KR100539918B1 - Ad Drop Multiplexing Apparatus and Method for Forming Various Channels - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

The present invention relates to an apparatus and method for add drop multiplexing for various channel formation in a wavelength division multiplexing system.

I. The technical problem to be solved by the invention

Various channel formation is possible even if the channel of the transmission system is limited.

All. Summary of Solution of the Invention

An arrayed waveguide grating device for separating and outputting an optical signal for each main wavelength by wavelength division demultiplexing an input optical signal, or for receiving an optical signal of various main wavelengths and performing wavelength division multiplexing and outputting the output optical signal as an output optical signal; Receives an optical signal of any one main wavelength including a sub-wavelength optical signal separated from the waveguide grating device, and separates an optical signal of a sub-wavelength having a prespectral range relationship with the main wavelength from the optical signal. A first optical splitter for dropping and outputting an optical signal of the sub-wavelength, and a subchannel identical to the optical signal of the dropped sub-wavelength, which is added to the optical signal of a main wavelength not dropped after being separated from the first optical splitter; The arrayed waveguide grating is obtained by receiving an optical signal having a wavelength and multiplexing two optical signals. A device is provided with a second optical splitter which serves as an optical signal of a main wavelength.

la. Important uses of the invention

The present invention is used in a wavelength division transmission system.

Description

Ad Drop Multiplexing Apparatus and Method for Forming Various Channels

The present invention relates to a wavelength division multiplexing (hereinafter referred to as WDM) transmission system, and more particularly to an apparatus and method for add drop multiplexing (hereinafter referred to as ADM).

A conventional ADM process will be described with reference to FIG. 1, which schematically illustrates the operation of an arrayed waveguide grating (hereinafter referred to as AWG) device for ADM in a conventional optical WDM transmission system. The input optical signals λ _1, λ _{2, and} λ ₃ in which optical signals having wavelengths of λ _1, λ _{2 and} λ ₃ are wavelength-division multiplexed are input to the AWG device 100. A second optical signal in the AWG device 100 has the input optical signal the first optical signal (λ ₁₎ of the λ ₁ separated by wavelengths by the wavelength division demultiplexing the _{(λ 1, λ 2, λ} 3), λ 2 ( λ _2), and outputs it as the third optical signal (λ ₃₎ of the λ _3.

The remaining optical signals, except for the first optical signal λ ₁ , which is the optical signal to be dropped, are input to the AWG device 100 again. The first optical signal (λ ₁₎ is the drop is output to the outside, is add to the first optical signal (λ ₁₎ and the fourth optical signal (λ ₁₎ the AWG device 100 of the same wavelength from the outside is input . The AWG device 100 performs wavelength division multiplexing on the second optical signal λ ₂ , the third optical signal λ ₃ , and the fourth optical signal λ ₁ , thereby outputting the output optical signals λ _1, λ _{2, and} λ _3. Output as

Since the channel of the conventional optical WDM transmission system is limited depending on the wavelength used, it is difficult to form various channels for additional services between adjacent points.

As described above, the channel of the conventional optical WDM transmission system is limited, which makes it difficult to form various channels.

Accordingly, an object of the present invention is to provide an ADM apparatus and method for enabling various channel formation.

According to the present invention for achieving the above object, the optical signal is separated and output by the main wavelength by multiplexing the input optical signal, or the optical signal of the various main wavelengths is input and the wavelength division multiplexed and output as the output optical signal. A raid waveguide grating device and an optical signal having a main wavelength separated from the arrayed waveguide grating device are input, and an optical signal having a sub wavelength having a prespectral range relationship with the main wavelength is separated from the optical signal. It receives a first optical splitter for dropping and outputting an optical signal of the sub-wavelength, an optical signal of a main wavelength that is not dropped after being separated from the first optical splitter, and an optical signal of a wavelength of a subchannel to be added. Multiplexing an optical signal and providing the arrayed waveguide grating apparatus as an optical signal of a main wavelength And a second light splitter.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. While many specific details are set forth in the following description and in the accompanying drawings, to provide a more general understanding of the invention, these specific details are illustrated for the purpose of illustrating the invention and are not meant to limit the invention thereto. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

Typically, AWG devices have free spectral range (hereinafter referred to as FSR) characteristics. According to the FSR characteristic, when the AWG device separates an optical signal of one wavelength (hereinafter, referred to as "main wavelength") by wavelength division demultiplexing an input optical signal, the optical signal of the main wavelength has a different wavelength (hereinafter, " Sub-wavelength ”, and the sub-wavelength is given by Equation 1 below.

[Equation 1]

As described above, when the AWG device separates an optical signal of one main wavelength from an input optical signal, the separated optical signal includes an optical signal of a sub wavelength. Accordingly, in the present invention, more various channel formation is possible by using the optical signal of the sub-wavelength included in the optical signal of the main wavelength separated by the AWG device.

An embodiment of the present invention will be described in detail with reference to FIG. 2, which shows a configuration diagram of an ADM device using the FSR characteristics of such an AWG device. First, the receiving side loads data on λ ₁ , λ ₂ , λ ₃ , which are main wavelengths, and λ ₁ ′, which is a sub wavelength with respect to λ ₁ , and then transmits the result by wavelength division multiplexing.

The input optical signals λ _1, λ ₁ ′, λ _{2, and} λ ₃ transmitted by wavelength division multiplexing in this way are input to the AWG device 200. The AWG device 200 separates and outputs the input optical signals λ _1, λ ₁ ′, λ _{2, and} λ ₃ by wavelength division demultiplexing for each main wavelength. An optical signal output from the AWG device 200 and the first and second optical signals (λ _1, λ ₁ ') according to the main wavelength λ _1, a main wavelength of the third optical signal (λ ₂₎ and according to the λ ₂ a fourth optical signal (λ ₃₎ in accordance with the main wavelength λ _3. Here, λ ₁ ′ is a sub wavelength with respect to λ ₁ , which is a main wavelength, and thus the first optical signal λ ₁ and the second optical signal λ ₁ ′ are output together without being separated from each other.

Since the third optical signal λ ₂ and the fourth optical signal λ ₃ are signals that are not added or dropped in the ADM device of FIG. 2, the third optical signal λ ₂ and the fourth optical signal λ ₃ are input to the AWG device 200 as they are.

The first and second optical signals λ _{1 and} λ ₁ ′ are input to the first optical splitter 202, and the first optical splitter 202 is provided with the first and second optical signals λ _{1 and} λ _1. ') Is output as the first optical signal λ ₁ and the second optical signal λ ₁ ' separately. Here, the second optical signal λ ₁ ′ is dropped and output. The first optical signal λ ₁ is input to the second optical splitter 204 without being dropped. The fifth optical splitter 204 is input with the fifth optical signal λ ₁ ′ having the same wavelength as the second optical signal λ ₁ ′. The second optical splitter 204 multiplexes the first optical signal λ ₁ and the fifth optical signal λ ₁ ′ and inputs the same to the AWG device 200.

The AWG device 200 performs wavelength division multiplexing on the first and fifth optical signals λ _{1 and} λ ₁ ′ multiplexed with the second optical signal λ ₂ and the third optical signal λ ₃ . Output as ( lambda _1, lambda ₁ ', lambda _2, lambda ₃ ).

As described above, the present invention enables the formation of a subchannel using a subwavelength having an FSR relationship with the main wavelength in addition to the main wavelength. Accordingly, even if the main channel according to the main wavelength is limited, it is possible to form various channels between adjacent points.

As described above, the present invention enables various channels to be formed even if the channel is limited in the transmission system.

1 schematically illustrates the operation of a conventional AWG device;

2 is a block diagram of an ad drop multiplexing device according to a preferred embodiment of the present invention.

Claims (2)

In the add-drop multiplexing device for forming various channels, An arrayed waveguide grating device for separating and outputting an optical signal for each main wavelength by multiplexing an input optical signal by wavelength division demultiplexing, or for receiving an optical signal of various main wavelengths and performing wavelength division multiplexing to output an output optical signal; Receives an optical signal of any one main wavelength including an optical signal having a sub wavelength separated from the arrayed waveguide grating device, and receives an optical signal of a sub wavelength having a prespectral range relationship with the main wavelength from the optical signal A first optical splitter that separates and outputs an optical signal of that sub-wavelength by dropping the signal; The optical signal of a wavelength of the same subchannel as the optical signal of the dropped sub-wavelength, which is added after being separated from the first optical splitter, and the optical signal of the dropped sub-wavelength is input, and the two optical signals are multiplexed to form the arrayed signal. And a second optical splitter for providing the waveguide grating apparatus as an optical signal of a main wavelength. In the drop multiplexing method for forming various channels, Separating and outputting the optical signal for each main wavelength by multiplexing the input optical signal by wavelength division demultiplexing; Receiving the optical signal of one main wavelength including the optical signal by the separated sub-wavelength and dropping the optical signal of the sub-wavelength; After the optical signal of the sub-wavelength is dropped from the optical signal of one main wavelength including the optical signal of the sub-wavelength, an optical signal having the same wavelength as that of the dropped sub-wavelength is added and multiplexed to receive the optical signal of the main wavelength. Outputting the signal, And receiving an optical signal of various main wavelengths, including an optical signal of the main wavelength generated by the multiplexing, and performing a wavelength division multiplexing to output the output optical signal as an output optical signal.