KR20040009525A - TMI Multiplexer for CWDM using fine tuning Waveguide - Google Patents

Abstract

PURPOSE: A two-mode interference wavelength multiplexer for coarse wavelength division multiplexing for controlling a fine channel is provided to control a channel interval between wavelengths of light waves by controlling the length of the waveguide inserted into a dual mode waveguide. CONSTITUTION: A two-mode interference wavelength multiplexer for coarse wavelength division multiplexing for controlling a fine channel includes an input waveguide(101), a dual mode waveguide and an output waveguide(103). The input waveguide(101) is used for receiving light waves. The dual mode waveguide and the output waveguide(103) are used for traveling an excited even-numbered mode and an excited odd-numbered mode through a Y-branch structure. A waveguide(102) having a minimum difference between electric wave constants of the even-numbered and the odd-numbered modes for a variation of wavelength is inserted into an intermediate part of the dual mode waveguide.

Description

Two-mode interference wavelength multiplexer for fine-density wavelength division multiplexing {TMI Multiplexer for CWDM using fine tuning Waveguide}

The present invention relates to a TMI used in the field of communication, and not only can finely adjust the channel spacing using a TMI inserted with a waveguide having the smallest wave constant difference between two modes with respect to the change of wavelength, Distribution also has the same characteristics as a typical TMI. The conventional TMI configuration as shown in FIG. 2 includes an input waveguide 101, a dual mode waveguide 104, and an output waveguide 103. The TMI serves to propagate the wavelength input from one input waveguide 101 to the output waveguide 103. TMI MUX / DEMUX for CWDM can be used in subscriber network, local area network (LAN), metro area network (MAN). The configuration of the TMI MUX / DEMUX for CWDM is shown in FIG. The configuration of 1 x 4 TMI MUX / DEMUX for CWDM consists of an input waveguide 201, a dual mode waveguide 202 with a channel spacing of 20 nm, a dual mode waveguide 203 with a channel spacing of 40 nm, and an output waveguide 204. It is done. The light waves incident on the input waveguide 201 simultaneously excite the right mode and the pre-mode in the Y-branch structure, and propagate in the sine wave square form to each output waveguide through the dual mode waveguide 202 having a channel spacing of 20 nm. do. At this time, when the square wave of the sine wave is input to the dual mode waveguide 203 having a channel spacing of 40 nm, the sine wave having only a specific wavelength component in the output waveguide 204 while propagating the dual mode waveguide 203 having a channel spacing of 40 nm. The square wave of is distributed to each output waveguide. In general, the channel spacing of TMI MUX / DEMUX for CWDM is quite wide, 10 nm and 20 nm. In the case of TMI MUX / DEMUX for CWDM with a channel spacing of 20 nm, the spacing between the four wavelengths output from the bimodal waveguide 202 with a first channel spacing of 20 nm is 20 nm, and a bimodal waveguide with a second channel spacing of 40 nm. By adjusting the length of 203 and adjusting the interval between the two wavelengths to be output to 40 nm, each output waveguide 204 outputs wavelengths having a channel interval of 20 nm, respectively. Here, an error occurs between the channel intervals in adjusting the channel intervals with the length of the dual mode waveguide 203 having a channel interval of 40 nm.

By inserting the waveguide having the smallest propagation constant difference between the right mode and the pre-mode with respect to the change in wavelength as shown in FIG. 1, the structure can be more finely adjusted than adjusting the channel spacing of the general CWDM TMI MUX / DEMUX.

Adjusting the channel spacing to the length of the dual mode waveguide 203 as in MUX / DEMUX for CWDM using a general TMI must bear the error of the channel spacing of the output waveguide 204, but the propagation constant between the two modes for the change of wavelength Changing the length of the inserted waveguide by inserting the waveguide having the smallest difference is a method of accurately matching the channel spacing of the wavelength output from the output waveguide 204.

The present invention relates to a TMI used in the field of communication, and not only can finely adjust the channel spacing using a TMI inserted with a waveguide having the smallest wave constant difference between two modes with respect to the change of wavelength, Distribution also has the same characteristics as a typical TMI. The conventional TMI configuration as shown in FIG. 2 includes an input waveguide 101, a dual mode waveguide 104, and an output waveguide 103. The TMI serves to propagate the wavelength input from one input waveguide 101 to the output waveguide 103. TMI MUX / DEMUX for CWDM can be used in subscriber network, local area network (LAN), metro area network (MAN). The configuration of the TMI MUX / DEMUX for CWDM is shown in FIG. The configuration of 1 x 4 TMI MUX / DEMUX for CWDM consists of an input waveguide 201, a dual mode waveguide 202 with a channel spacing of 20 nm, a dual mode waveguide 203 with a channel spacing of 40 nm, and an output waveguide 204. It is done. The light waves incident on the input waveguide 201 simultaneously excite the right mode and the pre-mode in the Y-branch structure, and propagate in the sine wave square form to each output waveguide through the dual mode waveguide 202 having a channel spacing of 20 nm. do. At this time, when the square wave of the sine wave is input to the dual mode waveguide 203 having a channel spacing of 40 nm, the sine wave having only a specific wavelength component in the output waveguide 204 while propagating the dual mode waveguide 203 having a channel spacing of 40 nm. The square wave of is distributed to each output waveguide. In general, the channel spacing of TMI MUX / DEMUX for CWDM is quite wide, 10 nm and 20 nm. In the case of TMI MUX / DEMUX for CWDM with a channel spacing of 20 nm, the spacing between the four wavelengths output from the bimodal waveguide 202 with a first channel spacing of 20 nm is 20 nm, and a bimodal waveguide with a second channel spacing of 40 nm. By adjusting the length of 203 and adjusting the interval between the two wavelengths to be output to 40 nm, each output waveguide 204 outputs wavelengths having a channel interval of 20 nm, respectively. Here, an error occurs between the channel spacing in adjusting the channel spacing to the length of the dual mode waveguide 203 having a channel spacing of 40 nm.

By inserting the waveguide having the smallest propagation constant difference between the right mode and the pre-mode with respect to the change in wavelength as shown in FIG. 1, the structure can be more finely adjusted than adjusting the channel spacing of the general CWDM TMI MUX / DEMUX.

Adjusting the channel spacing to the length of the dual mode waveguide 203 as in MUX / DEMUX for CWDM using a general TMI must bear the error of the channel spacing of the output waveguide 204, but the propagation constant between the two modes for the change of wavelength Changing the length of the inserted waveguide by inserting the waveguide having the smallest difference is a method of accurately matching the channel spacing of the wavelength output from the output waveguide 204.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram schematically illustrating a 1 × 2 TMI (Two-Mode Interference) of a structure using waveguide insertion having the smallest propagation aberration between a right mode and a standby mode for a change in wavelength to which the present invention is applied.

2 is a schematic representation of a typical 1 x 2 TMI.

Figure 3 schematically shows a 1 x 4 TMI MUX / DEMUX for a CWDM.

4 is a schematic representation of a 1 x 4 TMI MUX / DEMUX for CWDM using waveguide insertion used in the present invention.

5 is a wavelength characteristic curve of a TMI MUX / DEMUX for CWDM having a typical channel spacing of 20 nm.

Figure 6 is a wavelength characteristic curve of the TMI MUX / DEMUX for CWDM having a channel spacing 20nm inserted waveguide used in the present invention.

<Description of the symbols for the main parts of the drawings>

101: 1 x 2 TMI input waveguide

102: Waveguide inserted to adjust channel spacing

103: 1 x 2 TMI output waveguide

104: 1 x 2 TMI dual mode waveguide

105: tapered waveguide connecting the dual mode waveguide and the inserted waveguide

201: 1 x 4 TMI input waveguide

202: dual mode waveguide with 20 nm channel spacing

203: dual mode waveguide with 40 nm channel spacing

204: 1 x 4 TMI output waveguide

301: Waveguide inserted to adjust channel spacing

When described in detail according to the accompanying drawings of the present invention for implementing the above object is as follows. 1 is a TMI with a waveguide inserted to adjust channel spacing. In the Y-branch structure of the input waveguide 101, the right mode and the standby mode are simultaneously excited, and the dual mode waveguide 104 is simultaneously processed. The method of designing the waveguide 102 for adjusting the channel spacing is as follows. The waveguide having the smallest difference in propagation constant between two modes with respect to the wavelength change in the middle of the dual mode waveguide 104 may be inserted into the middle portion of the dual mode waveguide 104 by connecting to the tapered waveguide 105. By inserting a waveguide having a small difference in propagation constant between two modes with respect to a change in wavelength, the channel spacing can be adjusted by adjusting the length of the waveguide, and the channel spacing between wavelengths output from the output waveguide 103 can be finely adjusted. . In addition, the method of applying the new structure to TMI MUX / DEMUX for CWDM is as follows. A schematic diagram of a typical TMI MUX / DEMUX for CWDM is shown in FIG. 3. The configuration of MUX / DEMUX for CWDM using a general TMI includes an input waveguide 201, a dual mode waveguide 202 having a first channel spacing of 20 nm, a dual mode waveguide 203 having a second channel spacing of 40 nm, and an output waveguide (204). It is composed of). TMI is suitable for MUX / DEMUX for CWDM with 10nm and 20nm channel spacing. The TMI MUX / DEMUX for 1 × 4 CWDM having a channel spacing of 20 nm adjusts the length of the bimodal waveguide 202 so that the channel spacing is 20 nm. At this time, two wavelengths are output to one waveguide, and the distance between the two wavelengths is 40 nm. When the two output wavelengths are inputted to the dual mode waveguide again, the length of the dual mode waveguide is adjusted to adjust the length so that the channel spacing of the two wavelengths is 40 nm, and only one wavelength is output to the output waveguide. As a result, four wavelengths are output to the four output waveguides, and the channel spacing between these output wavelengths is 20 nm.

Wavelength characteristics of CWDM TMI MUX / DEMUX with a waveguide with small difference in propagation constant between two modes for the change of wavelength are compared with the following through BPM (Beam Propagation Method) do. The parameters used for the simulation of 1 x 4 TMI MUX / DEMUX with a channel spacing of 20 nm are as follows. The number of channels in TMI MUX / DEMUX is four. The refractive index of the core is 1.4564 and the refractive index of the cladding is 1.4455. neff = 1.45386 and width of input waveguide and output waveguide = 6㎛. First, the length of the bimodal waveguide for the channel spacing of 20nm is 18,000㎛ and the bimode waveguide width = 6.5㎛. Secondly, the length of the bimodal waveguide for making a bimodal waveguide having a channel spacing of 40 nm is 4247 m and the bimodal waveguide width is 6.5 m. The tapered waveguide connecting the dual mode waveguide has an initial width of 6.5 μm, a terminal width of 8 μm, and a taper length of 500 μm. The length of the inserted waveguide 301 to adjust the channel spacing is 103 탆 and 15 탆, respectively. The tapered waveguide connecting the inserted waveguide and the dual mode has an initial width of 8 μm, a terminal width of 6.5 μm, and a taper length of 500 μm. The length of the bimodal waveguide is 4247 m and the bimodal waveguide width = 6.5 m. At this time, the center wavelength = 1.55㎛ and simulated using BPM. Simulation results show that the wavelength characteristic curve of the TMI MUX / DEMUX for CWDM having a typical channel spacing of 20 nm is shown in FIG. 5. The channel spacing is 20nm, crosstalk is -21.8dB, and the loss over the full wavelength is 1.016-1.253dB. The crosstalk is -17.5dB and the bandwidth is 2.4-5.4nm. FIG. 6 shows a wavelength characteristic curve of the TMI MUX / DEMUX for CWDM having a channel spacing of 20 nm inserted with a waveguide for adjusting the channel spacing. The channel spacing is 20nm, crosstalk is -26.3dB, and the loss range over the entire wavelength is 0.933-1.267dB. The crosstalk is -17.5dB and the bandwidth is 4.4-5.5nm.

Comparing the general TMI MUX / DEMUX for CWDM with the TMI MUX / DEMUX for CWDM with the smallest waveguide difference between the two modes for the change of wavelength, crosstalk occurs in the wavelength characteristic of FIG. 6 with a new waveguide. Has been improved by -4.5dB and the bandwidth has been widened by 2nm. This makes it possible to more accurately adjust the channel spacing in FIG. 4 in which the waveguide of the new structure is inserted.

The above has shown only the embodiments according to the present invention, but does not limit the application according to the present invention.

As described above, the present invention relates to a TMI MUX / DEMUX used to configure a subscriber network, a LAN, and a MAN by wavelength division multiplexing. In the present invention, the optical wave incident on the input waveguide 101 in the TMI simultaneously excites the right mode and the pre-mode, and simultaneously proceeds the dual mode waveguide 104, wherein the propagation constant between the two modes for the change of the wavelength is here. The smallest difference waveguide is inserted in the middle of the dual mode waveguide 104, and the length of the inserted waveguide is adjusted to adjust the channel spacing between the wavelengths of the sine wave-type optical wave output to the output waveguide 103. The waveguide with the smallest propagation difference between the two modes with respect to the wavelength change is inserted in the middle of the dual mode waveguide 104, so that all the performance is the same as the conventional TMI MUX / DEMUX, but the channel accuracy is more accurate in terms of adjusting the channel spacing. Excellent structure with adjustable gap.

Claims (1)

It consists of an input waveguide 101 into which light waves are input, a dual mode waveguide 104 and an output waveguide 103 in which a right mode and an excited mode progress simultaneously through an Y-branch structure, and an output waveguide 103. TMI MUX / DEMUX inserting waveguide with the smallest difference in propagation constant