KR19980025718A - ATM optical exchange - Google Patents

Abstract

The present invention relates to an ATM optical exchanger, and more particularly, to an ATM optical exchanger that improves the processing efficiency of ATM cells of an optical exchanger by collectively processing a plurality of ATM cells exchanged in an optical exchanger into one supercell.

A conventional optical exchanger must generate an optical signal of a specific wavelength every time to output to each output port each time an ATM cell arrives at an input port. Therefore, when the ATM cell is converted to an optical signal and processed in a short time of several μs or less, there is a problem in that the tuning burden of generating a specific optical wavelength in the optical device becomes large.

The present invention can reduce the tuning burden of adjusting the wavelength of the optical signal transmission unit or the wavelength of the optical signal to be received by the tuner unit by processing a plurality of ATM cells as one super cell in the ATM optical exchanger. In the configuration of the exchanger, the expensive optical element can be simplified and the optical signal can be transmitted quickly, thereby increasing the throughput of the overall exchanger.

Description

ATM optical exchange

The present invention relates to an ATM optical exchanger, and more particularly, to an ATM optical exchanger that improves the processing efficiency of an ATM cell of an optical exchanger by collectively processing a plurality of ATM cells exchanged in an ATM optical exchanger into one supercell.

In general, when processing an ATM cell input from an Asynchronous Transfer Mode (ATM) exchange, the ATM cell processes a 53-byte data unit. The standard ATM interface speeds are 155 Mbit / s and 622 Mbit / s, or 2.4 Gbit / s. Therefore, ATM exchangers exchange ATM cells at high speed through hardware without complicated processing such as error control or flow control. Recently, with the development of optical fiber, faster ATM exchanges have been developed and used by optical exchange. have.

A conventional ATM optical exchanger is provided with an optical / electrical signal conversion unit 30, an optical exchange unit 10, and a control unit 20, as shown in Figure 1 attached to the optical / electrical signal conversion unit 30 Converts an ATM cell transmitted as an optical signal through the input ports I1 to I4 into an electrical signal and outputs the converted electrical signal. The controller 20 detects the output ports 01 to 04 through which the ATM cells are output and controls corresponding to the data stored in the header part of the ATM cell applied from the optical / electric signal converter 30. Output the signal. The optical exchange unit 10 switches according to a control signal applied from the control unit 20 and outputs an ATM cell to output ports 01 to 04 through which the ATM cell is output.

Referring to the operation of the conventional ATM optical switch configured as described above is as follows.

For example, an ATM cell with header information with an output port of O3 is entered into input port I1, an ATM cell with header information with an output port of O2 is input into input port I2, and a header with an output port of O1. When an ATM cell with information is input to input port I3, and an ATM cell with header information having an output port of O4 is input to input port I4, these ATM cells are optically corresponding to the respective input ports I1 to I4. The electrical signal conversion unit 30 is converted into an electrical signal, the control unit 20 can know the output port (01 ~ 04) through the header information of the ATM cell converted to the electrical signal, input to the input port I1 The ATM cell has an output port of O3 and is transmitted on an optical signal of W3. The ATM cell inputted to the input port I2 is transmitted on an optical signal of W2 because the output port is O2. ATM cell has an output port of O1, so the optical signal has an optical wavelength of W1. The ATM cell inputted to the input port I4 is transmitted on an optical signal having an optical wavelength of W4 since the output port is O4. Accordingly, the optical exchange unit 10 multiplexes and outputs the optical signals of W3, W2, W1, and W4 applied from the respective optical / electrical signal converters 30, and the output ports 01 to 04 are multiplexed and applied. Among the optical signals, only the optical signal corresponding to its port is detected and received. That is, output port O1 detects only the optical signal of W1, output port O2 detects only the optical signal of W2, output port O3 detects only the optical signal of W3, and output port O4 detects only the optical signal of W4.

Meanwhile, in the conventional ATM optical exchanger operating as described above, an example of generating an optical signal for optical exchange of ATM cells input through one input port is shown in FIG. 2. For example, when ATM cells input to the input port of I1 are exchanged with output ports O2, O3, O2, O4, and O1, optical / electric signal conversion is first performed on the ATM cells input to the input port of I1 as optical signals. When the unit 30 converts the electric signal, the control unit 20 detects the output port to be output from the header information of the ATM cell and receives the corresponding ATM cell at each output port. W3, W2, W4, W1 will be loaded. Therefore, if the ATM cells applied to the input ports I1 to I4 have the header information of the different output ports 01 to 04, the optical signals having different wavelengths must be generated for each arrival cycle of the ATM cells.

As described above, when the arrival interval of ATM cells arriving at one input port is less than 1 μs in the conventional ATM optical switch, there is a limit in the operation speed of the optical device, so that the optical signal applied to the input port by the ATM cell is converted into an electrical signal. To convert and generate and output the optical signal corresponding to the output port, each time the ATM cell arrives at the input port in a short time of several μs or less, it has to be tuned each time to output to each output port. Therefore, when the ATM cell is converted to an optical signal and processed in a short time of several μs or less, there is a problem in that the tuning burden of generating a specific optical wavelength in the optical device becomes large.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems. The present invention relates to a batch of ATM cells outputted to the same output port among input ATM cells, which are processed at once to generate an optical wavelength each time an ATM cell is input. It is an object of the present invention to provide an ATM optical exchange that can reduce the tuning burden of the exchange and increase the throughput of the overall ATM exchange.

The present invention for achieving the above object, in the ATM optical switch, converts an ATM cell applied to the input port in the state of the optical signal into an electrical signal and then outputs an output port from the data stored in the header of the ATM cell. A plurality of ATM cell processing apparatuses for outputting a supercell in which an output port binds the same number of ATM cells with a predetermined number to an optical signal having a wavelength corresponding to a port to be output; An optical signal multiplexer for multiplexing and outputting an optical signal applied from each of the ATM cell processing apparatuses; And a tuner unit for extracting an optical signal corresponding to each output port from the multiplexed optical signal applied from the optical signal multiplexer and outputting the optical signal to a corresponding output port.

On the other hand, the ATM cell processing apparatus, the buffer is provided corresponding to each output port and stores the ATM cell to be output; Input port processing unit for converting the ATM cell applied to the input port in the state of the optical signal into an electrical signal, detecting the port to be output from the data stored in the header of the ATM cell, and then outputting to the buffer corresponding to the output port Wow; And an optical signal transmitter configured to bundle a predetermined number of ATM cells stored in each of the buffers into one supercell, and then load the ATM signal into an optical signal having a wavelength corresponding to a port to be output.

1 is a block diagram of a conventional ATM optical switch.

2 is a diagram illustrating processing of an ATM cell in the ATM optical switch shown in FIG. 1;

3 is a block diagram of an ATM optical switch in accordance with the present invention;

4 is a diagram illustrating processing of an ATM cell in the ATM optical switch illustrated in FIG. 3.

Explanation of symbols on the main parts of the drawings

10: light exchange unit 20: control unit

30: optical / electrical signal converter 40-70: ATM cell processing device

80: optical signal multiplexer 90: tuner unit

I1 to I4: Input port O1 to O4: Output port

IPP1 to IPP4: Input port processing section BUF1 to BUF4: Buffer section

SEL1 to SEL4: Optical signal transmission unit Wi: Optical signal whose wavelength is i

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

The number of input and output ports of a general ATM optical switch is large, but in the embodiment of the present invention, four input and output ports are provided for convenience of description, and the number of ATM cells processed at one time is two.

ATM optical switch according to the present invention, as shown in Figure 3 attached to the ATM cell processing apparatus 40 to 70, the optical signal multiplexing unit 80 and the tuner unit 90. The ATM cell processing apparatus 40 to 70 converts an ATM cell applied to the input ports I1 to I4 in the state of an optical signal into an electrical signal and then outputs the output ports 01 to 04 stored in the header of the ATM cell. After storing in the buffer units BUF1 to BUF4 corresponding to the port to be detected and output, the supercell grouped with two ATM cells is loaded on the optical signal corresponding to the port to be output. The optical signal multiplexer 80 multiplexes and outputs a supercell applied to a specific optical signal from each ATM cell processing apparatus 40 to 70. The tuner unit 90 extracts only an optical signal corresponding to each output port 01 to 04 from the multiplexed optical signal applied from the optical signal multiplexing unit 80 and outputs the optical signal to the output ports 01 to 04.

On the other hand, the ATM cell processing apparatuses 40 to 70 include input port processing units IPP1 to IPP4, buffer units BUF1 to BUF4, and optical signal transfer units SEL1 to SEL4. The ATM cell processing apparatus 40 to 70 detects a port to be output from data stored in the header of the ATM cell after converting the ATM cell applied to the input ports I1 to I4 in the state of the optical signal into an electrical signal. Thereafter, ATM cells are output to the corresponding buffer units BUF1 to BUF4. Each of the buffer units BUF1 to BUF4 has buffers corresponding to the output ports 01 to 04, and stores ATM cells to be output to the respective output ports 01 to 04. FIG. The optical signal transmission units SEL1 to SEL4 bundle two ATM cells stored in each of the buffer units BUF1 to BUF4 into a single supercell, and output them on an optical signal corresponding to a port to be output.

Referring to the operation of the present invention configured as described above are as follows.

For example, as shown in FIG. 4, if the ATM cells having the output ports O2, O2, O4, O4, and O1 are input to the input port I1, the input port of the first ATM cell processing apparatus 40 The processing unit IPP1 converts the ATM cell inputted to the input port I1 into an electrical signal, analyzes the header information of the cell, detects the output ports 01 to 04, and then corresponds to the corresponding output ports 01 to 04. Since the input port of the input ATM cell is O2, O2, O4, O4, O1, two ATM cells are stored in the second buffer of the buffer unit BUF1, and two ATM cells are stored in the fourth buffer. One ATM cell is stored in the first buffer. The optical signal transmission unit SEL1 searches the fourth buffer in a round robin manner from the first buffer of the buffer unit BUF1, and when two or more buffers are filled, the output ports 01 to 04 which are bundled into two supercells and output. It is carried on the optical signal corresponding to the transmission. Therefore, the optical signal transmission unit SEL1 first searches for the first buffer, but since the first buffer is empty, the second buffer searches for the second buffer. In the second buffer, two ATM cells to be output to the output port O2 are stored. Therefore, two ATM cells are bundled into one supercell and the ATM cells are mounted on the optical signal W2 corresponding to the output port O2 and output to the optical signal multiplexer 80. The optical signal multiplexer 80 multiplexes an optical signal W2 applied from the first ATM cell processing unit 40 and an optical signal having a different wavelength applied from the remaining three ATM cell processing units 40 to 70. Output The multiplexed optical signal is applied to each output port (01 to 04). The tuner unit 90 of each output port (O1 to O4) is multiplexed and has a specific wavelength of light transmitted to its port in the applied optical signal. Extract only the signal. Therefore, since the second tuner 92 of the tuner unit 90 detects only the optical signal of W2, two ATM cells transmitted as the optical signal of W2 are exchanged at the output port O2. Subsequently, the optical signal transmission unit SEL1 of the first ATM cell processing apparatus 40 searches for the third buffer, but since there is no ATM cell in the third buffer, it searches for the fourth buffer. Since two ATM cells are stored in the fourth buffer, two ATM cells are bundled into one supercell, and the ATM cells are mounted on the optical signal W4 corresponding to the output port O4 and output to the optical signal multiplexer 80. The optical signal multiplexer 80 multiplexes and outputs an optical signal W4 applied from the first ATM cell processing unit 40 and an optical signal having a different wavelength applied from the remaining three ATM cell processing units 50 to 70. do. The multiplexed optical signal is applied to each output port (01 to 04). The tuner unit 90 of each output port extracts only the optical signal of a specific wavelength transmitted to its port from the multiplexed and applied optical signal. Since the fourth tuner 94 of the unit 90 detects only the optical signal of W4, two ATM cells transmitted with the optical signal of W4 are exchanged at the output port O4.

Therefore, by processing the supercell consisting of two ATM cells at once, the unit processing time corresponds to twice the arrival interval of one 53-byte ATM cell. On the other hand, the number of ATM cells constituting the supercell is appropriately adjusted according to the performance of the ATM exchanger to reduce the tuning burden of adjusting the wavelength at the optical signal transmitter or the wavelength of the optical signal to be received at the tuner. have.

As described above, the present invention stores an ATM cell in a buffer in an ATM optical switch, and processes a plurality of cells as one supercell when a predetermined time passes or when the buffer is full, thereby controlling wavelengths in an optical signal transmitter. It can reduce the tuning burden of adjusting the wavelength of the optical signal to be received by the tuner, simplify the expensive optical elements in the configuration of the optical exchanger, and transmit the optical signal quickly so that the throughput of the overall exchange can be increased. do.

Claims (2)

In the ATM optical exchanger, after converting an ATM cell applied to the input ports I1 to I4 in the state of an optical signal into an electrical signal, the output ports O1 to O4 are detected from the data stored in the header of the ATM cell. A plurality of ATM cell processing apparatuses 40 to 70 for later outputting supercells having a predetermined number of ATM cells having the same output port mounted on optical signals W1 to W4 having a wavelength corresponding to the output port; An optical signal multiplexing unit (80) for multiplexing and outputting optical signals (W1 to W4) applied from the respective ATM cell processing units (40 to 70); A tuner unit 90 which extracts an optical signal corresponding to each output port 01 to 04 from the multiplexed optical signal applied from the optical signal multiplexer 80 and outputs it to the corresponding output port 01 to 04. ATM optical exchanger comprising: a. 2. The ATM cell processing apparatus according to claim 1, further comprising: buffer units (BUF1 to BUF4) for storing ATM cells to be output with buffers corresponding to the respective output ports (01 to 04); The buffer unit corresponding to the port to be output after detecting the port to be output from the data stored in the header of the ATM cell after converting the ATM cell applied to the input port into an electrical signal in the state of the optical signals W1 to W4. Input port processing units IPP1 to IPP4 for outputting to BUF1 to BUF4; An optical signal that is output by placing the predetermined number of ATM cells stored in each of the buffer units BUF1 to BUF4 into one supercell and carrying the optical signals W1 to W4 having a wavelength corresponding to the port to be output. An ATM optical switch comprising a transmission unit (SEL1 to SEL4).