KR100356019B1 - Optical Distribution Network in ATM-PON System - Google Patents

Abstract

The present invention relates to an optical line termination device (OLT: Optical Line Termination) on a network side in an Asynchronous Transfer Mode-Passive Optical Network (ATM-PON) based on Time Division Multiplexing Access (TDMA). ) And an optical distribution network subsystem for physical connection between an optical network unit (ONU) on the subscriber side.

The optical distribution network subsystem of the asynchronous transfer mode-passive optical subscriber network distributes the optical signals from the optical fiber terminators to the optical network units and integrates the optical signals from the optical network units to the optical network terminator. Optical branch function means, optical distribution function means for transmitting an optical signal through the optical path between the optical branch function means and the optical network unit, the fault monitoring function for monitoring the failure of the optical path of the optical distribution function means and processing network recovery Means for performing a cross-connection function for distributing and switching optical signals between the optical termination device and the optical branch functional means, the optical branch functional means and the fault monitoring function means, the fault monitoring function means and the optical distribution function means. XC function means.

Description

Asynchronous Delivery Mode-Optical Distribution Network Subsystem of Passive Optical Subscriber Network {Optical Distribution Network in ATM-PON System}

The present invention relates to an Asynchronous Transfer Mode-Passive Optical Network (ATM-PON) based on Time Division Multiplexing Access (TDMA), which will be described in more detail. An optical distribution network subsystem for a physical connection between an optical line termination (OLT) and an optical network unit (ONU) on the subscriber side.

The asynchronous delivery mode-passive optical subscriber network (ATM-PON) consists of an optical network termination device (OLT) on the network side, an optical network unit (ONU) on the subscriber side, and an optical distribution network subsystem (ODN). The optical distribution network subsystem performs the optical transmission medium function to physically connect the optical fiber termination device and the optical network unit in a time division multiple access (TDMA) based asynchronous transmission mode-passive optical subscriber network.

In general, the optical subscriber network is a technology for constructing a communication network system that can provide high-speed information and communication services to each subscriber more economically, combining existing copper lines and optical lines or providing optical lines directly to subscribers' homes. Provide service. However, in the current technology, since the cost of optical cables and optical devices is high, there is an economic difficulty in laying the optical fiber in a point-to-point manner to subscribers' homes. To solve this problem, multiple subscribers use a single optical fiber using Time Division Multiplex (TDM), Wavelength Division Multiplex (WDM), or Sub-Carrier Multiplex (SCM). Passive fluorescence subscriber network (PON) systems that share the variability have been actively studied. In addition, researches on efficient distribution network structure design, network failure monitoring method, optical cable junction box design, high branch optical splitter fabrication, high density optical connector fabrication, etc. are being conducted to actually install optical fibers in the external environment.

Accordingly, the present invention has been made to solve the problems of the prior art, to provide an efficient and low-cost optical distribution network subsystem in TDMA-based ATM-PON. First, it is to provide a distribution network that can cope with network failures quickly by duplication of important functions, and actively respond to changing demands of subscribers by using a cross connection function unit and a reserve line. In addition, it is to provide an efficient distribution network that can monitor and manage the failure of the entire optical fiber installed from the OLT to each ONU in the national office, and save the optical cable cost.

1 is a structural diagram of a general asynchronous transfer mode-passive fluorescence subscriber network,

2 is a functional block diagram of an optical distribution network according to an embodiment of the present invention;

3 is a connection diagram of the optical branch functional unit and the optical network termination device shown in FIG.

4 is a connection diagram of the optical branch function unit and the fault monitoring unit illustrated in FIG. 2;

5 is a connection diagram of the fault monitoring function unit and the light distribution function unit shown in FIG. 2;

6 is an internal connection diagram of the XC functional unit shown in FIG.

7 is a structural diagram of a light distribution function according to an embodiment of the present invention.

In order to achieve the above object, the present invention provides an optical distribution network subsystem for connecting the optical network termination device on the network side and the optical network units on the subscriber side in the asynchronous transmission mode-passive optical subscriber network system. An optical branch function means for distributing a signal to the optical network units, integrating the optical signals from the optical network units, and delivering the optical signals to the optical fiber termination device; and an optical signal through the optical path between the optical branch function means and the optical network units. Optical distribution function means for transmitting the optical fiber function means for monitoring the failure of the optical path of the optical distribution function means and processing network recovery; and the optical network termination device and the optical branch function means, the optical branch function means and the failure monitoring function Means, a cross connection function for distributing and switching optical signals between the fault monitoring means and the light distribution means; Characterized in that the means for performing functions, including XC.

Preferably, the optical branch functional means is implemented as a double-window optical splitter that can use the wavelength band of the uplink signal and the wavelength band of the downlink signal.

More preferably, the optical branch functional means includes an operational optical splitter operated during normal operation and a preliminary optical splitter operating when a failure of the operational optical splitter occurs, and the distribution function means operates to transmit an optical signal during normal operation. And a preliminary optical beam operating in the event of a failure of the optical path and the operating optical path.

Even more preferably, the fault monitoring means comprises: an optical time domain reflectometer for generating a test signal in a light beam; and an optical signal distributed from the optical splitter and the light path test signal for transmitting to the light path. And an optical filter for filtering a test signal with the light beam transmitted to the optical splitter through the * 1 coupler and the 2 * 1 coupler.

Even more preferably, the XC function means connected between the optical branch function means and the fault monitoring function means connects the operating light splitter and the fault monitoring function means in normal operation, and the fault of the operating light splitter The preliminary optical splitter and the failure monitoring function means for connecting when generated.

Even more preferably, the XC function means connected between the fault monitoring function means and the optical distribution function means connects the fault monitoring function means and the operating light beam during normal operation, and monitors the fault when the fault occurs in the operating light beam. It is characterized by connecting the functional means and the spare optical path.

Hereinafter, the "optical distribution network subsystem of asynchronous transfer mode-passive optical subscriber network" according to an embodiment of the present invention with reference to the accompanying drawings in detail as follows.

1 is a schematic overall structural diagram of a general asynchronous delivery mode-passive fluorescence subscriber network (hereinafter referred to as ATM-PON) system. This ATM-PON system includes an optical network termination device (hereinafter referred to as OLT) 11 to be installed in a national office, an optical distribution network (hereinafter referred to as ODN) 12 serving as an optical transmission medium, and an optical network as a subscriber device. Units (hereinafter referred to as ONUs) 13 and 14 and the like. In the present invention, two types of optical net units are included, which are the home type optical net unit 14 in the concept of FTTH (Fiber To The Home) and the pole type optical net unit 13 in the concept of FTTC (Fiber To The Curb). The ODN 12 distributes optical signals between the OLT 11 and the ONUs 13 and 14, and uses an optical splitter and multiplexing schemes such as TDM, WDM, SCM, etc. 11) a passive fluorescence subscriber network system in which several ONUs 13 and 14 are connected.

2 is a functional block diagram of an optical distribution network subsystem in accordance with one embodiment of the present invention. The optical distribution network subsystem includes a cross-connection (21) function that performs cross-connection between optical fibers at optical fiber connection points for distribution and switching on a line, one OLT 11 and several ONUs. Through the optical branch function unit 22 for distributing / integrating the optical signals between the 13 and 14, the fault monitoring unit 23 for monitoring the failure of the optical path and processing the network recovery, and the optical paths 24 and 25. And an optical distribution function 26 which becomes an optical signal transmission medium between the OLT 11 and the ONUs 13 and 14.

In the present invention, the optical branch function unit 22 is provided in the national office to facilitate monitoring of the failure of the entire optical path. Up / down signals are transmitted in both directions through one optical fiber, and downlink (OLT-> ONU) signals are transmitted in the optical signal wavelength of 1.55um band, and uplink (ONU-> OLT) signals are optical signal wavelength in 1.3um band. This is used.

The signal transmitted from the OLT 11 is applied to the optical branch functional unit 22, as shown in FIG. 3, and divided by the optical splitter 31 into several strands of optical fiber. In this case, the optical splitter used uses a double window splitter that can use both wavelength bands of 1.55 / 1.3um. In addition, the optical branch functional unit 22 is not distributed in various fields in the outdoor field, but uses a small size element because all the branches are performed in the national office. In addition, the optical branch functional unit 22 uses the splitter 31 in preparation for the failure of the equipment. An XC function unit 21 exists between the OLT 11 and the optical branch function unit 22 to connect the operating part and the spare part as necessary for failover recovery. Output signals of the optical branch function unit 22 are applied to the optical distribution function unit 26 via the fault monitoring function unit 23.

The fault monitoring unit 23 sequentially selects the optical fibers 24 and 25 installed in the optical distribution unit 26 through a fiber selection unit to test each optical path and recovers when a failure occurs. Do this.

4 is a detailed configuration diagram of the failure monitoring function unit 23 described above. Each optical fiber exiting the optical branch functional unit 22 passes through the optical fiber selection unit 40 to the optical distribution function unit 26. This optical fiber selection unit 40 is comprised of 2 * 1 couplers 41 and 42 and optical filters 43 and 44 of 10/90. The optical filters 43 and 44 filter the test signal with light rays generated by an optical time domain reflectometer (OTDR) 45 to prevent crosstalk that may be caused to the received optical signal. 90% of the optical signal and 10% of the OTDR (45) light beam test signal is combined by the coupler (41, 42) and transmitted to the optical distribution function (26). The failure monitoring function 23 is not redundant in consideration of economical efficiency, and is connected to the operation and spare devices of the optical branch function 22 through the XC function 21.

5 is a detailed configuration diagram of the failure monitoring function unit 23 and the light distribution function unit 26. The light distribution function 26 is doubled in preparation for cutting into the light beam. Therefore, when a failure occurs in the operation line 24 by inserting the XC function unit 21 with the failure monitoring function unit 23, the transfer to the preliminary line 25 is performed. Since the optical fiber selection unit 40 is not redundant, the spare port of the XC function unit 21 is generally not connected to the optical fiber selection unit 40.

The XC function unit 21 used in the optical distribution network subsystem is used for the optical signal distribution point or the redundant equipment switching part, and the number of input ports is composed of operation ports and spare ports as well as output ports. Normally, no signal is connected to the spare input port, and in case of failure, the spare output port is switched to the operation port. However, when the number of subscribers is increased and a part of the spare port is switched to the operation port, both the input and output spare ports are used as the operation port, as shown in FIG.

7 is a structural diagram of a light distribution function. In other words, the center is set in the center and a two-stage radial network is constructed. The first stage is the radial network of feeder sections connected between CO (Central Office) and XC1, and the second stage is the radial network of distribution sections from XC1 to XC2. In XC2, each ONU drops an optical signal. In the present invention where the optical branch function is located in the national history, such a structure is an economical structure that can reduce the length of the optical cable. Each connected fiber is redundant. In addition, in order to accommodate a sudden increase in subscribers, it is possible to efficiently convert a spare fiber into an operational fiber through the XC function.

While the invention has been described above based on the preferred embodiments thereof, these embodiments are intended to illustrate rather than limit the invention. It will be apparent to those skilled in the art that various changes, modifications, or adjustments to the above embodiments can be made without departing from the spirit of the invention. Therefore, the protection scope of the present invention will be limited only by the appended claims, and should be construed as including all such changes, modifications or adjustments.

According to the present invention as described above, the failure monitoring of the entire optical line can be performed in the central office, and the recovery switching function can be performed in preparation for the failure of the optical line or the failure of the equipment. In addition, there is an economical and efficient distribution network that can flexibly cope with the increase in ONU and reduce the cost of fiber. The ODN subsystem according to the present invention can be applied to the optical subscriber network system using the optical fiber and can be spotlighted as an efficient ODN subsystem suitable for various environments.

Claims (6)

In the optical distribution network subsystem for connecting the optical termination device on the network side and the optical network unit on the subscriber side in the asynchronous delivery mode-passive optical subscriber network system, And an optical fiber splitter operating during normal operation and a spare optical splitter operating when a failure of the optical fiber splitter occurs. Optical branch function means for integrating and delivering the optical network termination device; An optical distribution function means for transmitting an optical signal through the optical path between the optical branch function means and the optical network unit, including an operation light beam for transmitting an optical signal in a normal operation and a backup optical beam operated when a failure of the operation light beam occurs; Failure monitoring means for monitoring the failure of the optical path of the optical distribution function means and processing network recovery; And XC function means for performing a cross connection function for distributing and switching the optical signal between the optical network termination device and the optical branch function means, the optical branch function means and the fault monitoring function means, and the fault monitoring function means and the optical distribution function means. The optical distribution network subsystem of the asynchronous delivery mode-passive optical subscriber network comprising a. 2. The optical distribution network of an asynchronous transfer mode-passive optical subscriber network according to claim 1, wherein the optical branch functional means is implemented as a double-window optical splitter capable of using a wavelength band of an uplink signal and a wavelength band of a downlink signal. Subsystem. delete The method of claim 3, wherein the fault monitoring means, An optical time domain reflectometer for generating a test signal with a light beam; A 2 * 1 coupler for combining the optical signal distributed by the optical splitter and the optical path test signal and transmitting the optical signal to the optical path; And an optical filter for filtering a test signal with the light beam transmitted through the 2 * 1 coupler to the optical splitter. 5. The XC functional means connected between the optical branch function means and the fault monitoring function means connects the operational light splitter and the fault monitoring function means in normal operation, and the fault of the operational light splitter is generated. The optical distribution network subsystem of the asynchronous delivery mode passive passive subscriber network, characterized in that it connects said preliminary optical splitter and said fault monitoring means upon occurrence. 4. The XC functional means connected between the fault monitoring function means and the optical distribution function means connects the fault monitoring function means with an operating light beam in normal operation, and monitors the faults when a fault occurs in the operating light beam. An optical distribution network subsystem in an asynchronous delivery mode passive passive subscriber network characterized by connecting functional means and a spare optical path.