KR20000028277A - Optical buffer using loop mirror - Google Patents

Abstract

PURPOSE: An optical buffer using a loop mirror is provided to store a cell having a lower priority order and to output at a needed time for solving a clash of cells needed to output with the same channel in a time separation multiplex network of high speed. CONSTITUTION: An optical buffer is equipped a loop mirror(10) to store by branching a cell inputted in early from an input terminal and to reflect to the inputted direction, an input device of cell(20) to re-input to the loop mirror by controlling a benefit and a phase of the cell reflected from the loop mirror, and an output device(30) to send the cell output by disconforming a phase in the loop mirror according to the input of a control pulse to the loop mirror. The loop mirror(10) is equipped a first optical coupler(12) to diverge the inputted cell in a regular rate(for example, 50: 50), and a dispersion shifted fiber(14) as a moving path of the cell inputted by diverging in the first optical coupler(12). Loops(21,22) of the inputting device of cell(20) comprises of a single mode fiber(21) as the moving path of the cell inputted by diverging with a second optical coupler(23), and a semiconductor optical amplifier(22) to amplify an optical power of the cell moved clockwise and counter clockwise in the single mode fiber(21). The position of the semiconductor optical amplifier(22) is located in the center of the single mode fiber(21).

Description

Optical buffer using loop mirror

The present invention relates to an optical buffer using a loop mirror, and more particularly, in order to resolve collisions between cells to be output on the same channel in a fast time division multiple local area network, a cell having a low priority is stored and stored at a necessary time. The present invention relates to an optical buffer using a loop mirror in which an output is made.

In recent years, as the service demands of users are rapidly increasing and a high speed network is required, it is difficult to solve the packet collision by the electric buffering method by the optical / electric conversion at any switching node. In addition, a method of optically buffering (AJ Poustie, AE Kelly, KJ Blow and RJ Manning, "All-optical regenerative memory with full read / write capability", Technical Digest Series vol. 5, April 1, 1998) is proposed. However, this method has a problem in that the structure is complicated and difficult to control since the wavelength conversion must be continued in the buffering process and a new light source is required for the wavelength conversion.

Accordingly, the present invention has been made in view of the above-described conventional situation. In a high-speed network, when several cells arrive at one node at the same time, a low priority cell is optically stored as necessary and stored when there is room in traffic. It is an object of the present invention to provide an optical buffer using a loop mirror that outputs a cell to be sent to a desired node without collision.

In order to achieve the above object, an optical buffer using a loop mirror according to a preferred embodiment of the present invention, a loop mirror for branching and storing the cell initially input from the input terminal and reflecting in the input direction,

Cell input means for adjusting the gain and phase of the cell reflected from the loop mirror to re-enter the loop mirror;

And outputting means for sending a cell outputted out of phase with the loop mirror as a control pulse is input to the loop mirror.

1 is a block diagram of an optical buffer using a loop mirror according to a preferred embodiment of the present invention.

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

1: cell 10: loop mirror

12: first optical coupler 14: dispersed shift fiber

20 cell input means 21 single mode fiber

22 semiconductor optical amplifier 23 second optical coupler

24 bandpass filter 25 third optical coupler

26: isolator 30: output means (band pass filter)

40: optical rotating machine 100: control pulse

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

1 is a block diagram of an optical buffer using a loop mirror according to a preferred embodiment of the present invention, and includes a loop mirror 10 for branching, storing, and reflecting a cell initially inputted from an input end, and from an input end. A cell input means 20 for inputting an initial input cell to the loop mirror 10 and adjusting the gain and phase of the cell reflected by the loop mirror 10 to re-enter the loop mirror 10; As the control pulse 100 is input to the loop mirror 10, an output means 30 for sending out a cell output out of phase with the loop mirror 10, and the loop mirror 10 and the output means ( 30 is provided between the optical rotator 40 to rotate the light so that only the cell initially input at the time of cell output by the control pulse 100 input from the outside through the output means (30).

The loop mirror 10 includes a first optical coupler 12 (WDM optical coupler) for dividing an input cell at a predetermined ratio (for example, 50:50), and a cell branched from the first optical coupler 12 and input. Dispersion Shifted Fiber (14), which is a moving path of, is provided.

The cell input means 20 includes loops 21 and 22 for branching and storing the cells reflected by the loop mirror 10 and re-outputting the phase matched cells in the input direction, and the loop and the loop mirror ( A second optical coupler 23 (2; 2 x 2) provided between the second and second branches to branch the cells from the loop mirror 10 to input the loops and to provide the cells from the loops to the loop mirror 10 side. Optical coupler) and the second optical coupler 23 and the loop mirror 10 to provide a cell from the loop mirror 10 to the second optical coupler 23 and to provide the second optical coupler. A band-pass filter 24 which removes noise of the cell from the combiner 23 and sends it to the loop mirror 10, between the band-pass filter 24 and the first optical combiner 12; A cell from the loop mirror 10 to the bandpass filter 24 and Blowing through the third optical coupler 25 (2 × 1 optical coupler) to send the cell from the bandpass filter 24 to the loop mirror 10 and through the third optical coupler 25 while the cell is being stored. It is provided with an isolator 26 for removing a cell copied and returned to the input terminal.

The loop is a single mode fiber (21) which is a movement path of a cell branched by the second optical coupler (23), and moves clockwise and counterclockwise in the single mode fiber (21). And a semiconductor optical amplifier 22 for amplifying the optical power of the cell. Here, the position of the semiconductor optical amplifier 22 is located at the center of the single mode fiber 21.

Next, the operation of the optical buffer using the loop mirror according to the embodiment of the present invention configured as described above is as follows.

First, traffic is increased in any one node, and collision between cells is expected, and the cell 1 having low priority is input. For ease of explanation, the wavelength of the input cell 1 is referred to as λ _S. At this time, the isolator 26 in the cell input means 20 receiving the cell 1 removes the cell which is copied through the third optical coupler 25 and partially reflected back to the input part while the cell is stored. The cell input via the third optical coupler 25 is input to the first optical coupler 12 of the loop mirror 10, and the first optical coupler 12 is connected to the input cell 1 at 50: 50. Branching is performed at a rate of 50, and at a ratio of 0: 100 for the control pulse 100 (? C) to be discussed later. The input cell 1 is split into 50:50 by the first optical coupler 12 and divided into cells traveling in the clockwise direction and cells traveling in the counterclockwise direction, and then provided as the dispersed shift fiber 14. Dispersion Shifted Fibers (14) are nonlinear fibers that have a property that the refractive index changes depending on the bit power of the inputted cells. Because the input cells branched at the same rate, the bits in the clockwise and counterclockwise cells experience the same change in refractive index. Since the change in the refractive index is proportional to the change in phase, the cells traveling in both directions eventually become the same phase and are phase-matched when the loop returns.

By this operation, the input cell reflected by the loop mirror 10 passes through the band pass filter 24 through the third optical coupler 25. The center wavelength of the bandpass filter 24 is set to λ _S so as to pass only the input cell, and the input cell passed through the bandpass filter 24 has a second optical coupler 23 having a distribution ratio of 50:50. ) Is entered. The input cell branches into a loop, in which bits in the clockwise and counterclockwise cells are input to the semiconductor optical amplifier 22 at the same time, undergoing the same gain and phase, and rotating around the loop. . The cells returned to the second optical coupler 23 are eventually phase matched and output in the direction in which the cells are input. The output input cell λ _S passes through a bandpass filter 24 having a center wavelength of λ _{S. In} this case, the bandpass filter 24 includes an ASE (A) where cells are added through the semiconductor optical amplifier 22. Amplified Spontaneous Emission. The input cell passing through the bandpass filter 24 is input to the loop mirror 10 via the third optical coupler 25. The input cell inputted to the loop mirror 10 is output in the input direction again by turning the loop once as described above.

Unless any control pulse 100 is input from the outside, the input cell has the effect of being stored permanently. In order to output the input cell at a desired time, the control pulse 100 may be incident in the opposite direction to which the input cell is input in the first optical coupler 12. At this time, the number of bits of the control pulse 100 is the same as the number of bits of the input cell, all composed of "1", and must be large enough to cause the nonlinear effect while the dispersion shift fiber 14 is advanced. In addition, the control pulse 100 is equal to the timing at which the input cell is input to the first optical coupler 12 so that the bits of the two cells running counterclockwise should overlap each other.

When the control pulse 100 is input, the operation in the loop mirror 10 composed of the first optical coupler 12 and the dispersion shift fiber 14 is as follows.

As described above, the cells 1 input through the cell input means 10 branch from the first optical coupler 12 at a ratio of 50:50 and progress in opposite directions, respectively. On the other hand, the control pulse 100 causes all the beams to run counterclockwise in the ratio of 0: 100 in the first optical coupler 12. The input cell running in the clockwise direction undergoes only a slight phase change since the pulse power of each bit is small enough so that the nonlinear effect is not obtained while the dispersion shift fiber 14 is advanced. On the other hand, the input cell traveling in the counterclockwise direction has an optical kerr effect by the power of the control pulse 100. Here, the optical kerr effect refers to a phenomenon in which the change of the refractive index in any medium is proportional to the square of the electric filed. Therefore, each bit of the input cell traveling in the counterclockwise direction has a relative phase difference compared to the bits of the input cell running in the clockwise direction. As such, when the power of each pulse of the control pulse 100 is properly adjusted, the respective bits of the input cells traveling in opposite directions by the first optical coupler 12 have a phase difference of π. Thus, the input cell 1 is output in the opposite direction that was output before the control pulse 100 was incident. The control pulse 100 is output in the direction input by the distribution ratio after proceeding in the counterclockwise direction. The output two cells are redirected by the optical rotator 10 and are input to the band pass filter 30 as an output means having a center wavelength of λ _S. The control pulse is removed by the band pass filter 30 having the center wavelength of lambda _S , and only the input cell 1 (lambda _S ) is output.

According to the present invention as described above, it is possible to optically store the low-priority cells as necessary, and output the stored cells when there is enough traffic to resolve the collisions between the cells, thereby improving the efficiency of the high-speed network. Can be.

On the other hand, the present invention is not limited only to the above-described embodiments, but may be modified and modified without departing from the scope of the present invention.

Claims (15)

A loop mirror for branching and storing a cell initially inputted from an input terminal and reflecting it in the input direction; Cell input means for adjusting the gain and phase of the cell reflected from the loop mirror to re-enter the loop mirror; And output means for sending a cell outputted out of phase with the loop mirror as a control pulse is input to the loop mirror. The method of claim 1, The loop mirror includes a first optical coupler for branching an input cell at a predetermined ratio, and a dispersion shift fiber which is a movement path of the branched input cell. The method of claim 2, And the first optical coupler is configured as a wavelength division multiplexing (WDM) combiner. The method of claim 3, The wavelength division multiplexing combiner splits an input cell at a 50:50 ratio, and branches at a ratio of 0: 100 with respect to the control pulse. The method of claim 1, The cell input means includes a loop for branching and storing a cell reflected by the loop mirror and re-outputting a phase matched cell in an input direction, and branching a cell from the loop mirror and inputting the loop into the loop. A second optical coupler providing a cell from a loop to the loop mirror side, a cell from the loop mirror to the second optical coupler side, and removing a noise of a cell from the second optical coupler side to the loop mirror side And a third optical combiner for sending a cell from the loop mirror to the band pass filter and sending a cell from the loop mirror to the loop mirror. buffer. The method of claim 5, The loop is composed of a single mode fiber which is a movement path of a cell branched by the second optical coupler and a semiconductor optical amplifier which amplifies the optical power of a cell moving in the single mode fiber. Optical fiber using. The method of claim 5, The center wavelength of the bandpass filter is the same as the wavelength of the initial input cell optical buffer using a loop mirror. The method of claim 6, And the semiconductor optical amplifier is located at the center of the single mode fiber. The method of claim 1, The cell input means includes a loop for branching and storing a cell reflected by the loop mirror and re-outputting a phase matched cell in an input direction, and branching a cell from the loop mirror and inputting the loop into the loop. A second optical coupler providing a cell from a loop to the loop mirror side, a cell from the loop mirror to the second optical coupler side, and removing a noise of a cell from the second optical coupler side to the loop mirror side A third optical combiner for sending outgoing bandpass filters, a cell from the loop mirror to the bandpass filter, and sending a cell from the bandpass filter to the loop mirror, and the third optical coupler while the cell is stored A loop mirror having an isolator for removing the cell copied through the input terminal and returning to the input terminal Using the light buffer. The method of claim 9, The loop is composed of a single mode fiber which is a movement path of a cell branched by the second optical coupler and a semiconductor optical amplifier which amplifies the optical power of a cell moving in the single mode fiber. Optical fiber using. The method of claim 9, The center wavelength of the bandpass filter is the same as the wavelength of the initial input cell optical buffer using a loop mirror. The method of claim 10, And the semiconductor optical amplifier is located at the center of the single mode fiber. The method of claim 1, And the number of bits of the control pulse is the same as the number of bits of the input cell when the cell is output through the output means. The method of claim 13, And the control pulse at the time of outputting the cell through the output means is equal to the timing at which the input cell is input to the first optical coupler. The method of claim 1, The output means is an optical buffer using a loop mirror, characterized in that the center wavelength is composed of a bandpass filter having the same wavelength as the initial input cell.