KR100947711B1 - WDM-TDM hybride optical network and self defection method of optical channel problem thereof - Google Patents

Abstract

The present invention provides a method for the OLT and WDM-TDM conversion apparatus in a WDM-TDM composite optical network combining a time division multiplexing-passive optical network (TDM-PON) with a wavelength division multiplexing (WDM) technique. The present invention relates to a technique for mutually diagnosing a channel failure between each WDM optical transceiver (TRx).

Such a WDM-TDM composite optical network includes an optical line terminal (OLT) including M first WDM optical transceivers for generating a downlink WDM optical signal; And a second WDM optical transceiver for converting the downlink WDM optical signal into a downlink electrical signal and a TDM optical transceiver for converting the downlink electrical signal into a downlink TDM optical signal, and generating an arbitrary pattern. And a WDM-TDM conversion device control unit for transmitting the same to the first WDM optical transceiver of the OLT using the second WDM optical transceiver; And an OLT control unit for inspecting the pattern transmitted through the first WDM optical transceiver and transmitting the pattern back to the second WDM optical transceiver if the pattern is normal, wherein the WDM-TDM converter control unit is configured to transmit the first WDM optical transceiver. If the pattern returned to the second WDM optical transceiver is abnormal by the characteristic configuration it is determined that the failure of the receiving apparatus of the second WDM optical transceiver or the transmitting apparatus of the first WDM optical transceiver.

Hybrid, passive optical network, PON, WDM, TDM, hybrid

Description

WDM-TDM hybrid optical network and channel fault self-diagnosis method using the same. {WDM-TDM hybride optical network and self defection method of optical channel problem}

The present invention provides a method for the OLT and WDM-TDM conversion apparatus in a WDM-TDM composite optical network combining a time division multiplexing-passive optical network (TDM-PON) with a wavelength division multiplexing (WDM) technique. The present invention relates to a technique for mutually diagnosing channel failure between WDM optical transceivers (TRx).

With the recent rapid increase in Internet traffic and the convergence of broadcasting and telecommunication services, the speed of subscriber networks has been increasing rapidly. Among these technologies, passive optical network (PON) technology is introduced due to the advantages of not only providing high bandwidth to subscribers but also significantly reducing the operating cost of the network because the OSP (outside plant) is composed of only passive components. This is spreading.

The PON technology is classified into two types according to the difference of multiplexing and multiple access methods. The first is TDM-PON based on time division multiplexing, and the second is WDM-PON based on wavelength division multiplexing.

Figure 1 shows a schematic diagram showing the configuration of a conventional general TDM-PON. TDM-PON is a structure in which subscribers share optical fiber with the optical line terminal (OLT) of a national company by using time division techniques, and B-PON and G-PON standardized by ITU-T, E-PON standardized by IEEE, etc. This is currently used.

Looking at the current transmission method of the general TDM-PON, one optical transceiver is installed in the optical line terminal (OLT) of the country side in terms of the downlink signal to broadcast the traffic delivered to each subscriber, A remote node (RN) uses a 1xN optical splitter that simply splits optical power, distributing the downlink optical signal transmitted from the OLT to N subscriber lines. The network termination or optical network unit (ONU) receives the downlink signal from the OLT and selectively transmits only the frames allocated to the subscriber.

On the other hand, when the uplink signal is transmitted, the subscriber's ONT or ONU is allocated a dedicated time slot from the OLT in advance through a ranging process, and then only when the time slot allocated to the subscriber arrives. When the uplink data is transmitted and not in its own slot, the optical transmitter is turned off completely. The uplink signal from each subscriber is combined in the optical splitter of the remote node and transmitted to the OLT.

In general, fixed wavelength light sources of 1480 nm to 1500 nm are used for OLT, and fixed wavelength light sources of 1260 nm to 1360 nm are used for ONT / ONU of subscriber side, but the possibility of changing the up and down wavelengths in the next generation of TDM-PON and downward Increasing bandwidth by distributing signals to optical transceivers having various wavelengths has been discussed in the standardization organization. However, TDM-PON has a problem that the transmission loss increases with the increase of the branch rate because the remote node is composed of the optical power splitter. As a result, TDM-PON has a limited bandwidth and branching rate of about 64 quarters at 2.5Gb / s shared bandwidth.

Unlike TDM-PON, which shares an optical line using time division multiplexing, the WDM-PON shown in FIG. 2 has a difference in that an optical line is shared using a wavelength division multiplexing technique. As shown in FIG. 2, the WDM-PON logically implements point-to-point connection by allocating dedicated uplink (λum) _and downlink wavelength (λdm) to M subscribers. There is no need for a time slot allocation process through complex ranging.

In OLT, M optical transceivers assigned to each subscriber are installed, they are combined in WDM wavelength branch combiner and transmitted by optical line, and are simply distributed to each subscriber by wavelength channel in WDM wavelength branch combiner installed in remote node. Has

The WDM system having such a structure is basically multiplexed in the physical layer and transmission transparency is ensured in the upper layer, thereby synchronous digital hierarchy (SDH) / synchronous network (SONET), asynchronous transfer mode (ATM), and GFP other than Ethernet. It is also possible to send a Generic Frame Procedure. WDM-PON provides logical point-to-point connectivity through wavelength assignment, provides greater security than broadcast-based TDM-PON, and increases bandwidth and fiber bandwidth per fiber simply by adding wavelength. There are advantages such as relatively easy to increase, but also has the disadvantage that the light source required for WDM is relatively expensive compared to the TDM-PON light source.

As a WDM light source for WDM-PON, CWDM (coarse WDM), DWDM (dense WDM) fixed wavelength light source and DWDM wavelength independent light source are used. As a DWDM wavelength independent light source technology, a wavelength tunable laser can be used. In addition, a seed light source such as a broadband light source or a laser array is used to seed a FP (fabry-perot) laser or a reflective semiconductor optical amplifier (RSAA). And a method of spectrally dividing and injecting a light source. In addition, an optical link configuration method for generating uplink signals by remodulating downlink signals to RSOA is being researched and developed.

Therefore, a wavelength division multiplexing / time division multiplexing (WDM-TDM) composite optical network has been proposed to provide an optical network for a subscriber network having low construction and operation costs by increasing transmission bandwidth and branching rate per optical fiber.

The WDM-TDM composite optical network includes a first WDM optical wavelength that combines M first WDM optical transceivers including a WDM light source and M downlink WDM individual wavelength optical signals received from the M first WDM optical transceivers to generate a downlink WDM optical signal. An optical line terminal (OLT) including a wavelength branching combiner, a second WDM wavelength branching combiner for wavelength-dividing the downward WDM optical signal to generate M downlink WDM individual wavelength optical signals, and receiving the downward WDM individual wavelength optical signal And a second WDM optical transceiver for converting the downlink electrical signal into a downlink TDM optical signal, and a WDM-TDM matching unit for connecting the second WDM optical transceiver and the second TDM optical transceiver. And a WDM-TDM conversion device for power branching each of the downlink TDM optical signals into N optical signals and power combining the uplink TDM optical signals. Includes an optical splitter and an optical nerwork termination (ONT) for receiving a downlink TDM optical signal that is power branched from the optical splitter.

Here, the conventional optical transceivers (TRx) in the existing WDM-PON and TDM-PON are mainly responsible for the function of the physical (PHY) layer, and the optical transceiver (Tx-PON) does not have a function for checking and confirming normal operation by self-diagnosis. The normal operation of the TRx) was to check if the traffic can be properly transmitted and received in the upper layer (MAC layer).

This is because the existing WDM-PON, TDM-PON, etc., the link configuration in which the optical transceiver (TRx) operates is a single section configuration, that is, a 1: 1 relationship between the OLT and the ONT, so that it does not cause a big problem in determining the failure. I did not.

However, for WDM-TDM complex optical networks, WDM, such as OLT↔WDM-TDM↔ONT converter or OLT↔WDM-TDM converter↔WDM-TDM converter↔ONT (when WDM-TDM converter is configured in multiple stages) Since the TDM converter has a complicated optical network structure that can be configured in multiple stages, it is difficult to determine whether there is a failure in a specific section by only user traffic.

In particular, the OLT↔WDM-TDM conversion device section is the first section that is connected to the OLT, which is the device on the national side, and the complex photonic device is used the most. Of course, it is possible to check whether there is an obstacle in a certain section by using optical instruments such as OTDR, such as optical power and loss, but this may cause problems such as cost increase, operation complexity, and service disconnection due to the introduction of external instruments. Entails.

The present invention provides a WDM-TDM composite optical network capable of mutually diagnosing channel failure between optical transceivers in an OLT↔WDM-TDM conversion device section in which a failure may occur without introducing an external instrument, and a channel failure self-diagnosis method using the same. I would like to.

WDM-TDM composite optical network of the present invention for achieving the above object is an optical line terminal (OLT) including M first WDM optical transceiver for generating a downlink WDM optical signal; And a second WDM optical transceiver for converting the downlink WDM optical signal into a downlink electrical signal and a TDM optical transceiver for converting the downlink electrical signal into a downlink TDM optical signal, and generating an arbitrary pattern. And a WDM-TDM conversion device control unit for transmitting the same to the first WDM optical transceiver of the OLT using the second WDM optical transceiver; And an OLT control unit for inspecting the pattern transmitted through the first WDM optical transceiver and transmitting the pattern back to the second WDM optical transceiver if the pattern is normal, wherein the WDM-TDM converter control unit is configured to transmit the first WDM optical transceiver. If the pattern returned to the second WDM optical transceiver is abnormal by the characteristic configuration it is determined that the failure of the receiving apparatus of the second WDM optical transceiver or the transmitting apparatus of the first WDM optical transceiver.

Here, if the pattern transmitted through the first WDM optical transceiver is abnormal, the OLT control unit of the present invention determines that the failure of the receiver of the first WDM optical transceiver or the transmitter of the second WDM optical transceiver.

Here, the pattern of the present invention consists of a combination of information and a transmission channel number of an optical transceiver.

The information of the optical transceiver of the pattern of the present invention is one or more of product name, product serial, and version information of the optical transceiver.

On the other hand, the channel failure self-diagnosis method using the WDM-TDM composite optical network according to the present invention includes: a) the WDM-TDM conversion device control unit generates an arbitrary pattern, and uses the second WDM optical transceiver for the first WDM optical transceiver of the OLT. Delivering to; b) the WDM-TDM conversion device control unit checking the returned pattern if the pattern transmitted to the first WDM optical transceiver of the OLT is checked by the OLT control unit as a normal pattern and returned to the second WDM optical transceiver again; And c) checking, by the WDM-TDM conversion device control unit, the pattern returned to the second WDM optical transceiver and determining that the pattern is abnormal as a failure of the receiving device of the second WDM optical transceiver or the transmitting device of the first WDM optical transceiver. It is set as the characteristic structure to include.

Wherein step a) of the present invention is made at a set cycle interval.

Here, step a) of the present invention is performed whenever the WDM-TDM conversion device detects that a new second WDM optical transceiver is installed in the WDM-TDM conversion device.

Meanwhile, in the present invention, if the pattern transmitted to the first WDM optical transceiver does not return again, the WDM-TDM converter control unit receives the second WDM optical transceiver or the transmission device of the first WDM optical transceiver. And determining the failure of the device.

On the other hand, the present invention further includes determining the failure of the transmitter of the first WDM optical transceiver or the receiver of the second WDM optical transceiver if the pattern does not return within the set time in step b)).

Herein, when the WDM-TDM converter control unit determines that the receiving device of the second WDM optical transceiver or the transmitting device of the first WDM optical transceiver is faulty, it notifies the operator.

On the other hand, a channel failure self-diagnosis method using a WDM-TDM composite optical network includes: a) the first WDM optical transceiver of the OLT is generated by the WDM-TDM converter control unit as information of the second WDM optical transceiver and transmitted through the second WDM optical transceiver; Passing any pattern to the OLT control unit; And b) the OLT control unit inspecting a pattern received from the first WDM optical transceiver; And c) if the pattern is normal, the OLT control unit transmits the pattern back to the second WDM optical transceiver of the WDM-TDM converter so that the WDM-TDM converter control unit returns the abnormal pattern returned from the first WDM optical transceiver of the OLT. And determining a failure of the receiver of the optical transceiver or the transmitter of the first WDM optical transceiver.

The present invention further includes the step of b ') in step b), if the pattern is abnormal, determining that the OLT control unit is a failure of the receiver of the first WDM optical transceiver or the transmitter of the second WDM optical transceiver.

Herein, in the present invention, if the OLT control unit determines the failure of the receiver of the first WDM optical transceiver or the transmitter of the second WDM optical transceiver in step b ′), the OLT control unit notifies the operator.

The present invention can reduce the cost of each other through the pattern transmission and reception between the optical transceiver of the optical line terminal (OLT) and the WDM-TDM converter without using a separate external measuring device and a higher layer (MAC) It is easy to operate and can minimize the service disconnection time by prompt failure determination.

In addition, the present invention is a range that does not interfere with the traffic by using a combination of the information of the optical transceiver and the transmission channel number of the optical transceiver irrespective of the transmission and reception traffic between the conventional optical line terminal (OLT) and the WDM-TDM conversion device It is possible to grasp the fault state of the optical line terminal (OLT) and the WDM-TDM conversion apparatus within the apparatus.

In addition to the basic operation mode of generating a random pattern at a set period using the WDM-TDM converter control unit and transmitting it to the OLT side, the present invention is also provided when a new second WDM optical transceiver is installed in the WDM-TDM converter. By generating a random pattern using the information and the transmission channel number of the new second WDM optical transceiver sensed each time and transmitting it to the OLT side, it is possible to exert the effect of improving the speed and stability of network maintenance.

In addition, the present invention, if the WDM-TDM converter control unit and the OLT converter control unit determines the failure of the transmitter or receiver of the optical transceiver to notify the operator immediately to send or receive the transmission apparatus or reception of the corresponding optical transceiver determined to the operator Since the replacement of the device is encouraged, it is possible to reduce the network downtime caused by the failure of the optical transceiver.

In addition, the ONT connected to the optical splitter of the WDM-TDM composite optical network of the present invention, because the optical transceiver is turned off in order to avoid collision with other ONTs when not in use, WDM- By determining whether or not the corresponding transmission / reception channel is disturbed between the OLT and the ONT through mutual transmission and reception of the pattern of the optical transceiver between the TDM conversion device and the OLT, it is possible to determine whether or not the channel is not affected by the operation of the optical transmission / reception device of the ONT. Can be exercised.

Hereinafter, with reference to the accompanying drawings will be described specific details for the practice of the invention.

As shown in FIG. 3, the WDM-TDM composite optical network 100 according to the present invention is basically an optical line terminal (OLT) 10, a WDM-TDM conversion apparatus 20, an optical splitter 30, and an ONT. optical nerwork termination (40) and the like.

Hereinafter, each component will be described.

As shown in FIG. 3, the optical line terminal (OLT) 10 is largely a TDM-PON MAC & PHY, a first WDM optical transceiver 12, a first WDM wavelength branch combiner 14, and an OLT control unit 16. And so on.

The TDM-PON MAC & PHY is provided in M-to-one correspondence with M first WDM optical transceivers 12 to transmit downlink TDM electrical signals to the M first WDM optical transceivers 12.

The first WDM optical transceiver 12 is provided as M to convert individual downlink TDM electrical signals received from M TDM-PON MAC & PHY into downlink WDM individual wavelength optical signals and transfer them to the first WDM wavelength branch combiner 14. Play a role.

The first WDM wavelength branch combiner 14 wavelength-couples the M downlink WDM individual wavelength optical signals received from the M first WDM optical transceivers 12 to generate a downlink WDM optical signal.

The OLT control unit 16 is connected to all the first WDM optical transceivers 12, respectively, so that the information of the first WDM optical transceiver 12, namely product name, product serial, from each of the first WDM optical transceivers 12, respectively. The first WDM optical transceiver receives version information and the like at a setting cycle, grasps the transmission channel numbers assigned to the first WDM optical transceivers 12, respectively, and determines the total number of transmission channels as the setting cycle. It records the total number of transport channels according to the information of 12) and transport channel number in a separate database.

In addition, the OLT control unit 16 checks whether the pattern of the first WDM optical transceiver 12 of the OLT 10 received from the second WDM optical transceiver 24 of the WDM-TDM conversion device 20 is normal and abnormal. .

In this case, the OLT control unit 16 checks whether the pattern is normal or abnormal by checking the frame size of the packet of the received pattern by checking whether the packet is an intact packet, or determining the received packet by CRC (Cyclic). redundancy check).

In addition, the OLT control unit 16 receives the pattern from the second WDM optical transceiver 24 of the WDM-TDM conversion device 20 when the first WDM optical transceiver 12 receives the pattern from the second WDM optical transceiver 24. The combination of the information and the transmission channel number is added to the pattern and serves to transmit it to the second WDM optical transceiver 24 of the WDM-TDM conversion device 20 again.

On the other hand, the WDM-TDM converter 20 is largely divided into a second WDM wavelength branch combiner 22, a second WDM optical transceiver 24, a second TDM optical transceiver 26, a WDM-TDM matching unit 28, and a WDM-TDM conversion. Device control unit 29 and the like.

The second WDM wavelength branch combiner 22 serves to generate M downlink WDM individual wavelength optical signals by wavelength-dividing the downward WDM optical signal received from the first WDM wavelength branch combiner 14 of the OLT 10.

The second WDM optical transceiver 24 serves to receive the downlink WDM individual wavelength optical signal generated by the second WDM wavelength branch combiner 22 and convert it into a downlink electrical signal.

The second TDM optical transceiver 26 converts the downlink electrical signal converted from the second WDM optical transceiver 24 into a downlink TDM optical signal and transmits the downlink TDM optical signal to the optical splitter 30.

On the other hand, the WDM-TDM matching unit 28 serves to connect the second WDM optical transceiver 24 and the second TDM optical transceiver 26.

The WDM-TDM converter control unit 29 is connected to all the second WDM optical transceivers 24, respectively, so that the information of the second WDM optical transceivers 24, namely product name, product, from all the second WDM optical transceivers 24, respectively. The second WDM optical transceiver receives serial, version information, etc. at a setting cycle, grasps the transmission channel number assigned to the second WDM optical transceiver 24 to determine the total number of transmission channels as the setting cycle, and receives and receives the second WDM optical transceiver at the setting cycle. It records the total number of transport channels according to the information of 24) and transport channel number in a separate database.

In addition, the WDM-TDM converter control unit 29 generates a pattern by using the information and the transmission channel number of the corresponding second WDM optical transceiver 24 to perform a diagnosis, the first WDM optical transceiver 12 of the OLT 10 ) Is used to send.

At this time, if the pattern transmitted to the first WDM optical transceiver 12 of the OLT 10 is returned by the first WDM optical transceiver 12 of the OLT 10 again, the returned pattern is inspected.

In this case, the normality and abnormality of the pattern of the WDM-TDM conversion device control unit 29 are determined by examining the size of each packet of the received pattern of the received pattern to determine whether the packet is an intact packet or the received packet. It is determined by checking the CRC (Cyclic redundancy check).

Here, the WDM-TDM conversion device control unit 29 of the present invention is generated based on the information of the second WDM optical transceiver 24 and the transmission channel number, and the information of the first WDM optical transceiver 12 by the OLT control unit 16. And the pattern to which the transmission channel number is added do not necessarily include information of the optical transceiver and the transmission channel number.

That is, the pattern is transmitted by the second WDM optical transceiver 24 under the control of the WDM-TDM converter control unit 29 to the first WDM optical transceiver 12 of the OLT when the pattern is transmitted. ) Allows the OLT control unit 16 connected to the controller to examine the received pattern so that it knows only whether the pattern has arrived in its normal state, and the OLT control unit 16 that has received the pattern is again in WDM-TDM When sent back to the second WDM optical transceiver 24 of the converter, the WDM-TDM converter control unit 29 checks the pattern returned to the second WDM optical transceiver 24 to confirm that the pattern has arrived in a normal state. Just do it.

However, the reason why the WDM-TDM converter control unit 29 forms the pattern by combining the information and the transmission channel number of the second WDM optical transceiver 24 is that the first WDM optical transceiver 12 of the OLT is connected with itself. This is to confirm the information and the transmission channel number of the second WDM optical transceiver 24 of the communicating WDM-TDM converter.

The reason why the OLT control unit 16 adds the information and the transmission channel number of the first WDM optical transceiver 12 to the pattern received from the second WDM optical transceiver 24 is the same.

On the other hand, the optical splitter 30 serves to power branch each of the downlink TDM optical signals received from the WDM-TDM converter 20 into N optical signals and to power couple the uplink TDM optical signals.

Meanwhile, the ONT 40 receives the downlink TDM optical signal branched from the optical splitter 30 and transmits the uplink TDM optical signal to the optical splitter 30.

Looking at the transmission of the downlink signal of the WDM-TDM composite optical network according to the present invention configured as described above.

In the OLT 10 of FIG. 3, M TDM-PON MAC & PHYs correspond to M first WDM optical transceivers 12 one-to-one.

As shown in FIG. 3, the first WDM optical transceiver 12 includes a WDM light source, and the downlink WDM individual wavelength light having M different wavelengths λ d1 to λ dM from the first WDM optical transceiver 12. The signal is sent to a first WDM wavelength branch combiner 14, which is wavelength coupled to a downlink WDM optical signal. The downlink WDM optical signal is transmitted to the WDM-TDM conversion apparatus 20. The WDM-TDM conversion apparatus 20 converts the downlink WDM optical signal into M downlink TDM optical signals into optical-to-optical conversion. The M downlink TDM optical signals are each transmitted to M optical splitters 30. Each optical splitter 30 power-branches down TDM optical signals into N, and the branched N down TDM optical signals are transmitted to ONT 40, which is a subscriber device.

Meanwhile, the downlink signal transmission of the WDM-TDM composite optical network according to the present invention will be described.

As shown in FIG. 3, first, an uplink TDM optical signal is transmitted to the optical splitter 30 in the ONT 40 which is a subscriber device. The optical splitters 30 power-couple the N upstream TDM optical signals transmitted from the ONT 40 into the upstream TDM optical signals, respectively. The power coupled uplink TDM optical signal is transmitted to the WDM-TDM conversion device 20. The WDM-TDM conversion apparatus 20 converts the M uplink TDM optical signals into upstream WDM optical signals through optical-to-optical conversion and transmits them to the OLT 10. Inside the OLT 10, the uplink WDM optical signal is first received at the first WDM wavelength branch combiner 14. The first WDM wavelength branch combiner 14 wavelength-divides the received uplink WDM optical signal into M uplink WDM individual wavelength optical signals λu1 to λuM. The M uplink WDM discrete wavelength optical signals are each transmitted to a first WDM optical transceiver 12. The first WDM optical transceiver 12 converts the received uplink WDM individual wavelength optical signal into an electrical signal, and transmits the electrical signal to the TDM-PON OLT 10 MAC & PHY to transmit the TDM-PON OLT 10 MAC & PHY. Allow the PHY to work.

Meanwhile, the downlink signal transmission in the WDM / TDM conversion apparatus according to the present invention will be described.

As shown in FIG. 3, the case of the wavelength-coupled downlink WDM optical signal received from the OLT 10 will be described first. The downlink WDM optical signal is received by the second WDM wavelength branch combiner 22 in the WDM-TDM conversion device 20. The second WDM wavelength branch combiner 22 splits the downward WDM optical signal into wavelengths and splits the downward WDM optical signal into M downward WDM individual wavelength optical signals having different wavelengths λd1 to λdM. The downlink WDM discrete wavelength optical signal is transmitted to a second WDM optical transceiver 24. The downlink WDM individual wavelength optical signal received by the second WDM optical transceiver 24 is converted into an electrical signal and transmitted to the WDM-TDM matching unit 28. The WDM-TDM matching unit 28 receives the electrical signal and transmits it to the second TDM optical transceiver 26. The second TDM optical transceiver 26 converts the received electrical signal into a downlink TDM optical signal and transmits it to the optical splitter 30. The WDM-TDM matching unit 28 serves to connect the second WDM optical transceiver 24 and the second TDM optical transceiver 26. For the specific connection, the second TDM optical transceiver 26 is a conventional TDM-PON. The optical transceiver used for the OLT 10 may be used.

Meanwhile, the transmission of uplink signals in the WDM / TDM conversion apparatus according to the present invention will be described.

As shown in FIG. 3, a process in which the uplink TDM optical signal received from the ONT 40 via the optical splitter 30 is transmitted by the WDM-TDM conversion apparatus 20 will be described. The uplink TDM optical signal is first received by a second TDM optical transceiver 26. The uplink TDM optical signal received by the second TDM optical transceiver 26 is converted into an electrical signal and transmitted to the WDM-TDM matching unit 28. The WDM-TDM matching unit 28 receives the electrical signal and transmits it to the second WDM optical transceiver 24. The second WDM optical transceiver 24 converts the received electrical signal into an uplink WDM individual wavelength optical signal and transmits it to the second WDM wavelength branch combiner 22. The second WDM wavelength branch combiner 22 wavelength-combines M uplink WDM individual wavelength optical signals having different wavelengths λu1 to λuM into an uplink WDM optical signal and transmits the same to the OLT 10.

The channel failure self-diagnosis method using the WDM-TDM composite optical network according to the present invention configured as described above will be described.

As shown in FIG. 5, first, the WDM-TDM conversion device control unit 29 periodically receives respective optical transceiver information from the second WDM optical transceivers 24 of the WDM-TDM conversion device 20. The total number of transport channels is determined by identifying transport channel numbers assigned to the second WDM optical transceivers 24 (S100).

Here, the transmission channel number may be any one of a serial number assigned to the second WDM optical transceiver 24 or a frequency band recording an area code or a frequency band assigned according to an area, or a combination of any one or more of them. Instead, if the number of second WDM optical transceivers 24 can be grasped, various modifications can be applied to the present invention.

Subsequently, the WDM-TDM converter control unit 29 detects whether there is a newly installed second WDM optical transceiver 24 (S102), and if a new 2WDM optical transceiver is found, the new second WDM optical transceiver 24 found. Receives the information of the optical transceiver and the transmission channel number of the optical transceiver and records it in a database (S104), and generates a pattern based on the information of the newly discovered optical transceiver and the transmission channel number of the optical transceiver and re-creates the second WDM optical signal. By transmitting to the transceiver 24, the second WDM optical transceiver 24 transmits the pattern to the first WDM optical transceiver 12 of the OLT 10 (S106).

However, if the WDM-TDM converter control unit 29 does not find the newly installed second WDM optical transceiver 24, the WDM-TDM converter operates in a diagnostic mode at a set cycle to diagnose the second WDM optical transceivers 24 sequentially. S105). That is, the WDM-TDM converter control unit 29 already receives the information of each of the second WDM optical transceivers 24 periodically, and grasps the transmission channel numbers assigned to the second WDM optical transceivers 24, respectively. Since the total number of transmission channels is grasped, the 2WDM optical transceivers corresponding to the number of transmission channels are sequentially diagnosed on the basis of a randomly set principle, so that the information of the second WDM optical transceiver 24 and the second WDM optical transceiver are in order. A pattern is generated based on the transmission channel number of the transceiver 24 and transmitted to the second WDM optical transceiver 24 so that the second WDM optical transceiver 24 transmits the pattern to the first WDM optical transceiver 12 of the OLT 10. To transmit (S106).

Subsequently, the WDM-TDM converter control unit 29 checks that the pattern transferred to the first WDM optical transceiver 12 of the OLT 10 is in a normal pattern by the OLT control unit 16, and again the second WDM optical transceiver ( Returning to 24), the returned pattern is inspected (S110). At this time, if the pattern transmitted to the first WDM optical transceiver 12 does not return again, the WDM-TDM conversion device control unit 29 may determine the transmission of the first WDM optical transceiver 12 or the second WDM optical transceiver 24. It is determined that the reception device is a failure (S108), and this is determined as a failure of the reception device of the second WDM optical transceiver 24 or the transmission device of the first WDM optical transceiver 12 (S109).

In this case, when the pattern returned to the second WDM optical transceiver 24 is examined as a result of S110, if the pattern is abnormal, it is determined as a failure of the receiving apparatus of the second WDM optical transceiver 24 or the transmitting apparatus of the first WDM optical transceiver 12. (S109).

If the WDM-TDM conversion device control unit 29 determines that the receiving device of the second WDM optical transceiver 24 or the transmitting device of the first WDM optical transceiver 12 is in error in step S109, the WDM-TDM conversion device control unit 29 may send an operator's mail or text message. Notify using (S109).

Herein, if the WDM-TDM conversion device control unit 29 checks the pattern returned to the second WDM optical transceiver 24 and the present pattern is normal, the WDM-TDM conversion device control unit 29 of the receiving device of the second WDM optical transceiver 24 or the first WDM optical transceiver 12 The transmitter determines that it is normal (S112).

Subsequently, the WDM-TDM converter control unit 29 compares the number of second WDM optical transceivers 24 diagnosed so far with the total number of transmission channels (S114), and the second WDM optical transceivers 24 diagnosed thus far. The number of times continues to return to step S100 until the total number of transmission channels is determined to perform the diagnosis of the second WDM optical transceiver 24 remaining.

The fault self-diagnosis of the channel has been described so far from the viewpoint of the WDM-TDM conversion device control unit 29, and the fault self-diagnosis of the channel is now described from the viewpoint of the OLT control unit 16.

As shown in FIG. 4, the OLT control unit 16 first receives information and a transmission channel number of the first WDM optical transceiver at a set cycle to maintain and record the state of the first WDM optical transceiver (S200). The WDM-TDM Determines whether any pattern generated by the converter control unit 29 as information of the second WDM optical transceiver 24 and transmitted through the second WDM optical transceiver 24 has been transmitted to the first WDM optical transceiver 12 In operation S202, when the first WDM optical transceiver 12 receives an arbitrary pattern from the second WDM optical transceiver 24, the received pattern is inspected (S204).

If the pattern is normal, the OLT control unit 16 transmits the pattern to the second WDM optical transceiver 24 of the WDM-TDM conversion apparatus 20 again (S206), and checks that the pattern of the first WDM optical transceiver 12 The receiver or the second WDM optical transceiver 24 transmitter determines that it is normal (S208).

Here, if the pattern is abnormal, the OLT control unit 16 determines that the reception device of the first WDM optical transceiver 12 or the second WDM optical transceiver 24 is a failure of the transmission device (S207), and this is an operator's mail or text message. You will be notified using.

Of course, the OLT control unit 16 is a failure situation of the transmission device of the first WDM optical transceiver 12, the information and transmission channel number of the corresponding first WDM optical transceiver 12 previously built in the database, and the first The 2WDM optical transceiver 24 transmits the information of the transmitter and the transmission channel number to the operator so that the operator can quickly identify the faulty first WDM optical transceiver 12.

Here, the WDM-TDM conversion device control unit 29 of the present invention first transmits the pattern to the OLT control unit 16. The WDM-TDM conversion device 20 is additionally installed in accordance with an increase in subscriber acceptance. Has properties This is because additional device deployment based on the service needs of the subscriber is more cost-effective than batch deployment.

Therefore, in the present invention, the WDM-TDM conversion device control unit 29 for detecting a new installation of the WDM-TDM conversion device 20 in order for the operator to immediately recognize that the WDM-TDM conversion device 20 is normally operated as soon as it is additionally installed. In order to confirm the operation of the newly installed WDM-TDM conversion apparatus 20, the first combination of the device information and the transmission channel number of the WDM-TDM conversion apparatus 20 is first transmitted to the OLT 10.

As mentioned above, although the present invention has been described by means of a limited configuration and drawings, the technical idea of the present invention is not limited to the above, and by those skilled in the art to which the present invention pertains, Various modifications and variations may be made without departing from the scope of the appended claims.

1 is a configuration diagram briefly showing the configuration of a conventional general TDM-PON.

Figure 2 is a schematic diagram showing the configuration of a conventional general WDM-PON.

Figure 3 is a schematic diagram showing the configuration of a WDM-TDM composite optical network according to the present invention.

4 is a flowchart illustrating a channel failure self-diagnosis method using an OLT control unit in a WDM-TDM composite optical network according to the present invention.

5 is a flowchart illustrating a channel failure self-diagnosis method using a WDM-TDM conversion device control unit in a WDM-TDM composite optical network according to the present invention.

Description of the main symbols in the drawings

100: WDM-TDM composite optical network

10: OLT 12: 1st WDM Optical Transceiver

14: first WDM wavelength branch combiner 16: OLT control unit

20: WDM-TDM Converter

22: second WDM wavelength branch combiner 24: second WDM optical transceiver

26: second TDM optical transceiver 28: WDM-TDM matching unit

29: WDM-TDM converter control unit

30: optical splitter

40: ONT

Claims (13)

In the WDM-TDM composite optical network, An optical line terminal (OLT) including M first WDM optical transceivers for generating a downlink wavelength division multiplexing (WDM) optical signal; And a second WDM optical transceiver for converting the downlink WDM optical signal into a downlink electrical signal and a TDM optical transceiver for converting the downlink electrical signal into a downtime division multiplexing (TDM) optical signal; And A WDM-TDM conversion device control unit for generating an arbitrary pattern and transferring it to the first WDM optical transceiver of the OLT using the second WDM optical transceiver; And an OLT control unit for inspecting the pattern transmitted through the first WDM optical transceiver and transmitting the pattern back to the second WDM optical transceiver if the pattern is normal. The WDM-TDM converter control unit determines that the pattern returned by the first WDM optical transceiver to the second WDM optical transceiver is abnormal as a failure of the receiving device of the second WDM optical transceiver or the transmitting device of the first WDM optical transceiver. WDM-TDM composite optical network. The method of claim 1, And if the pattern transmitted through the first WDM optical transceiver is abnormal, determines that the OLT control unit is a failure of the receiving device of the first WDM optical transceiver or the transmitting device of the second WDM optical transceiver. The method according to claim 1 or 2, And the pattern is a combination of information of a second WDM optical transceiver of the WDM-TDM converter and a transmission channel number of the optical transceiver. The method of claim 3, The information of the optical transceiver of the pattern is WDM-TDM composite optical network, characterized in that any one or more of the product name, product serial, version information of the optical transceiver. a) the WDM-TDM conversion device control unit generates an arbitrary pattern and passes it to the first WDM optical transceiver of the OLT using the second WDM optical transceiver; b) the WDM-TDM conversion device control unit checking the returned pattern if the pattern transmitted to the first WDM optical transceiver of the OLT is checked by the OLT control unit as a normal pattern and returned to the second WDM optical transceiver again; And c) checking, by the WDM-TDM conversion device control unit, the pattern returned to the second WDM optical transceiver and determining that the pattern is abnormal as a failure of the receiving device of the second WDM optical transceiver or the transmitting device of the first WDM optical transceiver. A channel failure self-diagnosis method using a WDM-TDM composite optical network, characterized in that. The method of claim 5, Step a) is a channel failure self-diagnosis method using a WDM-TDM composite optical network characterized in that the set interval. The method of claim 5, Step a) is performed whenever the WDM-TDM conversion device detects that a new second WDM optical transceiver is installed in the WDM-TDM conversion device control unit. Way. The method of claim 5, b ') In step b), if the pattern transmitted to the first WDM optical transceiver does not return again, the WDM-TDM converter control unit determines that the failure of the transmitting apparatus of the first WDM optical transceiver or the receiving apparatus of the second WDM optical transceiver is determined. Channel failure self-diagnosis method using a WDM-TDM composite optical network characterized in that it further comprises the step. The method of claim 5, b '') If the pattern does not return again within the set time in step b), the WDM-TDM converter controlling unit determines that the failure of the transmitter of the first WDM optical transceiver or the receiver of the second WDM optical transceiver Channel failure self-diagnostic method using WDM-TDM composite optical network, characterized in that further comprising. The method according to any one of claims 5, 8 or 9, and d) notifying the operator when the WDM-TDM converter control unit determines a failure of the receiver of the second WDM optical transceiver or the transmitter of the first WDM optical transceiver. Channel disorder self-diagnosis using a) the first WDM optical transceiver of the OLT forwarding to the OLT control unit any pattern generated by the WDM-TDM conversion device control unit and transmitted through the second WDM optical transceiver; And b) checking, by the OLT control unit, a pattern received from a first WDM optical transceiver; And c) If the pattern is normal, the OLT control unit transmits the pattern back to the second WDM optical transceiver of the WDM-TDM conversion device, thereby causing the WDM-TDM conversion device control unit to return the second WDM optical signal if the pattern returned from the first WDM optical transceiver of the OLT is abnormal. A method for self-diagnosing a channel failure using a WDM-TDM composite optical network, comprising determining a failure of a receiver of a transceiver or a transmitter of a first WDM optical transceiver. The method of claim 11, b ') In step b), if the pattern is abnormal, the OLT control unit further comprises determining that the failure of the receiver of the first WDM optical transceiver or the transmitter of the second WDM optical transceiver, WDM-TDM composite optical Channel failure self-diagnosis using network. The method of claim 12, b '') WDM-TDM composite further comprises the step of notifying the operator when the OLT control unit determines the failure of the receiver of the first WDM optical transceiver or the transmitter of the second WDM optical transceiver in step b '). Channel failure self-diagnosis using optical network.

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