KR101254265B1 - Single core network tap - Google Patents

Abstract

Single core network tap according to an embodiment of the present invention, the first network port to which the first WDM wavelength signal is input; A second network port to which a second WDM wavelength signal is input; A first WDM optical filter for filtering the first WDM wavelength signal into a first WDM single wavelength signal λ ₁ and for transmitting a second WDM single wavelength signal λ ₂ branched from a second optical coupler to the first network port device; A second filter for filtering the second WDM wavelength signal into the second WDM single wavelength signal [lambda] ₂ and transferring the first WDM single wavelength signal [lambda] ₁ branched from a first optical coupler to the second network port; WDM optical element; A first analyzer port for providing said first WDM single wavelength signal [lambda] ₁ branched from said first optical coupler to a monitoring system; And a second analyzer port for providing the monitoring system with the second WDM single wavelength signal [lambda] ₂ branched from the second optical coupler.

Description

Single core network tap {SINGLE CORE NETWORK TAP}

The dual-core network port configuration consists of a single-core network port, which frees the signal of a single wavelength to the monitoring system, and selects one of the WMD wavelengths according to the WDM network structure. Signals were provided to the monitoring system to realize single core network monitoring.

The present invention relates to a single core network tap used in a monitoring system applied to a network configuration based on a wavelength division multiplexing (WDM) fiber subscriber loop (WDM) for configuring a transmission path by independently assigning wavelengths to subscribers. .

The network tap used for the optical subscriber network has the dual core form of FIG. 2, and the SWITCH / ROUTER TX upstream of ELEMENT 1 and the SWITCH / ROUTER RX downstream of ELEMENT 1 are configured in pairs and have respective directions. I / O is used for monitoring system.

However, this method can be used in a dual core network, but cannot be used in a WDM network using a single core network as shown in FIG. In the WDM network where SWITCH / ROUTER T / RX upstream (λ1) and downstream (λ2) of ELEMENT 1 coexist in a single core, it is not applicable to the monitoring system through additional equipment and multiple devices.

There is a problem in that the SWITCH / ROUTER TX upward (λ2) of ELEMENT 1 and the SWITCH / ROUTER RX downward (λ1) of ELEMENT 1 are separated into pairs and used in a dual core network tap form.

The present invention has been made to improve the prior art as described above, by configuring the network port configuration of the dual core type of the existing Figure 1 to be used as a single core network port of Figure 3 at the same time eliminating additional equipment and processes It is possible to provide the wavelength signal of the network port output to the monitoring system by selecting an arbitrary wavelength among the WDM network structure from the existing network tap that provided only a single wavelength signal to the monitoring system. Its purpose is to realize single-core network monitoring.

In order to achieve the above object and to solve the problems of the prior art, a single core network tap according to an embodiment of the present invention, the first network port to which the first WDM wavelength signal is input; A second network port to which a second WDM wavelength signal is input; A first WDM optical element for filtering the first WDM signal into a first WDM single wavelength [lambda] ₁ signal and transferring a second WDM single wavelength [lambda] ₂ branched from a second optical coupler to the first network port; A second WDM that filters the second WDM wavelength signal into the second WDM single wavelength [lambda] ₂ signal and transfers the first WDM single wavelength [lambda] ₁ signal branched from a first optical coupler to a second network port; Optical elements; A first optical coupler for dividing a first WMD single wavelength (λ ₁ ) signal in half as a connection element between the second WDM optical element and the first analyzer port; A second optical coupler for dividing the second WMD single wavelength (λ ₂ ) signal in half as an element for connecting the first WDM optical element and the second analyzer port; A first analyzer port for providing said monitoring system with said first WDM single wavelength signal [lambda] ₁ branched from said first optical coupler; And a second analyzer port for providing the second WDM single wavelength signal [lambda] ₂ branched from the second optical coupler to a monitoring system.

The dual-core network port configuration can be used as a single-core network port to omit unnecessary equipment and processes, and it is possible to skip arbitrary wavelengths and provide a single wavelength signal to the monitoring system. By selecting to implement the wavelength signal of the network port output to the monitoring system, any wavelength can be provided by one device.

1 is a conventional dual core network tap structure diagram.
2 is a block diagram of a WDM optical communication network according to FIG. 1;
3 is a diagram illustrating a single core network tap structure according to an embodiment of the present invention.
4 is a configuration diagram of a WDM optical communication network according to FIG. 3;
5 is a diagram illustrating a single core bypass network tap structure according to an embodiment of the present invention.
6 is a block diagram of a WDM optical communication network according to FIG. 5;

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

3 is a schematic diagram of a single core network tap according to an embodiment of the present invention, FIG. 4 is a schematic diagram of a WDM optical network according to FIG. 3, and FIG. 5 is a diagram of a single core bypass network tap according to an embodiment of the present invention. 6 is a configuration diagram of a WDM optical communication network according to FIG. 5.

One embodiment of the present invention is the first network port (NETWORK A (T / RX)) 110, the second network port (NETWORK B (T / RX)) 120, the first optical coupler 130, 2 optical coupler 140, a first WDM optical device 150, a second WDM optical device 160, a first analyzer port (ANALYZER A (TX)) 170, and a second analyzer port (ANALYZER B (TX) )) (180).

The first WDM wavelength signal input to the first network port NETWORK A (T / RX) 110 of FIG. 3 is a first WDM single wavelength signal λ1 of various wavelengths through the first WDM optical element 150. Filtered to and transmitted to the first optical coupler (130). The signal input to the first optical coupler 130 is sent to the second WDM optical device 160 to maintain the existing network. The first WDM single wavelength signal [lambda] 1 sent to the first analyzer port (ANALYZER A (TX)) 170 is also provided to the monitoring system.

A second WDM wavelength signal input to the second network port NETWORK B (T / RX) 120 of FIG. 3 is a second WDM single wavelength signal lambda 2 of various wavelengths through the second WDM optical device 160. The filter is filtered and transmitted to the second optical coupler 140. The signal input to the second optical coupler 140 is sent to the first WDM optical device 150 to maintain the existing network. In addition, a second WDM single wavelength signal [lambda] 2 sent to the second analyzer port (ANALYZER B (TX)) 180 is provided to the monitoring system.

Regardless of the first analyzer port (ANALYZER A (TX)) 170 and the second analyzer port (ANALYZER B (TX)) 180, the first network port (NETWORK A (T / RX)) 110 and the first 2, the network port (NETWORK B (T / RX)) 120 maintains the WDM network and changes the first WDM optical element 150 and the second WDM optical element 160 according to the wavelength required by the user. By outputting the desired single wavelength (λn), you can provide arbitrary wavelengths to the monitoring system to monitor the network status by wavelength.

In addition, in the trend that Internet security is important, public institutions and enterprises use a single core because most security devices that use intrusion prevention system (IPS), intrusion detection system (IDS), and firewall are using dual core network type. There is a difficulty in compatibility with the network.

In order to compensate for this, as shown in FIG. 5, a device for converting a single core network into a dual core network type for a security device is freely used in a WDM network structure.

That is, the first network port (NETWORK A (T / RX)) 210, the second network port (NETWORK B (T / RX)) 220, the first WDM optical element 230, the second WDM optical element (240), a first analyzer port (ANALYZER A (TX, RX)) (250), and a second analyzer port (ANALYZER B (TX, RX)) (260).

The first analyzer port (ANALYZER A (TX, RX)) 250 filters the first WDM wavelength signal from the first WDM optical element 230 as a first WDM single wavelength signal λ1, and transmits it to the monitoring system for monitoring. The wavelength signal λ1-1 received from the system is transmitted to the first WDM optical device 230.

The second analyzer port (ANALYZER B (TX, RX)) 260 filters the second WDM wavelength signal from the second WDM optical element 240 into the second WDM single wavelength signal λ2, and transmits it to the monitoring system for monitoring. The wavelength signal λ2-1 received from the system is transmitted to the second WDM optical device 240.

As described above, according to the present invention, a dual core network port configuration can be used as a single core network port so that unnecessary equipment and processes can be omitted and only a single wavelength signal is provided to the monitoring system. In addition, arbitrary wavelengths can be selected according to the WDM network to provide a wavelength signal at the network port output to the monitoring system so that any wavelength can be provided by one equipment.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only in accordance with the following claims, and all equivalents or equivalent variations thereof are included in the scope of the present invention.

Claims (2)

A first network port to which a first WDM wavelength signal is input;
A second network port to which a second WDM wavelength signal is input;
A first WDM optical filter for filtering the first WDM wavelength signal into a first WDM single wavelength signal λ ₁ and for transmitting a second WDM single wavelength signal λ ₂ branched from a second optical coupler to the first network port device;
A second filter for filtering the second WDM wavelength signal into the second WDM single wavelength signal [lambda] ₂ and transferring the first WDM single wavelength signal [lambda] ₁ branched from a first optical coupler to the second network port; WDM optical element;
A first analyzer port for providing said first WDM single wavelength signal [lambda] ₁ branched from said first optical coupler to a monitoring system; And
A second analyzer port for providing said second WDM single wavelength signal [lambda] ₂ branched from said second optical coupler to said monitoring system
Single core network tab comprising a. delete

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