelength of the uplink optical signal is λ1u to λ6u, between the optical path terminator (OLT) 100 and the first optical network device (ONU) 161 to the sixth optical network device (ONU) 163. The principle of forming six independent communication channels results in a wavelength division passive optical network (WDM-PON).

In order for the wavelength division passive optical network WDM-PON to operate normally, the wavelengths λ1d to λ6d of the downlink optical signal transmitted from the optical path termination device (OLT) 100 and the first optical network device ONU ( 161 to 6th optical network device (ONU) 163 wavelength (λ1u to λ6u) of the uplink optical signal transmitted from the first optical multiplexer / demultiplexer (ODMX) 120 and the second optical beam shown in FIG. In the light transmission characteristic of the multiplex / demultiplexer (ODMX) 151, it is important not to coincide with or deviate from a certain level by the center wavelength of each channel. That is, the wavelength of the downlink optical signal of the optical path termination device (OLT) 100 and the wavelength of the uplink optical signal of the first optical network device (ONU) 161 to the sixth optical network device (ONU) 163 are different. It is essential to fix the technology so that it does not move in place.

The wavelength-variable optical transceiver (T-TRX) used in the optical path termination device (OLT) 100 or the first optical network device (ONU) 161 to the sixth optical network device (ONU) 163 is generally external. The output light wavelength tends to change easily due to factors such as air temperature change. If the tunable optical transmitter (T-TRX) deviates from the predetermined wavelength position due to an external factor such as a change in the external air temperature, the communication may be interrupted or interfere with the wavelength of another channel, causing serious communication quality degradation. Done.

Accordingly, there is a demand for development of a technology that can more easily and effectively implement wavelength locking or wavelength stabilization of a light source used in a wavelength division passive optical network (WDM-PON).

SUMMARY OF THE INVENTION The present invention has been made to improve the prior art as described above. Among the structures of a wavelength division multiplexing-passive optical network (WDM-PON), an optical line terminal (OLT) External environment such as temperature change in transmitting / receiving optical signals between a wavelength-tunable optical transceiver (T-TRX) and an optical network unit (ONU) -tunable optical transceiver (T-TRX) By performing wavelength locking or wavelength stabilization in which the wavelength of the optical signal that changes according to the optical signal is adjusted to the wavelength of the optical signal having the maximum optical intensity through the optical coupler, the optical wavelength inspector, and the channel card, Regardless of external environment, wavelength division that can maximize communication quality by guaranteeing stable communication channel through transmission and reception of optimized optical signal at all times An object of the present invention is to provide an optical signal wavelength locking / stabilization method for a passive optical network (WDM-PON).

In order to achieve the above object and to solve the problems of the prior art, an optical line terminal (OLT) according to an embodiment of the present invention, the first optical signal having a first wavelength to the N-th wavelength A channel card unit including first channel cards to Nth channel cards respectively outputting Nth optical signals, and adjusting wavelengths of the respective optical signals based on a predetermined reference wavelength; A first flat optical multiplexer / demultiplexer (ODMX) for multiplexing the first to Nth optical signals output from the channel card unit into one optical signal; An optical coupler for coupling the multiplexed optical signal to a remote node (RN) and an optical wavelength transition tester; And an optical wavelength shift checker for demultiplexing the multiplexed optical signal received from the optical coupler into the first to Nth optical signals and feeding back to the first to Nth channel cards, respectively. Include.

In addition, the K-channel card, which is any one of the first channel card to the N-th channel card of the optical path terminating apparatus (OLT), according to an embodiment of the present invention, transmits the K-th optical signal having the K-th wavelength. A K-th wavelength tunable optical transceiver (T-TRX) for outputting to a flat optical multiplexer / demultiplexer (ODMX); A K-th wavelength controller configured to receive a K-th optical signal fed back from the optical-wavelength transition inspector and to control the K-th wavelength variable optical transmitter (T-TRX) such that a center wavelength of the K-th optical signal becomes a K-th reference center wavelength ; Kth light intensity controller; And the K-th feedback part connected to the K-th wavelength controller and the K-th light intensity controller, respectively, and fed back from the wavelength conversion tester when the multiplexed optical signal is output from the first flat optical multiplexer / demultiplexer (ODMX). And a K-th switch for switching an optical signal to be transmitted to the K-th optical wavelength controller, wherein the K-th reference center wavelength is a center wavelength of a K-th channel of a Gaussian optical demultiplexer included in the optical-wavelength transition checker. It is characterized by.

In addition, the K-th optical wavelength controller of the optical path terminator (OLT) according to an embodiment of the present invention maintains a predetermined algorithm, and the algorithm is measured according to the change in the center wavelength of the K-th optical signal It is characterized in that the algorithm for changing the center wavelength of the K-th optical signal so that the maximum.

In addition, the first flat optical multiplexer / demultiplexer (ODMX) of the optical path termination device (OLT) according to an embodiment of the present invention is based on an arrayed waveguide grating (AWG) and a free spectral range (FSR). Where the filter pattern of the same band is formed in the spaced apart by a multiple of the and has a flat channel transmission characteristics.

In addition, the optical coupler of the optical path termination device (OLT) according to an embodiment of the present invention, the optical path between the first flat optical multiplexer / demultiplexer and the remote node device (RN) and the optical wavelength transition tester first path And a second path connected to each other, and when the multiplexed optical signal is output from the first flat optical multiplexer / demultiplexer (ODMX), the multiplexed optical signal is transmitted to the optical wavelength transition tester through the first path. It is characterized by coupling.

In addition, the optical wavelength shift inspector of the optical path termination device (OLT) according to an embodiment of the present invention, is connected to the first path and the second path of the optical coupler, respectively, the first flat optical multiple / reverse An optical switch for switching the multiplexed optical signal into a Gaussian optical demultiplexer (ODX) through connection with the first path when the multiplexed optical signal is output from the neutralizer (ODMX); A Gaussian optical demultiplexer (ODX) which demultiplexes the multiplexed optical signal into the first to Nth optical signals; And a first optical detector to an N-th optical detector for converting the demultiplexed first optical signals to the Nth optical signals into electrical signals and transmitting the electrical signals to the first channel card to the Nth channel card, respectively. It includes a photo detector.

In addition, the Gaussian optical demultiplexer (ODX) of the optical path termination device (OLT) according to an embodiment of the present invention is spaced apart by a multiple of a free spectral range (FRS) based on an arrayed waveguide grating (AWG). It is characterized in that it has an optical characteristic to form a filter pattern of the same band at the place, and has a Gaussian channel transmission characteristic.

In addition, the optical fiber terminal device (OLT) according to an embodiment of the present invention is characterized in that it is part of the wavelength division multiplexing-passive optical network (WDM-PON).

In addition, the optical network unit (ONU: Optical Network Unit) according to an embodiment of the present invention, the wavelength variable optical transmitter (T-) for transmitting the optical signal to the optical path termination device (OLT) through the remote node device (RN) TRX); The optical signal transmitted to the optical path terminating device (OLT) receives the optical signal whose amplitude is modulated by the optical path terminating device (OLT) through the remote node device (RN), and the amplitude modulated optical signal An optical detector for converting the signal into an electrical signal and outputting the converted signal; And adjusting the wavelength of the optical signal to a predetermined reference wavelength by controlling the wavelength variable optical transmitter (T-TRX) which converts the electrical signal output from the optical detector into an optical signal and outputs the optical signal. An optical wavelength controller.

In addition, the optical wavelength controller of the optical network device (ONU) according to an embodiment of the present invention maintains a predetermined algorithm, the algorithm is such that the optical signal intensity measured in accordance with the change in the central wavelength of the optical signal to the maximum Characterized in that the algorithm to adjust the center wavelength of the optical signal.

In addition, the optical path terminating device (OLT) of the optical network device (ONU) according to an embodiment of the present invention receives the optical signal from the optical network device (ONU) via the remote node device (RN). An optical coupler for coupling the optical signal to a first flat optical multiplexer / demultiplexer (ODMX) and an optical wavelength shift checker, respectively; An optical wavelength shift checker for converting the optical signal received from the optical coupler into an electrical signal and outputting the electrical signal; A channel card unit for converting the electrical signal output from the optical wavelength transition checker into an optical signal, and amplitude modulating and outputting the optical signal into an optical signal having an optical intensity proportional to the intensity of the electrical signal; And a first flat optical multiplexer / demultiplexer (ODMX) for transmitting the amplitude modulated optical signal output from the channel card unit to the optical detector of the optical network device ONU through the remote node device RN. Include.

In addition, the optical coupler of the optical network device (ONU) according to an embodiment of the present invention is the optical path between the first flat optical multiplexer / demultiplexer and the remote node device (RN) and the optical wavelength transition tester to the first path and When the optical signal is received from the optical network device (ONU) and connected to each other via a second path, the optical signal is coupled to be transmitted to the optical wavelength transition tester through the second path.

In addition, the optical wavelength transition checker of the optical network device (ONU) according to an embodiment of the present invention, respectively connected to the first path and the second path of the optical coupler, from the optical network device (ONU) An optical switch configured to switch the optical signal to enter a Gaussian optical demultiplexer (ODX) through the connection with the second path when the optical signal is received; A Gaussian optical demultiplexer (ODX) for outputting the optical signal to a corresponding optical detector; And an optical detector including first to Nth detectors for converting the optical signal into an electrical signal and outputting the electrical signal to the channel card.

In addition, the channel card portion of the optical network device (ONU) according to an embodiment of the present invention includes a first channel card to the N-th channel card, the K-th channel card is any one of the first channel card to the N-th channel card The channel card includes: a K-th wavelength variable optical transmitter (T-TRX) for converting and outputting the electrical signal received from the optical detector into an optical signal; A K-th light intensity controller for controlling the K-th wavelength variable optical transceiver T-TRX so that the light signal is amplitude-modulated such that the light intensity of the converted optical signal is proportional to the intensity of the electrical signal; K-th wavelength controller; And the optical signal, which is connected to the K-th wavelength controller and the K-th light intensity controller, respectively, and receives the optical signal from the optical network device ONU, the optical signal output from the optical wavelength transition inspector is the K-th light intensity controller. And a K-th switch switching to be transmitted to.

In addition, the remote node device (RN) of the optical network device (ONU) according to an embodiment of the present invention includes a second flat optical multiplexer / demultiplexer (ODMX), the second flat optical multiplexer / demultiplexer ( ODMX) has optical characteristics in which filter patterns of the same band are formed at a distance separated by multiples of a free spectral range (FRS) based on an arrayed waveguide grating (AWG), and has a flat channel transmission characteristic. It is done.

In addition, the optical network device (ONU) according to an embodiment of the present invention is characterized in that the optical network device (ONU) is part of a wavelength division multiplexing-passive optical network (WDM-PON). do.

According to the optical signal wavelength lock / stabilization method of the wavelength division passive optical network (WDM-PON) of the present invention, during the configuration of the wavelength division multiplexing-passive optical network (WDM-PON), Optical signal transmission and reception between a wavelength variable optical transceiver (T-TRX) and an optical network unit (ONU) optical variable terminal (OLT: Tunable Optical Transceiver) Wavelength Locking or Wavelength Stabilization in which the wavelength of the optical signal, which changes according to the external environment such as temperature change, is adjusted to the wavelength of the optical signal having the maximum light intensity through the optical coupler, the optical wavelength inspector, and the channel card. By performing Wavelength Stabilization, it is possible to maximize communication quality by guaranteeing stable communication channel through transmission and reception of optimized optical signal at all times regardless of external environment. The effect can be obtained.

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

FIG. 3 is a view illustrating an overall configuration of a wavelength division passive optical network (WDM-PON) in which an optical path terminator (OLT) stabilizes a wavelength of an optical signal and transmits the optical signal to an optical network device (ONU) according to an embodiment of the present invention. One drawing.

A wavelength division multiplexing-passive optical network (WDM-PON) according to an embodiment of the present invention includes an optical line terminal (OLT) 300 and a remote node device (RN). 350, and N optical network units (ONUs) 360a to 360n.

In the embodiment of the present invention described with reference to FIG. 3, the optical path terminator (OLT) 300 transmits an optical signal to the optical network devices ONUs 360a to 360n, that is, the transmission of the downlink optical signal is performed. The wavelength division passive optical network (WDM-PON) to be implemented is described as an example.

According to an embodiment of the present invention, an optical line terminator (OLT) 300 includes a first channel card 310a to an Nth channel card 310n and a first flat optical multiplexer / demultiplexer (ODMX: Optical De / A multiplexer 320, an optical coupler 330, and an optical wavelength shift inspector 340.

The first channel card 310a to the Nth channel card 310n respectively output the first optical signal having the first wavelength to the Nth optical signal having the Nth wavelength, and are based on a predetermined reference wavelength. The wavelength of each optical signal is adjusted.

The K-th channel card, which is one of the first channel card 310a to the N-th channel card 310n, includes a K-th wavelength variable optical transceiver (T-TRX), a K-th wavelength controller, and a K-th optical intensity A controller, and a K-th switch. For example, the first channel card 310a may include a first wavelength variable optical transceiver (T-TRX) 312a, a first optical wavelength controller 311a, a first optical intensity controller 313a, and a first switch 314a. The N-th channel card 310n may include an N-th wavelength variable optical transmitter (T-TRX) 312n, an N-th wavelength controller 311n, an N-th light intensity controller 313n, and an N-th channel card 310n. Switch 314n.

The downlink optical signals output from the first channel card 310a to the Nth channel card 310n respectively include a second flat optical multiplexer / demultiplexer (ODMX) 351 of the remote node device 350. The first optical network device 360a to the Nth optical network device 360n may be transmitted through the respective devices. That is, the first channel card 310a may output a first downlink optical signal having an optical wavelength of λ _1d that can be received by the first optical network device 360a, and the first optical network device 360a may include a first optical signal. A first uplink optical signal having an optical wavelength of λ _1u that can be received by one channel card 310a may be output. The same pattern can be applied to other channel cards and optical network devices.

In the present specification, for convenience of description, the N-th channel card 310n outputs a first downlink optical signal having an optical wavelength of λ _nd to be transmitted to the N-th optical network device 360n, and the N-th optical network device 360n Will be described as an example of outputting a first uplink optical signal having an optical wavelength of λ _nu and transmitting it to the N-th channel card 310n.

The N-th wavelength variable optical transmitter (T-TRX) 312n outputs the N-th optical signal having the N-th wavelength to the first flat optical multiplexer / demultiplexer (ODMX) 320.

The N-th optical wavelength controller 311n receives the N-th electrical signal fed back from the optical wavelength transition checker 340. The N-th electrical signal is converted into an N-th optical signal through an N-th wavelength variable optical transmitter (T-TRX) 312n and output to the first flat optical multiplexer / demultiplexer (ODMX) 320.

The N-th optical wavelength controller 311n controls the N-th wavelength variable optical transceiver (T-TRX) 312n such that the center wavelength of the N-th optical signal is the N-th reference center wavelength. The Nth reference center wavelength may be implemented as the center wavelength of the Nth channel of the Gaussian Optical Demultiplexer 342 included in the optical wavelength shift detector 340.

The N-th switch 314n is connected to the N-th wavelength controller 311n and the N-th light intensity controller 313n, respectively. The N-th switch 314n is configured to output the multiplexed optical signal from the first flat optical multiplexer / demultiplexer (ODMX) 320, that is, the first downlink where the N-th channel card 310n has an optical wavelength of λ _nd . When the optical signal is output and transmitted to the N-th optical network device 360n, the N-th electrical signal fed back from the optical wavelength transition checker 340 may be switched to be transmitted to the K-th optical wavelength controller 311n.

The N-th optical wavelength controller 311n maintains the selected algorithm, and the algorithm changes the center wavelength of the N-th optical signal so that the optical signal intensity measured according to the change in the center wavelength of the N-th optical signal is maximized. It can be implemented with an algorithm to.

The first flat optical multiplexer / demultiplexer (ODMX) 320 multiplexes the first optical signal to the Nth optical signal output from the first channel card 310a to the Nth channel card 310n into one optical signal. do. The first flat optical multiplexer / demultiplexer (ODMX) 320 is a light in which filter patterns having the same band are formed at a distance separated by a multiple of a free spectral range (FRS) based on an arrayed waveguide grating (AWG). It may be implemented to have characteristics and flat channel transmission characteristics.

An optical coupler 330 couples the multiplexed optical signal to a remote note device RN 350 and an optical wavelength transition checker 340. The optical coupler 330 is a light path between the first flat optical multiplexer / demultiplexer 320 and the remote node device (RN) 350 and the optical wavelength shift tester through the first path 331 and the second path 332. Can be connected to each other. The optical coupler 330 is configured to output the multiplexed optical signal from the first flat optical multiplexer / demultiplexer (ODMX) 320, that is, when the downlink optical signal is output from the optical path terminator 300. The optical signal may be coupled to be transmitted to the optical wavelength transition tester 340 through the first path 331.

The optical wavelength transition checker 340 demultiplexes the multiplexed optical signal received from the optical coupler 330 into the first to Nth optical signals and feeds back the first channel card to the Nth channel card, respectively. feedback). The light wavelength transition checker 340 includes an optical switch 341, a Gaussian optical demultiplexer (ODX) 342, and first to third detectors 343a to 343n.

The optical switch 341 is connected to the first path 331 and the second path 332 of the optical coupler 330, respectively. The optical switch 341 has a first path when the multiplexed optical signal is output from the first flat optical multiplexer / demultiplexer (ODMX) 320, that is, when the downlink optical signal is output from the optical path terminator 300. The multiplexed optical signal may be switched to be introduced into a Gaussian optical demultiplexer (ODX) 342 through a connection with the 331.

A Gaussian optical demultiplexer (ODX) 342 demultiplexes the multiplexed optical signal into the first to Nth optical signals. The first optical detector 343a to the N-th optical detector 343n convert the demultiplexed first optical signal to the Nth optical signal into electrical signals, respectively, to convert the first channel card 310a to the Nth channel. Each card 310n can be transmitted. The Gaussian optical demultiplexer (ODX) 342 has an optical characteristic in which filter patterns of the same band are formed at spaced apart multiples of a free spectral range (FRS) based on an arrayed waveguide grating (AWG), It may be implemented to have Gaussian channel transmission characteristics.

4 illustrates light transmission characteristics of a first flat optical multiplexer / demultiplexer (ODMX), a second flat optical multiplexer / demultiplexer (ODMX), and a Gaussian optical demultiplexer (ODX) according to an embodiment of the present invention. It is a graph.

In FIG. 4, (a) shows light transmission characteristics of the first flat optical multiplexer / demultiplexer (ODMX) 320, and (b) shows light transmission characteristics of the second flat optical multiplexer / demultiplexer (ODMX) 351. (C) shows the light transmission characteristics of the Gaussian light demultiplexer (ODX).

As shown in FIG. 4, the light transmission characteristics of the first flat optical multiplexer / demultiplexer (ODMX) 320 and the light transmission characteristics of the second flat optical multiplexer / demultiplexer (ODMX) 351 are the same. Can be. On the other hand, the light transmission characteristics of the Gaussian optical demultiplexer (ODX) 342 are the light transmission characteristics of the first flat optical multiplexer / demultiplexer (ODMX) 320 and the second flat optical multiplexer / demultiplexer (ODMX) 351. Compared to the light transmission characteristic of the band, the center wavelength of each band is matched, but the shape of the band filter may be formed differently.

The first flat optical multiplexer / demultiplexer (ODMX) 320, the second flat optical multiplexer / demultiplexer (ODMX) 351, and the Gaussian optical demultiplexer (ODX) 342 are all shown in FIG. 4. Likewise, the same band filter pattern may be formed at an interval separated by a multiple of a free spectral range (FRS), and may be implemented through an arrayed waveguide grating (AWG) technique.

Referring back to FIG. 3, the N-th wavelength variable optical transmitter (T-TRX) 312n included in the N-th channel card 310n of the optical path terminator (OLT) 300 corresponds to the N-th optical network. In order to communicate with the device 360n, the optical signal must be output at an optical wavelength λ _nd that can be received by the N-th optical network device 360n. If the optical signal of another wavelength is outputted, the N-th optical network device cannot pass through the first flat optical multiplexer / demultiplexer (ODMX) 320 and the second optical multiplexer / demultiplexer (ODMX) 351. It becomes impossible to communicate with 360n.

However, unless special measures are taken, the wavelength of the N-th wavelength variable optical transmitter (T-TRX) 312n is always changed due to external conditions such as changes in ambient temperature. It is necessary to lock / stabilize the optical wavelength of the N-th wavelength variable optical transmitter (T-TRX) 312n, which is constantly changing in the natural state, to a specific wavelength.

That is, the optical signal of the N-th wavelength variable optical transmitter (T-TRX) 312n passes through the optical coupler 330 along with the signals of other channels via the first flat optical multiplexer / demultiplexer (ODMX) 320. do. The optical coupler 330 sends some of the optical signals to the optical switch 341. The output of the optical switch 341 is input to a Gaussian optical demultiplexer (ODX) 342. The nth output of the Gaussian optical demultiplexer (ODX) 342 is converted into an electrical signal by the Nth optical detector 343n. The converted signal is input to the N-th wavelength controller 311n. The N-th wavelength controller 311n may move the wavelength of the N-th wavelength variable optical transmitter (T-TRX) 312n to a desired position according to the magnitude of the input signal.

5 is a graph showing the optical wavelength adjustment principle of the optical wavelength controller according to an embodiment of the present invention.

When the initial wavelength of the N-th wavelength variable optical transmitter (T-TRX) 312n measured at the input terminal of the N-th optical detector 343n is located at (a) as shown in FIG. 311n may vary the wavelength in the direction of increasing the wavelength so that the wavelength of the N-th wavelength variable optical transmitter (T-TRX) 312n is in the (b) position, whereby the intensity of the optical signal is increased.

The N-th wavelength controller 311n continuously varies the wavelength in a direction in which the wavelength increases, so that the wavelength of the N-th wavelength variable optical transceiver (T-TRX) 312n becomes (C). At this time, the intensity of the optical signal increases. Then, the wavelength is varied in the direction of increasing the wavelength so as to be (d). However, at this time, the intensity of the optical signal is reduced.

From this point on, the N-th wavelength controller 311n operates in a direction of decreasing wavelength. Thus, the wavelength of the optical signal is set to (c). At this time, the intensity of the optical signal increases. Again, the N-th wavelength controller 311n causes the wavelength to be (b). At this time, the intensity of the optical signal is reduced. From this time, the N-th wavelength controller 311n again controls to increase the wavelength. As a result, the N-th wavelength controller 311n may operate to change the wavelength in the direction of the past (increase or decrease in wavelength) from the past direction (increase or decrease in wavelength) when the phenomenon of the intensity of the optical signal decreases. .

Through this series of operations, the optical wavelength of the optical signal output from the N-th wavelength variable optical transceiver (T-TRX) 312n is centered on the center wavelength λ _nd of the nth channel of the Gaussian optical demultiplexer (ODX) 342. Can be stabilized. The series of operations may be applied to both the first wavelength variable optical transmitter (T-TRX) 312a to the Nth wavelength variable optical transmitter (T-TRX) 312n included in the optical path terminator 300. .

FIG. 6 illustrates an overall configuration of a wavelength division passive optical network (WDM-PON) in which an optical network device (ONU) stabilizes the wavelength of an optical signal and transmits the optical signal to an optical path termination device (OLT) according to another embodiment of the present invention. One drawing.

A wavelength division multiplexing-passive optical network (WDM-PON) according to another embodiment of the present invention includes an optical line terminal (OLT) 300 and a remote node device (RN). 350, and N optical network units (ONUs) 360a to 360n.

In an embodiment of the present invention described with reference to FIG. 6, the optical network devices (ONUs) 360a to 360n transmit optical signals to the optical fiber terminator 300. The wavelength division passive optical network (WDM-PON) to be implemented is described as an example. In the present specification, for convenience of description, the N-th optical network device (ONU) 360n among the first optical network device (ONU) 360a to the N-th optical network device (ONU) 360n is the N-th optical signal. The case of transmitting to the N-th channel card 310n of the optical path terminator (OLT) 300 will be described as an example.

An N-th optical network device 360n according to another embodiment of the present invention includes an N-th wavelength variable optical transmitter (T-TRX) 362n, an N-th optical detector 363n, an N-th band separation filter 361n, and N-th wavelength controller 364n.

The N-th wavelength variable optical transmitter (T-TRX) 362n transmits an optical signal to the optical path terminator (OLT) 300 through the remote node device (RN) 350. The N-th optical detector 363n outputs an optical signal of which the optical signal is amplitude-modulated by the optical path terminator (OLT) 300 to the remote node device (RN). Received through the 350, and converts the amplitude-modulated optical signal into an electrical signal and outputs.

The N-th wavelength controller 364n controls the N-th wavelength variable optical transmitter (T-TRX) 362n to convert the electrical signal output from the N-th optical detector 363n into an optical signal and output the converted optical signal. The wavelength of the signal can be adjusted to a predetermined reference wavelength. The N-th optical wavelength controller 364n maintains a predetermined algorithm, and the algorithm may be implemented as an algorithm for adjusting the central wavelength of the optical signal to maximize the optical signal intensity measured according to the change in the central wavelength of the optical signal. Can be.

When the optical coupler 330 of the optical path terminator OLT receives the optical signal from the N-th optical network device ONU 360n through the remote node device RN 350, the optical signal is the first signal. And couple to a flat optical multiplexer / demultiplexer (ODMX) 320 and a lightwave transition detector 340, respectively. The optical coupler 330 passes the optical path and the optical wavelength transition tester 340 between the first flat optical multiplexer / demultiplexer 320 and the remote node device RN 350 to the first path 331 and the second path 332. The optical signal is transmitted to the optical wavelength transition detector 340 through the second path 332 when the optical signal is received from the N-th optical network device (ONU) 360n. can do.

The optical wavelength transition checker 340 converts the optical signal received from the optical coupler 330 into an electrical signal and outputs the electrical signal. The optical switch 341 of the optical wavelength transition checker 340 is connected to the first path 331 and the second path 332 of the optical coupler 330, respectively, and the N-th optical network device (ONU) 360n When the optical signal is received from the optical signal, the optical signal may be switched to be introduced into the Gaussian optical demultiplexer (ODX) 342 through the connection with the second path 332. A Gaussian optical demultiplexer (ODX) 342 outputs the optical signal to an Nth optical detector 343n, which is a corresponding optical detector. The Nth optical detector 343n may convert the optical signal into an electrical signal and output the converted electrical signal to the Nth channel card 310n which is a corresponding channel card.

The N-th channel card 310n converts the electrical signal output from the optical wavelength shift checker 340 into an optical signal, and amplitude-modulates the optical signal into an optical signal having an optical intensity proportional to the intensity of the electrical signal. can do.

The Nth channel card 310n includes an Nth wavelength variable optical transceiver (T-TRX) 312n, an Nth light intensity controller 313n, an Nth optical wavelength controller 311n, and an Nth switch 314n. .

The N-th wavelength variable optical transmitter (T-TRX) 312n converts the electrical signal received from the N-th optical detector 343n into an optical signal and outputs the converted optical signal. The N-th light intensity controller 313n controls the N-th wavelength variable optical transmitter (T-TRX) 312n such that the light signal is amplitude modulated such that the light intensity of the converted optical signal is proportional to the intensity of the electrical signal. . The N-th switch 314n is connected to the N-th optical wavelength controller 311n and the N-th optical intensity controller 313n, respectively, and receives an optical wavelength when the optical signal is received from the N-th optical network device (ONU) 360n. The optical signal output from the transition checker 340 is switched to be transmitted to the N-th light intensity controller 313n.

The first flat optical multiplexer / demultiplexer (ODMX) 320 transmits the amplitude modulated optical signal output from the Nth channel card 310n through a remote node device (RN) 350 to the Nth optical network device (ONU). Nth photodetector 363n of (360n).

The remote node device (RN) 350 includes a second flat optical multiplexer / demultiplexer (ODMX) 351. The second flat optical multiplexer / demultiplexer (ODMX) 351 is a light in which filter patterns of the same band are formed at a distance separated by a multiple of a free spectral range (FRS) based on an arrayed waveguide grating (AWG). Characteristics, and may be implemented to have flat channel transmission characteristics.

As such, in the case of the uplink optical signal outputting the optical signal from the optical network devices 360a to 360n to the optical fiber terminator 300, an algorithm for adjusting the optical wavelength may be implemented differently from the embodiment of FIG. 3.

The electrical signal of the N-th optical detector 343n may not be input to the N-th optical wavelength controller 311n but may be input to the N-th optical intensity controller 313n at the optical path terminator 300. In addition, the state of the optical switch 341 of the light wavelength transition tester 340 may operate to connect the second path 332 as shown in FIG.

If the optical wavelength of the N-th wavelength variable optical transceiver (T-TRX) 362n of the N-th optical network device (ONU) 360n does not become λ _nu , then the N-th channel card of the optical path terminator (OLT) 300 is provided. Unable to communicate with 310n. This is because the first flat optical multiplexer / demultiplexer (ODMX) 320 and the second flat optical multiplexer / demultiplexer (ODMX) 351 cannot pass through as in the case of the optical path terminator (OLT) 300. to be.

The wavelength of the N-th optical network device (ONU) 360n is adjusted as follows. The optical signal of the N-th wavelength variable optical transmitter (T-TRX) 362n passes through the second flat optical multiplexer / demultiplexer (ODMX) 351 and the optical coupler 330 to the optical path terminator (OLT) 300. Is sent. A part of the optical signal passing through the optical coupler 330 is input to the optical switch 341. The output of the optical switch 341 is input to a Gaussian optical demultiplexer (ODX) 342.

The output of the Gaussian optical demultiplexer (ODX) 342 is input to the N-th optical detector 343n so that the intensity of the optical signal is converted into the intensity of the electrical signal. The converted electrical signal is input to the Nth light intensity controller 313n. The N-th light intensity controller 313n may amplitude-modulate the light intensity of the N-th wavelength variable optical transmitter (T-TRX) 312n in proportion to the light intensity detected by the N-th optical detector 343n.

The optical signal of the amplitude modulated N-th wavelength variable optical transmitter (T-TRX) 312n is input to an N-th optical detector 363n in the N-th optical network device (ONU) 360n. The output of the N-th optical detector 363n is input to the N-th optical wavelength controller 364n. The N-th wavelength controller 364n may lock or stabilize the wavelength to be λ _nu by controlling the wavelength of the N-th wavelength variable optical transmitter (T-TRX) 362n. This series of operations can be applied to both the first optical network device (ONU) 360a to the Nth optical network device (ONU) 360n.

The process of locking / stabilizing wavelengths in the first optical network device (ONU) 360a to the N-th optical network device (ONU) 360n is the same as that of the corresponding optical path terminator (OLT) 300. The difference is that in the optical path terminator (OLT) 300, the output (electrical signal) of the nth optical detector 343n is directly input to the optical wavelength controller 311n, whereas the Nth optical network device (ONU) 360n ), There is no way to directly transfer the output (electrical signal) of the n th optical detector (343n) to the optical wavelength controller (364n), so converts the electrical signal into a proportional optical signal (OLT) 300 Transfers the signal to the N-th optical network device (ONU) 360n, and then converts the optical signal into an electrical signal again using an optical detector 363n located in the N-th optical network device (ONU) 360n, thereby converting the optical signal into an optical wavelength controller 364n. You can type in

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 is a diagram showing the overall network configuration of a wavelength division passive optical network (WDM-PON) according to the prior art.

FIG. 2 is a view illustrating light transmission characteristics of an optical multiplexer / demultiplexer (ODMX) of an optical path terminator (OLT) and an optical multiplexer / demultiplexer (ODMX) of a remote node device (RN) according to the prior art.

FIG. 3 is a view illustrating an overall configuration of a wavelength division passive optical network (WDM-PON) in which an optical path terminator (OLT) stabilizes a wavelength of an optical signal and transmits the optical signal to an optical network device (ONU) according to an embodiment of the present invention. One drawing.

4 illustrates light transmission characteristics of a first flat optical multiplexer / demultiplexer (ODMX), a second flat optical multiplexer / demultiplexer (ODMX), and a Gaussian optical demultiplexer (ODX) according to an embodiment of the present invention. graph.

Figure 5 is a graph showing the optical wavelength adjustment principle of the optical wavelength controller according to an embodiment of the present invention.

FIG. 6 illustrates an overall configuration of a wavelength division passive optical network (WDM-PON) in which an optical network device (ONU) stabilizes the wavelength of an optical signal and transmits the optical signal to an optical path termination device (OLT) according to another embodiment of the present invention. One drawing.

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

300: fiber termination

310a to 310n: channel card

311a to 311n: light wavelength controller

312a to 312n: wavelength variable optical transmitter

313a to 313n: light intensity controller

314a to 314n: switch

320: first flat optical multiplexer / demultiplexer

330: optocoupler

331: first route

332: second path

340: light wavelength inspector

341: optical switch

342: Gaussian light demultiplexer

343a to 343n: optical detector

350: remote node device

351: second flat optical multiplexer / demultiplexer

360a to 360n: optical network device

361n: N-th band separation filter

362n: Nth wavelength variable optical transceiver

363n: Nth light detector

364n: Nth wavelength controller

Claims (16)

A first channel card to an Nth outputting the first optical signal having the first wavelength to the Nth optical signal having the Nth wavelength, and adjusting the wavelength of each optical signal based on a predetermined reference wavelength; A channel card unit including a channel card; A first flat optical multiplexer / demultiplexer (ODMX) for multiplexing the first to Nth optical signals output from the channel card unit into one optical signal; An optical coupler for coupling the multiplexed optical signal to a remote node (RN) and an optical wavelength transition tester; And An optical wavelength shift checker which demultiplexes the multiplexed optical signal received from the optical coupler into the first to Nth optical signals and feeds back to the first to Nth channel cards, respectively Optical line terminal (OLT: Optical Line Terminal) characterized in that it comprises a. The method of claim 1, The K-th channel card, which is any one of the first channel card to the N-th channel card, A K-th wavelength tunable optical transceiver (T-TRX) for outputting a K-th optical signal having a K-th wavelength to the first flat optical multiplexer / demultiplexer (ODMX); A K-th wavelength controller which receives the K-th optical signal fed back from the optical wavelength transition inspector and controls the K-th wavelength variable optical transceiver T-TRX so that the center wavelength of the K-th optical signal becomes the K-th reference center wavelength ; Kth light intensity controller; And The k-th optical signal fed back from the optical wavelength shift detector when the multiplexed optical signal is connected to the k-th wavelength controller and the k-th light intensity controller, respectively, and is output from the first flat optical multiplexer / demultiplexer (ODMX) A K-th switch to switch the call to the K-th wavelength controller Including, The Kth reference center wavelength is an optical line terminal (OLT: Optical Line Terminal), characterized in that the center wavelength of the K-th channel of the Gaussian Optical Demultiplexer including the optical wavelength shift detector. The method of claim 2, The K-th optical wavelength controller maintains a predetermined algorithm, and the algorithm changes the center wavelength of the K-th optical signal to maximize the intensity of the optical signal measured according to the change of the center wavelength of the K-th optical signal. Optical line terminal (OLT: Optical Line Terminal) characterized in that. The method of claim 1, The first flat optical multiplexer / demultiplexer (ODMX) has an optical characteristic in which filter patterns having the same band are formed at a distance separated by a multiple of a free spectral range (FRS) based on an arrayed waveguide grating (AWG). And an optical line terminal (OLT: Optical Line Terminal) characterized by having a flat channel transmission characteristic. The method of claim 1, The optical coupler connects the optical path between the first flat optical multiplexer / demultiplexer and the remote node device RN and the optical wavelength transition checker through a first path and a second path, and the first flat optical multiplexer / demultiplexer. When the multiplexed optical signal is output from the neutralizer (ODMX), the multiplexed optical signal is coupled to be transmitted to the optical wavelength transition tester through the first path. . The method of claim 5, The light wavelength transition checker, When the multiplexed optical signal is output from the first flat optical multiplexer / demultiplexer (ODMX), respectively, connected to the first path and the second path of the optical coupler, the first path is connected to the first path. An optical switch for switching the multiplexed optical signal into a Gaussian optical demultiplexer (ODX); A Gaussian optical demultiplexer (ODX) which demultiplexes the multiplexed optical signal into the first to Nth optical signals; And And a first optical detector to an Nth optical detector for converting the demultiplexed first optical signals to the Nth optical signals into electrical signals and transmitting the electrical signals to the first channel card to the Nth channel card, respectively. Dig Optical line terminal (OLT: Optical Line Terminal) characterized in that it comprises a. The method of claim 6, The Gaussian optical demultiplexer (ODX) has an optical characteristic that a filter pattern of the same band is formed at a space that is spaced apart by a multiple of a free spectral range (FSR) based on an arrayed waveguide grating (AWG) and a Gaussian channel. Optical line terminal (OLT: Optical Line Terminal) characterized in that it has a transmission characteristic. The method of claim 1, The optical line terminal (OLT) is an optical line terminal (OLT), characterized in that part of the configuration of a wavelength division multiplexing-passive optical network (WDM-PON). delete delete delete delete delete delete delete delete

Images