KR100893214B1 - Apparatus and metod for controlling optical transmission in optical network unit - Google Patents

Abstract

An apparatus and method for controlling light output in an ONU according to the present invention include filtering a part of an optical output signal transmitted to an OLT to monitor an optical signal having an UP Stream wavelength of the ONU, and filtering the filtered optical signal through a photodiode. Will be monitored. The photodiode converts the monitored optical signal into an electrical signal and converts the converted signal into a digital signal. When the converted signal (light output ON signal) is continuously maintained for a set time (time slot period) or when the light output is sensed to be in the ON state, the laser diode is driven to block the light output. By forcibly turning off, it is possible to stably operate the entire PON system by blocking and protecting the effect on other ONUs that normally operate due to the malfunction of the laser diode.

Description

Apparatus and metod for controlling optical transmission in optical network unit

1 is a view showing a connection configuration of a general EPON system.

FIG. 2 is a diagram showing an internal block configuration of the optical network unit ONU shown in FIG.

3 is a block diagram of an optical output control apparatus in the optical network unit of the EPON system according to the present invention;

4 is a flowchart showing an operation of the method for controlling the light output in the optical network unit of the EPON system according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: OLT 200: optical splitter

300: ONU 310: optical transmission module

311: optical switching unit 312: optical transmission unit

320: EPON MAC module 330: optical output control module

331: Light detection splitter

332: light detector 333: A / D converter

334 control unit 335 clock generation unit

The present invention relates to a PON system, and in particular, by detecting the optical signal output from the optical network unit of the PON system to determine the abnormality of the LD module according to the detected optical signal, and to control the driving of the LD module according to the determination result An apparatus and method for controlling light output in an optical network unit of a PON system.

The recent Internet craze is fundamentally changing the paradigm of the communication environment. As the demand for high speed / high quality data of users increases, the market size is rapidly increasing. This is due to the spread of the Asymmetric Digital Subscriber Line (ADSL), a technology that enables high-speed Internet while utilizing existing copper wire. However, users' demands are beyond the speed limits of ADSL, and one of the technologies to replace ADSL is the Passive Optical Network (PON). Here, the PON may be divided into an APON (ATM PON) and an EPON (Ethernet PON).

PON is an optical subscriber network technology that provides fiber-based, high-speed data services to businesses, small office home offices (SOHO), and homes. The typical structure of a PON is a structure in which an optical line termination (OLT) is installed in a central office (CO) and a plurality of optical network units (ONUs) are connected to one OLT through a 1: n optical star coupler. to be. The ONU performs a function of converting an optical signal into an electrical signal or vice versa.

In the case of the PON Time Division Multiplexing (TDM) passive optical network (TDM Based PON), the respective equipments share an optical line. This method allows each device to transmit and receive data without collisions over a shared track by outputting optical signals at predetermined or permitted times. If even one device outputs an optical signal in an unauthorized time, it can have a fatal effect on all devices using the same line. Conventional methods for preventing this use a method of detecting or controlling the on / off of the laser. Hereinafter, the operation of a general time division multiplexing optical network will be described.

1 is a block diagram illustrating a general time division multiplexing EPON system.

As shown in FIG. 1, the time division type EPON system may include an OLT 100, a splitter 200, and a plurality of ONUs 300, 400, 500, 600,... Of course, the time division optical network includes substantially more components, but only those components that can exhibit the characteristics of the present invention are shown in FIG.

The OLT 100 corresponds to an optical end device of a service provider as part of an optical network. A multiservice device that connects an optical subscriber network with other systems. It can be composed of SIPP (Service Interface and Protocol Processing) devices, integrated wired devices, transmission devices, and network management devices. It provides signaling method, connection with local exchange of CAS (Channel Associated Signaling), and interface function in packet public data exchange network.

ONU (300, 400, 400, 500, ...) is a network termination device for connecting to the optical subscriber network constituting the next-generation communication network. ONU (300, 400, 500, 600, ..) is a device installed in the subscriber's premises, the user-network interface of the narrowband Integrated Information Network (N-ISDN), the user of the Broadband Integrated Information Network (B-ISDN) A communication interface such as a network interface or an image signal interface is converted to connect to an optical fiber network.

In addition, the splitter 200 corresponds to a device that receives one optical signal and separates the optical signal into a plurality of optical signals. The splitter 200 includes an input optical waveguide core (not shown) connected to an input optical fiber block including an input optical fiber and a plurality of output optical waveguide cores (not shown) branched from the core.

1 illustrates a plurality of ONUs 300, 400, 500, 600,..., Respectively, transmitting uplink data during a time domain allocated thereto. The plurality of ONUs 300, 400, 500, 600,... Respectively transmit data for a time allocated to them. In FIG. 1, IDs of data transmitted during the divided time are illustrated as 1, 4, 3, and 2, respectively. The transmitted data is transmitted to the OLT 100 through the splitter 200. Since the data having the IDs of the first, the fourth, the third, and the second are not transmitted at the same time, the OLT (100) from the splitter 200 is transmitted. The optical signal transmitted to) does not cause a collision. As such, a system in which a plurality of ONUs 300, 400, 500, 600,... Transmit data for a time interval allocated thereto is called time division multiplexing.

As shown in FIG. 1, in an EPON system using time division multiplexing, a downlink data transmission scheme is an ONU 300, 400, 500, 600,... Which is connected point-to-multipoint via a splitter 200 like a broadcasting scheme. The same data is transmitted to.) And only the subscriber's data is received by the ONU (300, 400, 500, 600, ..) that received it.

On the other hand, in the case of uplink data, a plurality of ONUs (300, 400, 500, 600, ..) connected to the OLT 100 according to the MPCP (Multi Point Control Protocol) OLT 100 is a gate message frame (Gate Message Frame) ONU (300, 400, 500, 600, ..) is the current buffer usage of EPON MAC modules mounted in ONU (300, 400, 500, 600, ..) via Report Message Frame. And notifies the upper OLT 100 of the CoS (Class of Service) information of the user data, and according to the control information received from each ONU (300, 400, 500, 600, ..), the OLT 100 and ONU ( Synchronize sync timing between 300, 400, 500, 600, ..) and assign and notify the appropriate user data time slot to ONU (300, 400, 500, 600, ..) do. The ONU's EPON MAC module, as shown in FIG. 2 of the ONU (300, 400, 500, 600, ..) that received the message, only controls the optical transmission module including the radar diode and only receives the assigned time slot. The signal is output to the OLT 100 through the splitter 200.

The configuration of the ONU (300, 400, 500, 600, ...) in the above will be briefly described with reference to FIG.

FIG. 2 is a diagram illustrating an internal block configuration of the optical network unit ONU shown in FIG. 1.

As shown in FIG. 2, the ONU 300 includes an optical transmission module 310 and an EPON MAC module 320, and the optical transmission module 310 includes an optical switching unit 311 and an optical transmission unit 312. It may include. Although not shown in the drawing, the optical transmitter 312 includes an LD module and an LD driver.

The EPON MAC module 320 transmits data for transmitting to the OLT 100 to the LD driver of the optical transmitter 312. In addition, since the ONU 300 transmits an optical signal to the OLT 100 in a time division manner, the EPON MAC module 320 generates an optical output application signal for activating the laser diode of the optical transmitter 312 for a time allocated thereto. The optical transmitter 320 transmits the light.

The optical transmitter 312 plays a role of controlling the overall optical output by activating the laser diode according to the optical output application signal provided from the EPON MAC module 320. The LD driver of the optical transmitter 312 receives an optical signal output control signal through the Laser Enable terminal and a data signal through the In + and In − terminals from the EPON MAC module 320 to physically use the laser diode of the LD module. Serves to generate optical signals.

On the other hand, the optical switching unit 311 of the optical transmission module 310 is an optical signal UP STREAM transmitted from the ONU 300 to the OLT 100 and an optical signal transmitted from the OLT 100 to the ONU 300. It divides (DOWN STREAM) and plays a role of switching each. Here, the switching operation determines the magnitude of the wavelength of the upstream optical signal and the wavelength of the downstream optical signal to perform the up / down switching operation.

As shown in FIG. 2, the ONU 300 which wants to transmit user data to the upper part through the optical link should insert data correctly into the allocated time slot according to the control message exchange with the upper OLT 100. Due to the abnormal operation of the optical transmission module 310 of 300, LD ON / OFF control is not properly performed, so if the LD continues to operate in the ON state or the light output enough to be recognized as the ON state is allocated to another ONU. Since the time slot region is continuously invaded, all the other ONUs that operate normally are not able to operate normally, thereby degrading the performance of the entire network.

Accordingly, an object of the present invention is to solve the above-described problems according to the prior art, and an object of the present invention is to prevent performance degradation of the entire network due to malfunction of an optical transmission module of a PON system ONU using time division multiplexing. In order to monitor each ONU optical output signal and to provide an optical output control apparatus and method for the optical network unit of the PON system to cut off the optical output of the ONU when an abnormal operation of the optical transmission module occurs.

An optical output control apparatus of an optical network unit (ONU) according to the present invention for achieving the above object comprises: an optical transmission module for transmitting an optical signal in which data is inserted into an assigned time slot to an OLT; And an optical output control module configured to detect the transmitted optical signal and block generation of the optical signal transmitted to the OLT when the optical signal is detected for a predetermined time or more.

The optical output control module may include: an optical sensor configured to detect an optical signal transmitted from the optical transmission module to the OLT; And a controller configured to block the light output of the optical transmission module by determining that the optical transmission module is malfunctioning when the detection time of the optical signal is longer than a predetermined time.

The optical output control module may include: an A / D converter configured to convert an electrical signal of the optical signal detected by the optical sensor into a digital signal and then provide the converted digital signal to the controller; And a clock generator configured to generate a clock corresponding to the set time and provide the control unit to compare the sensing time of the optical signal with the set time.

The light sensing unit includes a photodiode.

The control of the optical transmission module in the optical output control module is achieved by controlling off the driving of the laser diode in the optical transmission module.

According to an aspect of an optical network unit of a PON system according to the present invention, an optical transmission module for transmitting an optical signal, the data is inserted into the assigned time slot to the OLT; An optical sensor detecting an optical signal transmitted from the optical transmission module to the OLT; An A / D converter converting an electrical signal of the optical signal detected by the light detector into a digital signal; The optical signal output from the A / D converter determines whether the detection time of the optical signal is greater than or equal to a predetermined time, and when the output detection time of the optical signal is greater than or equal to a predetermined time, it is determined that the optical transmission module is malfunctioning. A control unit to block and control the light output of the transmission module; And a clock generator configured to generate a clock corresponding to the set time and provide the control unit to compare the sensing time of the optical signal with the set time.

On the other hand, according to one aspect of the optical output control method of the optical network unit (ONU) according to the present invention, the step of transmitting the optical signal, the data is inserted into the assigned time slot to the OLT; The method may include detecting the transmitted optical signal and blocking the generation of the optical signal transmitted to the OLT when the optical signal is detected for a predetermined time or more.

The blocking control may include detecting an optical signal transmitted to the OLT; Converting an electrical signal for the detected optical signal into a digital signal; Determining whether the output detection time of the optical signal according to the converted digital signal is greater than or equal to a set time; And blocking the generation of the optical signal transmitted to the OLT when the output detection time of the optical signal is greater than or equal to a predetermined time as a result of the determination.

Detection of the optical signal transmitted to the OLT is detected using a photodiode.

On the other hand, according to another aspect of the optical output control method in the optical network unit of the PON system according to the present invention, the step of transmitting the optical signal with the data inserted in the assigned time slot to the OLT; Detecting an optical signal transmitted from the optical transmission module to the OLT; Converting an electrical signal for the detected optical signal into a digital signal; Determining whether the detection time of the optical signal is greater than or equal to a set time according to the converted digital signal as a reference clock provided; As a result of the determination, if the output detection time of the optical signal is more than the set time may include blocking control of the generation of the optical signal transmitted to the OLT.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the light output control device and method in the ONU according to the present invention will be described in detail. Here, in the following description of the present invention will be described as an embodiment of the EPON system of the PON system, it should be understood that the present invention is not necessarily limited to the EPON system, but may be equally applicable to the APON system. Therefore, the rights of the present invention should be interpreted not by the following examples, but by the claims that follow.

3 is a block diagram of an optical output control apparatus in an optical network unit of an EPON system according to a preferred embodiment of the present invention. Here, in the description of FIG. 3, detailed descriptions of the same components as those of FIGS. 1 and 2 will be omitted.

As shown in FIG. 3, the EPON system includes an OLT 100, a splitter 200, and an ONU 300.

The ONU 300 includes an optical transmission module 310, an EPON MAC module 320, and an optical output control module 330, and the optical transmission module 310 includes an optical switching unit 311 and an optical transmission unit 312. It may include.

The light output control module 330 includes a light sensing splitter 331, a light sensing unit 332, an A / D converter 333, a controller 334, and a clock generator 335. .

The light sensing splitter 331 distributes an optical signal transmitted to the OLT 100 through the light switching unit 311 of the light transmission module 3100 and provides the light signal to the light sensing unit 332.

The light detector 332 detects an optical signal distributed through the splitter 331 for detecting light, converts the detected optical signal into an electrical signal, and provides the converted optical signal to the A / D converter 333. The photo detector 332 may be configured as a photo diode.

The A / D converter 333 detects a current of the signal provided from the light detector 332, converts the corresponding signal into a digital signal, and provides the converted digital signal to the controller 334.

The clock generator 335 generates a clock having a set period as a kind of timer and provides the clock to the controller 334.

The controller 334 determines whether the digital signal provided from the A / D converter 333 is continuously received from the A / D converter 333 during the clock period provided by the clock generator 335. . That is, the controller 334 determines whether the optical signal is kept on for a predetermined time, and if the optical signal is maintained in the ON state for a predetermined time, the LD of the optical transmitter 312 is driven to exceed the allotted time slot. It is determined that a signal is being generated.

Therefore, when the digital signal is continuously received from the A / D converter 333 continuously for more than a predetermined time, the controller 334 determines that the abnormality of the optical transmission module 310 has occurred and transmits the error to the optical transmitter 312. The control signal for blocking the LD drive is provided to forcibly turn off the LD drive.

The operation of the light output control apparatus in the EPON system according to the present invention having such a configuration will be described in more detail.

First, data for transmitting from the EPON MAC module 320 to the OLT 100 is provided to the optical transmission unit 312 of the optical transmission module 310. That is, since the ONU 300 transmits the optical signal to the OLT 100 in a time division manner, the EPON MAC module 320 is a laser diode in the optical transmission unit 312 of the optical transmission module 310 during the time slot allocated thereto. The optical output applying signal for activating the signal is provided to the optical transmitter 320.

The optical transmission unit 312 of the optical transmission module 310 activates the laser diode according to the optical output application signal provided from the EPON MAC module 320 to generate an optical signal during the assigned timeslot, thereby generating the optical switching unit 311. To provide. That is, the LD driver of the optical transmitter 312 receives an optical signal output control signal through the Laser Enable terminal and a data signal through the In + and In − terminals from the EPON MAC module 320 to transfer the laser diode of the LD module. Physically generate an optical signal and provide the generated optical signal to the optical switching unit 311.

The optical switching unit 311 of the optical transmission module 310 includes an optical signal UP STREAM transmitted from the ONU 300 to the OLT 100 and an optical signal transmitted from the OLT 100 to the ONU 300. ) And switch each, and whether the optical signal generated by the optical transmitter 312 is an optical signal having a wavelength for transmitting to the upper OLT or an optical signal having a downward wavelength transmitted from the OLT. Determine and perform the switching operation accordingly. That is, the switching operation determines the magnitude of the wavelength of the UP STREAM optical signal and the wavelength of the DOWN STREAM optical signal to perform the UP / DOWN switching operation.

The optical switching unit 311 transmits the optical signal to the OLT 100 through the splitter 200 when it is determined that the optical signal generated by the optical transmitter 3120 is an optical signal for transmitting to the upper OLT 100. Will be.

Here, in the optical monitoring splitter 331 of the optical output control module 330, the optical sensing unit 332 displays some optical signals in order to monitor whether the optical signals transmitted to the upper OLT 100 are normally transmitted during the allocated time slots. To distribute)

The light detector 332 is made of a photodiode, and detects an optical signal distributed from the optical monitoring splitter 331, converts the detected optical signal into an electrical signal, and provides it to the A / D converter 333. Will be done. Here, the method of converting the detected optical signal into an electrical signal by detecting the optical signal using the photodiode by the photo detector 332 will be omitted.

The A / D converter 333 of the light output control module 330 converts the electrical signal (analog signal) provided from the light detector 332 into a digital signal and then converts the converted digital signal into the controller 334. to provide.

The controller 334 is a case where the digital signal provided from the A / D converter 333 is continuously received for more than a clock period (set time) provided from the clock generator 335, that is, exceeds the allocated time slot. When the output of the optical signal is detected during the period, it is determined that the abnormality of the laser diode or the laser diode driver is generated, and thus the control signal for blocking the driving of the laser diode is transmitted to the light transmitting unit 312 of the optical transmission module 310. To provide. More specifically, to provide the LD driver of the light transmission unit 312 to force off the laser diode.

The light output control method according to the present invention corresponding to the operation of the light output control device according to the present invention will be described step by step with reference to FIG. 4.

4 is an operational flowchart of a method of controlling light output in an ONU of an EPON system according to the present invention.

First, after inserting data for transmission to the OLT 100 in the timeslot assigned to the ONU 300, the laser diode is activated to generate an optical signal for the data inserted in the time slot assigned to the ONU 300. (S101, S102).

The generated optical signal is transmitted to the upper OLT 100 through the splitter 200 (S103).

Here, a part of the optical signal transmitted to the OLT 100 is distributed to monitor the output of the optical signal whether the optical signal is normally transmitted during the time slot normally allocated from the ONU 300 to the OLT 100 (S104).

After detecting the distributed optical signal using a photodiode, the detected optical signal is converted into an electrical signal (S105), and the converted electrical signal (analog signal) is converted into a digital signal (S106).

It is determined whether the converted digital signal is continuously received for a predetermined time or more, that is, whether the output of the optical signal is detected during a period exceeding the allocated time slot (S107).

As a result, when the output of the optical signal is detected during the period exceeding the allotted time slot (more than the set time), it is determined that the abnormality of the laser diode or the error of the laser diode driver is generated, thereby forcibly turning off the driving of the laser diode. It will be (S108).

If, as a result of the determination, if the optical signal transmitted to the OLT is not detected for more than a set time (time slot), it is determined that the laser diode is operating normally and the monitoring operation of the optical signal is continuously performed.

As a result, the optical output control apparatus and method of the ONU according to the present invention, by filtering a portion of the optical output signal transmitted to the OLT 100 to monitor the optical signal of the UP Stream wavelength of the ONU 300, The optical signal is monitored through the photodiode.

The photodiode converts the monitored optical signal into an electrical signal and converts the converted signal into a digital signal. When the converted signal (light output ON signal) is continuously maintained for a set time (time slot period) or when the light output is sensed to be in the ON state, the laser diode is driven to block the light output. Is to force off.

An apparatus and method for controlling light output in an ONU according to the present invention as described above may filter a portion of an optical output signal transmitted to an OLT to monitor an optical signal of an UP Stream wavelength of the ONU, and filter the filtered optical signal. Monitoring through a photodiode. The photodiode converts the monitored optical signal into an electrical signal and converts the converted signal into a digital signal. When the converted signal (light output ON signal) is continuously maintained for a set time (time slot period) or when the light output is sensed to be in the ON state, the laser diode is driven to block the light output. By forcibly turning off, it is possible to reliably operate the entire PON system by blocking and protecting the effect on other ONUs that operate normally due to the malfunction of the laser diode.

Claims (11)

In the optical output control apparatus of the optical network unit (ONU), An optical transmission module for transmitting an optical signal, in which data is inserted into an allocated timeslot, to an OLT; An optical sensor detecting an optical signal transmitted from the optical transmission module to the OLT; And a controller configured to block the light output of the optical transmission module by determining that the optical transmission module is malfunctioning when the detection time of the optical signal is greater than or equal to a predetermined time, and the controller detects the transmitted optical signal. And an optical output control module to block generation of an optical signal transmitted to the OLT when the optical signal is detected for a predetermined time or more. delete The method of claim 1, The light output control module, An A / D converter for converting an electrical signal of the optical signal detected by the light detector into a digital signal and providing the converted digital signal to the controller; And a clock generator which generates a clock corresponding to the set time and provides the control unit to compare the sensing time of the optical signal with the set time. The method of claim 1, The light sensing unit includes a photodiode. The method of claim 1, And the control of the optical transmission module in the optical output control module to control off the driving of the laser diode in the optical transmission module. In the optical network unit of the PON system, An optical transmission module for transmitting an optical signal, in which data is inserted into an allocated timeslot, to an OLT; An optical sensor detecting an optical signal transmitted from the optical transmission module to the OLT; An A / D converter converting an electrical signal of the optical signal detected by the light detector into a digital signal; The optical signal output from the A / D converter determines whether the detection time of the optical signal is greater than or equal to a predetermined time, and when the output detection time of the optical signal is greater than or equal to a predetermined time, it is determined that the optical transmission module is malfunctioning. A control unit to block and control the light output of the transmission module; And a clock generator which generates a clock corresponding to the set time and provides the control unit to compare the sensing time of the optical signal with the set time. In the optical output control method of the optical network unit (ONU), Transmitting to the OLT an optical signal having data inserted in the assigned timeslot; Detecting an optical signal transmitted to the OLT; Converting an electrical signal for the detected optical signal into a digital signal; Determining, according to a provided clock, whether an output detection time of an optical signal is longer than a set time according to the converted digital signal; And Blocking the generation of the optical signal transmitted to the OLT when the output detection time of the optical signal is greater than or equal to a predetermined time as a result of the determination. delete delete delete In the optical output control method in the optical network unit of the PON system, Transmitting to the OLT an optical signal having data inserted in the assigned timeslot; Sensing an optical signal transmitted from the optical transmission module to the OLT; Converting an electrical signal for the detected optical signal into a digital signal; Determining whether the detection time of the optical signal is greater than or equal to a set time according to the converted digital signal as a reference clock provided; And determining to block generation of an optical signal transmitted to the OLT when the output detection time of the optical signal is greater than or equal to a predetermined time as a result of the determination.

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