KR100811423B1 - Wavelength-tunable transceiver for wavelength independent wdm networks and wavelength alignment method in the transceiver - Google Patents

Abstract

A wavelength-tunable transceiver for wavelength independent WDM networks and a wavelength alignment method in the same are provided to adopt a wavelength control light source to an optical transceiver as maintaining compatibility with the existing optical transceiver by having an optical transceiver's structure for connection with a WDM system. In a wavelength control light source(13), a wavelength of outputted light is varied. A wavelength monitoring unit(14) monitors change of the output wavelength of the wavelength control light source. A wavelength controller(15) controls an output wavelength of the wavelength control light source according to a correction signal. An external power monitoring unit(16) monitors change of external power supplied for operations of the wavelength controller independently of inner power supplied through a standard interface. A controller(22) generates the correction signal for controlling the operations of the wavelength controller according to monitoring information from the wavelength monitoring unit and wavelength information pre-assigned from an OLT(Optical Line Terminal). According to monitoring information from the external power monitoring unit, the controller reports an abnormality generation state of the external power to a WDM(Wavelength Division Multiplexing) system through the standard interface.

Description

Wavelength-tuned transceiver for wavelength independent WDM networks and wavelength alignment method in the transceiver

1 is a block diagram showing the configuration of an optical transmitting and receiving device according to the standards of conventional GBIC and SFP.

2 is a block diagram showing the configuration of a wavelength-controlled optical transmission / reception apparatus for a wavelength independent wavelength division multiplexing optical network according to the present invention.

FIG. 3 is a flowchart illustrating an operation for wavelength monitoring and wavelength control in the wavelength controlled optical transmitter and receiver of FIG. 2.

4 is a memory map for transmitting monitoring values, caution and warning information added in the optical transmission and reception apparatus of the present invention to a WDM system through a standard interface.

<Description of Symbols for Main Parts of Drawings>

11 light source driver 12 transmission light detector

13 wavelength control light source 14 wavelength monitoring unit

15: wavelength control unit 16: external power monitoring unit

17: memory 18: temperature sensor

19: internal power monitoring unit 20: receiving light detector

21: limited amplifier 22: control unit

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an optical transmission / reception device used in a wavelength-division multiplexing (WDM) optical network. More specifically, the present invention relates to a wavelength-controlled light source while maintaining compatibility with an existing optical transmission / reception device. It relates to an optical transmitting and receiving device that can be used.

Recently, due to the growth of applications related to the Internet, the required bandwidth of the network is rapidly increasing. Therefore, the WDM technique is actively applied to provide the required bandwidth in a limited optical fiber infrastructure.

WDM is a method of simultaneously transmitting optical signals having several different wavelengths through one optical fiber, and is a transmission method that can stably increase transmission capacity without additionally installing optical fiber.

Currently, most WDM transmission systems use a fixed wavelength light source in which a wavelength of a light source for generating an optical signal is fixedly assigned to each WDM channel. However, in the conventional WDM transmission system using multiple wavelengths, as the concept of high density WDM (DWDM: Dense WDM) is introduced, the number of light wavelengths used per fiber increases to several tens or hundreds, so the wavelength of the light source is individually increased. Management puts a big burden on network operation and maintenance.

Accordingly, in the case of the WDM network construction method such as WDM passive optical network (WDM-PON), which is expected to be widely deployed in large quantities, a wavelength independent light source or a wavelength controlled light source is used to pursue a wavelength independent WDM optical network. The method provides great convenience in the operation of the network.

In order to configure such a WDM optical network, an optical transmission / reception device for transmitting and receiving optical signals should be installed in optical termination devices at both ends of an optical fiber. The optical transmission and reception device adopts a standardized structure and interface to improve field applicability and to reduce cost. For example, SFF-8053 defines Gigabit Interface Converter (GBIC), and SFF-8075 defines Small Form-factor Pluggable (SFP).

1 is a block diagram showing the configuration of an optical transmission and reception apparatus according to the standards of the conventional GBIC and SFP.

The transmission data (differential signal) received from the WDM system (not shown) is first input to the light source driver 1, and the light source driver 1 drives the fixed wavelength light source 3 according to the input differential signal so that the optical signal is transmitted to the optical fiber. Through the transmission to the other side optical transmitting and receiving device (not shown). In this case, as the fixed wavelength light source 3, a Fabry-Perot laser, a distributed feedback laser, or the like is used. The transmission light detector 2 detects the intensity of the optical signal output from the fixed wavelength light source 3 to the transmission optical fiber and feeds back the information to the light source driver 1. The optical signal received through the reception optical fiber is converted into an electrical signal in the reception optical detector 4, and then amplified in the limiting amplifier 5 and transmitted to the WDM system (not shown) as received data (differential signal). At this time, the transmitting optical fiber and the receiving optical fiber are separated, but in the case of the bidirectional optical transceiver, since one optical fiber is used in both directions, optical connection may be made with one optical fiber.

The light source driver (1) and the limiting amplifier (5) provide monitoring and management functions, such as detection and interruption of transmission and reception, as standard, and the optical transmission / reception device uses a WDM system (not shown) and a memory through a two-wire serial interface. It transmits the information on the specification of the module stored in (6) to the WDM system (not shown).

The SFF-8472 standard, which extends the optical transmission / reception monitoring function of the optical transmission / reception apparatus of FIG. 1, can be commonly applied to existing GBICs and SFPs, and has a controller added when compared to SFF-8053 or SFF-8075. Additional monitoring functions such as light output monitoring, module temperature monitoring and internal power voltage monitoring are provided and the information is provided to the WDM system via a standard interface. That is, the light source driver 1 transmits information on transmission power and transmission failure to the WDM system through the controller, instead of directly receiving the differential signal (transmission data). The limiting amplifier 5 also transmits information on reception power and reception failure other than the differential signal (reception data) output to the WDM system through the controller. In addition, the controller provides the WDM system with information stored in memory, module temperature monitoring, internal power supply voltage monitoring, etc. via a 2-wire serial interface.

However, all of these optical transmission and reception devices such as SFF-8053, SFF-8075 and SFF-8472 are based on the assumption of using a fixed wavelength light source, and there is a problem in that the supervisory and supervisory control functions required for the wavelength control light source cannot be implemented. . That is, the conventional optical transmission and reception apparatus has a structure in which the wavelength control light source cannot be adopted.

Moreover, since the conventional optical transmission / reception apparatus presupposes the use of a fixed wavelength light source, the power source (internal power source) provided from the WDM system is also limited accordingly. That is, the conventional optical transmitter and receiver is designed to use a fixed wavelength light source, so the WDM system is also designed to supply only a limited size of power to the optical transmitter and receiver. Therefore, in order to maintain compatibility with the existing optical transmission and reception apparatus, since the standardized interface with the WDM system should not be changed, the internal power source is used as it is. There is a problem that can not implement the monitoring and management control functions required for the wavelength control light source.

Accordingly, an object of the present invention for solving the above problems is to improve the structure of the optical transmission and reception device while maintaining the compatibility with the existing optical transmission and reception device while simultaneously adopting a wavelength independent light source or a wavelength controlled light source in the optical transmission and reception device. To make it work.

A wavelength-controlled optical transmission / reception apparatus for wavelength-independent wavelength division multiplexing optical networks of the present invention for achieving the above object includes a wavelength control light source in which the wavelength of the output light is variable; A wavelength monitoring unit for monitoring a change in an output wavelength of the wavelength controlled light source; A wavelength controller for adjusting an output wavelength of the wavelength controlled light source according to a calibration signal; An external power monitoring unit for monitoring a change in external power supplied for operation of the wavelength control unit separately from the internal power supplied through the standard interface; And generating the calibration signal for controlling the operation of the wavelength control unit according to the monitoring information from the wavelength monitoring unit and the wavelength information previously allocated from the OLT, and generating the calibration signal according to the monitoring information from the external power monitoring unit. And a control unit for notifying the WDM system of the abnormal occurrence state through the standard interface.

A wavelength control method in a wavelength-controlled optical transmission / reception apparatus for a wavelength-independent wavelength division multiplexing optical network of the present invention includes a first step of receiving wavelength information from an OLT as an optical signal; A second step of photoelectrically converting and decoding the received optical signal to store the wavelength information; Finding a wavelength allocated to a WDM channel connected between itself and the OLT based on the wavelength information; And a fourth step of adjusting the output wavelength of the wavelength controlled light source to the wavelength found in the third step and transmitting a wavelength alignment response to the OLT.

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

FIG. 2 is a block diagram showing the configuration of a wavelength-controlled optical transmission / reception device for a wavelength independent multiplexing optical network according to the present invention. In the present embodiment, an optical transmission / reception device used and employed in an optical network unit (ONU) will be described. do.

2 is a light source driver 11, a transmission light detector 12, a wavelength controlled light source 13, a wavelength monitor 14, a wavelength controller 15, an external power monitor 16, and a memory ( 17), a temperature sensor 18, an internal power supply monitoring unit 19, a reception light detector 20, a limiting amplifier 21 and a control unit 22.

When the light source driver 11 receives the transmission data (differential signal) from the WDM system (part of ONU except for the optical transmission and reception apparatus of the present invention), the light source driver 11 converts it into an optical signal and feeds back the converted optical signal and the transmission light detector 12. The wavelength control light source 13 is driven by generating a drive signal in accordance with the information on the transmitted power. The light source driver 11 receives the state (power) information of the output light output from the wavelength control light source 13 to the transmission optical fiber from the transmission light detection unit 12 to detect the transmission power of the output light and whether or not a transmission failure occurs. Information about the control unit 22 is transmitted to the control unit 22. The light source driver 11 stops the light output from the light source 13 when a transmission stop command is applied from the controller 22.

The transmission light detector 12 measures the intensity (power) of the light output from the wavelength control light source 13 and feeds back the measured value (light power) to the light source driver 11.

The wavelength control light source 13 generates light having a predetermined wavelength according to the drive signal of the light source driver 11 and outputs the light to the transmission optical fiber. At this time, the wavelength of the light output from the wavelength control light source 13 is variably adjusted by the wavelength control unit 15.

The wavelength monitoring unit 14 monitors the wavelength change of the light output from the wavelength control light source 13 and transmits the monitoring information to the control unit 22. In this case, as a method for monitoring the wavelength, the temperature of the light source 13 is measured or a part of the output light is reflected by using an optical grid, and then the wavelength of the reflected light is measured.

The wavelength controller 15 adjusts the output wavelength of the wavelength control light source 13 to match the wavelength allocated by the OLT (the wavelength of the WDM channel to which the transmission optical fiber is connected) according to the calibration signal from the controller 22. In this case, the wavelength may be adjusted by using a temperature controller such as a heater or a thermoelectric cooler to adjust the temperature of the wavelength control light source 13 or to adjust the current injected into the light source 13. .

The external power monitoring unit 16 monitors the state (level) change of the power (external power) applied to the optical transmission / reception apparatus separately from the internal power applied through the standard interface with the WDM system, and controls the state information. To send). That is, the wavelength monitoring and the wavelength control for using the wavelength control light source 13 requires an additional power supply in addition to the internal power applied from the WDM system. Therefore, the optical transmission and reception apparatus of the present invention is provided with a power port for receiving power separately from the power supplied from the WDM system through a standard interface to receive external power. Monitored by (16), and transmits the status information to the control unit (22).

The memory 17 stores data for driving the optical transmitter and receiver, information on the specifications of the optical transmitter and receiver, and data for wavelength monitoring and control as shown in FIG. 4, and stores the corresponding information at the request of the controller 22. 22). The memory 17 stores wavelength information provided from the OLT in a setup mode.

The temperature sensor 18 senses the temperature in the optical transceiver and transmits the result to the controller 22.

The internal power monitoring unit 19 monitors the state (level) change of the internal power supplied from the WDM system through the standard interface and transmits the state information to the control unit 22.

The reception light detector 20 converts the optical signal received from the OLT through the reception optical fiber into an electrical signal and transmits the signal to the limiting amplifier 21.

The limiting amplifier 21 decodes and amplifies the received data from the receiving light detector 20 and transmits the received data to the WDM system as a differential signal through a standard interface. The limiting amplifier 21 detects the reception power and the reception failure by comparing the size of the received data with a preset threshold and transmits the detection result to the controller 22.

The control unit 22 controls the data transmission and reception, wavelength monitoring and wavelength control operations of the optical transmission and reception apparatus as a whole. In particular, when the output wavelength of the wavelength control light source 13 deviates from the predetermined wavelength, the controller 22 adjusts and stabilizes the wavelength of the wavelength control light source 13 according to the wavelength information received from the OLT in the setup mode. That is, when the controller 22 receives the information on the wavelength allocated to each WDM channel from the OLT in the setup mode, the controller 22 checks the wavelength of the WDM channel connected between the OLT and the OLT based on the provided wavelength information. The output wavelength of the control light source 13 is adjusted to the corresponding wavelength. In addition, the controller 22 determines whether the output wavelength of the wavelength control light source 13 deviates from the wavelength allocated from the OLT and the degree of deviation thereof during the data transmission / reception after the setup mode is finished through the monitoring information from the wavelength monitoring unit 14. After finding out, the calibration signal for correcting the deviation is output to the wavelength control unit 15, and the information on the deviation is notified to the WDM system through the two-wire serial interface. In addition, the controller 22 generates an abnormality or abnormality with respect to internal / external power and temperature in the transceiver according to the status information from the external power detecting unit 16, the internal power detecting unit 19, and the temperature sensor 18. Determine the likelihood of occurrence and notify the WDM system of the result via a 2-wire serial interface.

Although FIG. 2 illustrates a case in which a transmitting optical fiber for transmitting an optical signal and a receiving optical fiber for receiving an optical signal are respectively separated, it is also possible to use one optical fiber in both directions.

FIG. 3 is a flowchart illustrating an operation for wavelength monitoring and wavelength control in the wavelength controlled optical transmitter and receiver of FIG. 2.

Since the process of transmitting and receiving data using the optical signal in the optical transmitting and receiving apparatus is substantially the same as the process of transmitting and receiving data in the conventional optical transmitting and receiving apparatus, in this embodiment, the wavelength monitoring and the wavelength control operation of the wavelength control light source 13 is mainly focused. Explain.

After initialization, the wavelength controlled optical transmitter and receiver provided in the OLT and the ONU operate in the setup mode.

In this setup mode, the OLT repeatedly transmits its wavelength information to the ONUs through the WDM channels connected thereto for the wavelength control of the present invention (step 310).

In other words, in the setup mode, the OLT repeatedly transmits information about wavelengths allocated to each WDM channel to ONUs connected to the WLT channel. At this time, the OLT encodes the wavelength information at a low speed of several thousand to thousands of bits per second and transmits it to the ONU through the WDM channel.

When the wavelength information is received from the OLT in the setup mode, the reception light detector 20 of the optical transmitter / receiver transmits the converted wavelength information directly to the controller 22 through the reception power monitoring channel (step 320).

In other words, the data received in the setup mode is transmitted to the control unit 22 through the reception power monitoring channel instead of the conventional data path. In the present invention, the wavelength information is transmitted using the narrow reception power monitoring channel because the speed of the wavelength information transmitted by the OLT is very low as in step 310, so that the information is extracted even within the narrow bandwidth of the reception power monitoring channel. Because it is possible.

The control unit 22 decodes the received wavelength information, stores it in the memory 17, detects which wavelength is currently connected to the WDM channel, and adjusts the wavelength of the wavelength control light source 13 according to the corresponding wavelength. The signal is transmitted to the wavelength controller 15 (step 330).

When the wavelength control is completed, the controller 22 transmits a wavelength alignment response to the OLT informing that the wavelength alignment with respect to the wavelength control light source 13 is completed according to the received wavelength information (step 340).

As a result, the setup mode of the optical transceiver is completed.

When the wavelength alignment is completed in the setup mode, the light source driver 11 of the optical transmitter / receiver converts the differential signal (transmission data) received from the WDM system into an optical signal through the standard interface and then converts the wavelength control light source 13 accordingly. By driving the corresponding optical signal is transmitted to the OLT at the wavelength adjusted in step 330 (the wavelength allocated from the OLT for the upward optical signal transmission). Then, the optical transmission and reception apparatus photoelectrically converts the optical signal received from the OLT in the receiving light detector 20 and then decoded in the limited amplifier 21 to transmit to the WDM system through the standard interface (step 350). Since the data transmission and reception process using the optical signal is substantially the same as the conventional transmission and reception process, a detailed description thereof will be omitted.

In the optical transmission and reception process of step 350, the wavelength monitoring unit 14 measures the output wavelength of the wavelength control light source 13, continuously monitors the change of the wavelength, and transmits the measured value to the control unit 22. At this time, the wavelength monitoring unit 14 measures the wavelength of the wavelength control light source 13 or reflects a part of the output light to measure the wavelength of the light.

The controller 22 compares the output wavelength of the current wavelength control light source 130 with the wavelength adjusted in the setup mode (that is, the wavelength allocated to the corresponding WDM channel) according to the monitoring information from the wavelength monitor 14. If the reference value is out of the predetermined reference value (step 360), a flag indicating the current output wavelength and the degree of deviation of the wavelength is transmitted to the WDM system through the two-wire serial interface to notify the abnormality. The controller 22 transmits a calibration signal for controlling the wavelength to the wavelength controller 15 to perform wavelength adjustment on the wavelength control light source 13 (step 370).

At this time, the monitoring value, the caution, and the warning reference value added by the optical transmitter and receiver for wavelength control are shown in FIG. 4, and the monitoring parameters transmitted from the control unit 22 to the WDM system through the two-wire serial interface are represented by the light source output wavelength value ( TX wavelength, light source output wavelength short warning, light source output wavelength short warning, light source output wavelength short alarm, light source output wavelength short alarm Is defined as

As the wavelength control method for the wavelength control light source 13, a method of adjusting the temperature of the wavelength control light source 13 using a heat generator or a thermoelectric cooler may be used. That is, the control unit 22 uses the temperature control unit 13 using a temperature controller such as a heat generator or a thermoelectric cooler as the wavelength control unit until the monitoring information (temperature information) from the wavelength monitoring unit 14 reaches a desired level. Adjust the temperature.

In addition to the monitoring and control function for output wavelength control, the controller 22 monitors the external power level of the external power additionally supplied from the outside for the wavelength control separately from the power (internal power) provided through the standard interface with the WDM system. Detection is made through the unit 16.

If the level of the external power detected by the external power monitoring unit 16 is higher or lower than the preset reference value as shown in FIG. 4B (step 380), the external power supply voltage as shown in FIGS. 4A and 4C. A value (a warning or caution flag) indicating a value and an abnormality in the external power supply is transmitted to the WDM system through the two-wire serial interface (step 390).

The operations of steps 360 to 390 are repeatedly performed until the operation of the optical transceiver is terminated.

In the flowchart of FIG. 3 described above, steps 360 and 380 may be reversed.

As described above, the optical transmission and reception apparatus of the present invention detects the deviation of the wavelength from the optical transmission and reception apparatus itself without the help of the upper layer such as the MAC layer and controls the wavelength, thereby preventing the existing GBIC (SFF-8053) or SFP ( Even in a system designed in consideration of a standard optical transmitter and receiver such as SFF-8075, it is possible to use a wavelength controlled light source simply by replacing the optical transmitter and receiver with the optical transmitter and receiver of the present invention. Secured.

As described above, the optical transmission / reception apparatus of the present invention has a connection structure (standard interface) with the WDM system of the conventional optical transmission / reception apparatus as it is, while maintaining compatibility with the existing optical transmission / reception apparatus, while simultaneously providing a wavelength to the optical transmission / reception apparatus. Control light source can be used.

Claims (10)

In the optical transmission and reception apparatus having a standard interface structure for connection with a WDM system, A wavelength control light source whose wavelength of output light is variable; A wavelength monitoring unit for monitoring a change in an output wavelength of the wavelength controlled light source; A wavelength controller for adjusting an output wavelength of the wavelength controlled light source according to a calibration signal; An external power monitoring unit for monitoring a change in external power supplied for operation of the wavelength control unit separately from the internal power supplied through the standard interface; And The calibration signal for controlling the operation of the wavelength control unit is generated according to the monitoring information from the wavelength monitoring unit and the wavelength information previously assigned from the OLT, and the abnormality of the external power source is generated according to the monitoring information from the external power monitoring unit. A wavelength-controlled optical transmission / reception apparatus for a wavelength independent wavelength division multiplexing optical network having a control unit for notifying a generation state to the WDM system through the standard interface. The method of claim 1, And a reception light detector for converting the optical signal received from the OLT into an electrical signal. The method of claim 2, wherein the receiving light detector The wavelength-controlled optical transmission / reception apparatus for a wavelength independent wavelength division multiplexing optical network, wherein the wavelength information received in the setup mode is transmitted to the controller through a reception power monitoring channel. The method of claim 1, wherein the control unit Detecting a wavelength allocated to a channel connected to the WDM system based on the wavelength information provided from the OLT, and generating the calibration signal for controlling the output wavelength of the wavelength controlled light source to match the detected wavelength. A wavelength controlled optical transmission / reception device for a wavelength independent wavelength division multiplexing optical network. The method of claim 4, wherein the control unit When the output wavelength of the wavelength-controlled light source deviates from the pre-assigned wavelength, a flag indicating the degree of departure is transmitted to the WDM system through the standard interface. Transceiver. A wavelength alignment method in an ONU optical transmission and reception device employing a wavelength controlled light source, A first step of receiving wavelength information from an OLT as an optical signal; A second step of photoelectrically converting and decoding the received optical signal to store the wavelength information; Finding a wavelength allocated to a WDM channel connected between itself and the OLT based on the wavelength information; And And a fourth step of adjusting the output wavelength of the wavelength controlled light source to the wavelength found in the third step and transmitting a wavelength alignment response to the OLT. How to sort. The method of claim 6, wherein the first to fourth steps A wavelength alignment method in a wavelength-controlled optical transmission / reception apparatus for a wavelength independent wavelength division multiplexing optical network, characterized in that the OLT and the ONU are in a setup mode. 8. The method of claim 7, wherein in the first step And the wavelength information is received from the OLT at a low speed of several thousand to several thousands of bits per second. 10. A wavelength alignment method in a wavelength controlled optical transceiver for wavelength independent multiplexing optical networks. The method of claim 8, wherein the wavelength information A wavelength alignment method in a wavelength-controlled optical transmission / reception apparatus for a wavelength independent wavelength division multiplexing optical network, characterized in that the optical transmission and reception apparatus is transmitted through a reception power monitoring channel. The method of claim 6, A fifth step of comparing an output wavelength of the wavelength controlled light source with a wavelength previously assigned by the OLT; And And a sixth step of adjusting the output wavelength of the wavelength controlled light source to the wavelength allocated by the OLT when the deviation of the output wavelength occurs. Wavelength Sorting Method in Transceiver.

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