KR20110068745A - Module apparatus and method for controling multi lane using control signal of physical layer - Google Patents

Abstract

PURPOSE: A multi lane control module using a control signal of a physical layer and method thereof are provided to control the power of a lane to cope with a defect of the lane. CONSTITUTION: A multi lane control module using a control signal of a physical layer is applied to a fast Ethernet(100). The fast Ethernet comprises a first module(101) and a second module(111). The first module includes MAC(Media Access Control)(103), PCS(Physical Coding Sublayer)(105), and PMA(Physical Media Attachment)(107). The first module is matched with the second module physically or logically by a multi lane. The second module comprises a PMD(Physical Media Dependent)(113). The second module selectively includes PMA(115).

Description

Multi-lane control module device and method using control signal of physical layer {MODULE APPARATUS AND METHOD FOR CONTROLING MULTI LANE USING CONTROL SIGNAL OF PHYSICAL LAYER}

Embodiments of the present invention relate to a multi-lane control module apparatus and method using a control signal of a physical layer that can minimize power consumption by controlling power of a lane in which a problem occurs among multiple lanes.

The present invention is derived from the research conducted as part of the IT source technology development project of the Ministry of Knowledge Economy and the Ministry of Information and Communication Research and Development. [Task management number: 2008-F-017-02, Title: Development of 100Gbps Ethernet and optical transmission technology] .

As the number of devices connected to the network increases and a higher data rate is required, a new transmission technique capable of high-speed data transmission is needed. On the other hand, in the case of Ethernet devices, in order to overcome the speed limitation as the bandwidth increases, it is standardized to expand the bandwidth using multiple lanes. At this time, the Ethernet device can reduce the burden on the processing of the high-speed signal and the development of components by using multiple lanes, while vulnerable to hardware defects or errors because a plurality of components constitute multiple lanes. In particular, unlike the media access control (MAC) and the physical coding sublayer (PCS) composed of a single chip, physical media attachment (PMA) and PMD having a multi-lane structure are vulnerable to the above defects or errors.

The present invention has been made to solve the above problems, and when a problem occurs in the transmission lane of the counterpart module, by controlling the power of the reception lane connected to the transmission lane of the counterpart module or the transmission lane corresponding to the reception lane. The aim is to minimize power consumption.

The multi-lane control module apparatus using the control signal of the physical layer according to an embodiment of the present invention, when detecting a defect in the first transmission lane of the counterpart module, is physically connected to the first transmission lane, the first reception lane And a detector configured to generate a loss signal for the signal, and a controller configured to turn off the second transmission lane corresponding to the first reception lane according to the generation of the loss signal.

The multi-lane control module apparatus using a control signal of a physical layer according to another embodiment of the present invention includes a flag generator for generating a defect flag to a set value when a defect occurs in a first transmission lane, and the first generator. A loss signal for the second receive lane, physically connected to the second transmit lane, when detecting the off of the second transmit lane of the counterpart module corresponding to the first receive lane of the counterpart module physically connected to the transmit lane And a controller configured to turn off the first transmission lane corresponding to the second reception lane according to the generation of the loss signal.

In the multi-lane control method using a control signal of a physical layer according to an embodiment of the present invention, when detecting a defect in a first transmission lane of a counterpart module, the multi-lane control method may include a first reception lane physically connected to the first transmission lane. Generating a lossy signal for a signal; and turning off a second transmission lane corresponding to the first reception lane according to the generation of the lossy signal.

Multi-lane control method using a control signal of a physical layer according to another embodiment of the present invention, if a defect occurs in the first transmission lane, generating a defect flag to a set value, and the first transmission lane and Generating a loss signal for a second reception lane that is physically connected with the second transmission lane when detecting an off of the second transmission lane of the counterpart module that is physically coupled and corresponding to the first reception lane of the counterpart module. And turning off the first transmission lane corresponding to the second reception lane according to the generation of the lost signal.

According to an embodiment of the present invention, when a problem occurs in a transmission lane of a counterpart module, power consumption may be minimized by controlling a power of a reception lane connected to a transmission lane of a counterpart module or a transmission lane corresponding to the reception lane. have.

Therefore, by controlling the power of the lane according to the defect of the lane, it is easy to control the operation of each lane, it is possible to improve the stability of the device.

In addition, according to the embodiment of the present invention, since the control and communication in the upper layer (layer), unlike the conventional multi-lane control method for creating and managing a separate communication channel with the upper layer of the matching module matching, PMD Since the state of the lane is identified through the optical signal of, it is possible to solve the complexity of the separate communication channel creation and management.

1 is a diagram illustrating a configuration of Fast Ethernet to which a multi-lane control module apparatus using a control signal of a physical layer according to an embodiment of the present invention is applied.
2 is a diagram illustrating a configuration of a multi-lane control system using a control signal of a physical layer according to an embodiment of the present invention.
3 is a diagram illustrating a configuration of a multi-lane control system using a control signal of a physical layer according to another embodiment of the present invention.
4 is a diagram illustrating hardware of a CFP multi-source agreement (MSA) corresponding to a PMD for transmitting control information according to a sensed loss signal in a multi-lane control system using a control signal of a physical layer according to an embodiment of the present invention. It is a figure which shows an example about pin assignment.
5 is a flowchart illustrating a multi-lane control method using a control signal of a physical layer according to an embodiment of the present invention.
6 is a flowchart illustrating a multi-lane control method using a control signal of a physical layer according to another embodiment of the present invention.

Hereinafter, a multi-lane control module apparatus and method using a control signal of a physical layer according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a configuration of Fast Ethernet to which a multi-lane control module apparatus using a control signal of a physical layer according to an embodiment of the present invention is applied.

Referring to FIG. 1, a Fast Ethernet 100 to which a multi-lane control module apparatus using a control signal of a physical layer according to an embodiment of the present invention is applied includes a first module 101 and a second module 111.

The first module 101 includes a media access control (MAC) 103, a physical coding sublayer (PCS) 105, and a physical media attachment (PMA) 107, and is physically or logically multiplexed with the second module 111. Matching can be done through multi lanes.

The second module 111 may include a physical media dependent (PMD) 113 and may further include a PMA 115.

2 is a diagram illustrating a configuration of a multi-lane control system using a control signal of a physical layer according to an embodiment of the present invention.

2, the multiple lane control system 200 using the control signal of the physical layer according to an embodiment of the present invention includes a first multiple lane control module 201 and a second multiple lane control module 211. do.

The first multi lane control module 201 includes a first detector 203 and a first controller 205.

When the first detector 203 detects a fault with respect to the first transmission lane of the counterpart module, that is, the second multi-lane control module 211, the first reception unit 203 is physically connected to the first transmission lane. Generates a Loss of Signal for the lane. Here, the first detector 203 may be a reception (RX) element that controls the first reception lane.

In addition, even when the first detection unit 203 detects the off of the first transmission lane, the first detection unit 203 may generate a loss signal for the first reception lane.

The first controller 205 turns off the second transmission lane corresponding to the first reception lane according to the generation of the loss signal. Here, the first control unit 205 can turn off the second transmission lane by turning off the power of the transmission (TX) element controlling the second transmission lane.

In addition, the first controller 205 may turn off the first reception lane according to generation of a loss signal for the first reception lane.

The second multi lane control module 211 includes a second detector 213 and a second controller 215.

When the second detection unit 213 detects a defect of the second transmission lane of the counterpart module, that is, the first multi-lane control module 211, the second detection unit 213 may be connected to the second reception lane, which is physically connected to the second transmission lane. Generate a loss signal. Here, the second detector 213 may be a reception (RX) device that controls the second reception lane.

In addition, even when the second detection unit 213 detects the off of the second transmission lane, the second detection unit 213 may generate a loss signal for the second reception lane.

The second controller 215 turns off the first transmission lane corresponding to the second reception lane according to the generation of the loss signal. Here, the second control unit 215 may turn off the first transmission lane by turning off the power of the transmission (TX) element controlling the first transmission lane.

In addition, the second controller 215 may turn off the second reception lane according to generation of a loss signal for the second reception lane.

In a multiple lane control system using a control signal of a physical layer according to an embodiment of the present invention, when a defect occurs in a first transmission lane of a second multiple lane control module, a first multiple physically connected to the first transmission lane A first reception lane of a lane control module, a second transmission lane corresponding to the first reception lane, a second reception lane of a second multi-lane control module physically connected with the second transmission lane, and corresponding to the second reception lane By turning off at least one of the first transmission lanes, power consumption can be minimized.

3 is a diagram illustrating a configuration of a multi-lane control system using a control signal of a physical layer according to another embodiment of the present invention.

Referring to FIG. 3, the multiple lane control system 300 using the control signal of the physical layer according to another embodiment of the present invention includes a first multiple lane control module 301 and a second multiple lane control module 311. do.

The first multi lane control module 301 includes a first flag generator 303, a first detector 305, and a first controller 307.

The first flag generator 303 generates a fault flag with a set value when a defect occurs in the first transmission lane of the first multi-lane control module 301. For example, the first flag generator 303 may generate a defect flag set to '1'.

The first sensing unit 305 is a part of the second multi-lane control module 311 corresponding to the first receiving lane of the counterpart module, that is, the second multi-lane control module 311 which is physically connected to the first transmission lane. When detecting the off of the second transmission lane, a loss signal is generated for the second reception lane, which is physically connected to the second transmission lane.

In addition, even when the first detector 305 detects a defect in the second transmission lane of the second multi-lane control module 311, the first detector 305 may generate a loss signal for the second reception lane.

The first controller 307 turns off the first transmission lane corresponding to the second reception lane according to generation of a loss signal for the second reception lane.

In addition, the first controller 307 may control on or off of the second reception lane according to the value of the defect flag. That is, the first control unit 307 turns off the second reception lane when the defect flag is the set value, and maintains the second reception lane on when the defect flag is not the set value. You can. For example, the first control unit 307 turns off the second reception lane when the defect flag is '1', and turns on the second reception lane when the defect flag is not '1'. ) Can be maintained.

The second multi lane control module 311 includes a second flag generator 313, a second detector 315, and a second controller 317.

The second flag generator 313 generates a fault flag with a set value when a defect occurs in the second transmission lane of the second multi-lane control module 300. For example, like the first flag generator 303, the second flag generator 313 may generate a defect flag set to '1'.

The second detector 315 may be configured to include a first module of the first multi-lane control module 301 corresponding to the second reception lane of the counterpart module, that is, the first multi-lane control module 301, which is physically connected to the second transmission lane. When the first transmission lane is detected to be off, a loss signal is generated for the first reception lane, which is physically connected to the first transmission lane.

In addition, even when the second detector 315 detects a defect in the first transmission lane of the first multi-lane control module 301, the second detector 315 may generate a loss signal for the first reception lane.

The second controller 317 turns off the second transmission lane corresponding to the first reception lane according to generation of a loss signal for the first reception lane.

In addition, the second controller 317 may control on or off of the first reception lane according to the value of the defect flag. That is, the second control unit 317 turns off the first reception lane when the defect flag is the set value, and maintains the first reception lane on when the defect flag is not the set value. You can. For example, the second controller 317 turns off the first reception lane when the defect flag is '1', and turns on the first reception lane when the defect flag is not '1'. ) Can be maintained.

In a multiple lane control system using a control signal of a physical layer according to an embodiment of the present invention, when a defect occurs in a first transmission lane of a first multi-lane control module, a second multiple physically connected to the first transmission lane A second transmission lane corresponding to the first reception lane of the lane control module, a second reception lane of the first multi-lane control module physically connected with the second transmission lane, and a first transmission lane corresponding to the second reception lane The power consumption may be reduced while activating the first reception lane corresponding to the communication channel by turning off at least one and keeping the first reception lane of the second multi-lane control module in which the defect does not occur.

4 is a CFP (Centum Form-factor Pluggable) MSA (PMD) corresponding to a PMD for transmitting control information according to a sensed loss signal in a multi-lane control system using a control signal of a physical layer according to an embodiment of the present invention. FIG. 1 shows an example of hardware pin assignment of a multi-source agreement.

Referring to FIG. 4, the multi-lane control system may allocate distinguished information to each pin according to the number of lanes in which four defects occur.

In a multi-lane control system, when a control unit is implemented in a processor in the PMD, the control unit may easily collect information using a local bus or a general purpose input output (GPIO) provided by the processor, but the control unit exists in a higher processor. In this case, the control unit collects each piece of information through MDC / MDIO (Management Data Clock / Management Data Input Output). At this time, since the MDC / MDIO bus is a low speed serial bus, it is not suitable for a high speed Ethernet control method. Therefore, the controller may use a hardware pin of the PMD for lane control with a fast response speed. That is, the controller may acquire control information using reserved pins of the PMD or a combination of pins previously defined.

5 is a flowchart illustrating a multi-lane control method using a control signal of a physical layer according to an embodiment of the present invention.

Referring to FIG. 5, when a fault occurs with respect to a first transmission lane in a counterpart module, that is, the second multi-lane control module 211 (501), the first multi-lane control module 201 may generate the first multi-lane control module 201. A defect for the first transmission lane is detected through the first reception lane of the first multi-lane control module 201 physically connected to the first transmission lane (511).

The first multiple lane control module 201 generates a loss of signal for the first reception lane of the first multiple lane control module 201 (512), and the first multiple lane corresponding to the first reception lane. The second transmission lane of the lane control module 201 is turned off (513). In operation 514, the first multi-lane control module 201 may turn off the first reception lane according to generation of a loss signal for the first reception lane.

The second multi lane control module 211 is configured to be physically connected to the second transmission lane when the second transmission lane of the first multi lane control module 201 is turned off. Through the two reception lanes, detecting the off of the second transmission lane (502).

The second multi lane control module 211 generates a loss signal for the second reception lane of the second multi lane control module 211 (503), and the second multi lane control module 211 corresponding to the second reception lane. The first transmission lane () is turned off (504). In addition, the second multiple lane control module 211 may turn off the second reception lane according to generation of a loss signal for the second reception lane (505).

Multiple lane control method using a control signal of the physical layer according to an embodiment of the present invention The multiple lane control method has been described as an example in which a fault occurs in the first transmission lane of the second multi-lane control module. The present invention can be controlled similarly to the above method even when a fault occurs in the second transmission lane of the first multi-lane control module.

6 is a flowchart illustrating a multi-lane control method using a control signal of a physical layer according to another embodiment of the present invention.

Referring to FIG. 6, the first multi-lane control module 301 generates a fault flag with a set value when a defect occurs in the first transmission lane of the first multi-lane control module 301. (601). For example, the first multi lane control module 301 may generate a defect flag set to '1'.

The second multi-lane control module 311 is physically connected to the first transmission lane when a fault occurs for the first transmission lane in the counterpart module, that is, the first multi-lane control module 301. 2, a defect for the first transmission lane is detected through the first reception lane of the multiple lane control module 311 (611).

The second multiple lane control module 311 generates a loss of signal for the first reception lane of the second multiple lane control module 311 (612), and the second multiple lane corresponding to the first reception lane. The second transmission lane of the lane control module 311 is turned off (613). In addition, when the flag is 1, the second multi-lane control module 311 may turn off the first reception lane according to generation of a loss signal for the first reception lane (614). As a result, the second multi-lane control module 311 turns on the first reception lane because the flag is not 1 as the defect on the second transmission lane of the second multi-lane control module 311 does not occur. It can be kept on.

The first multi-lane control module 301 may be configured to be physically connected to the second transmission lane when the second transmission lane of the second multi-lane control module 311 is turned off. Through the two reception lanes, detecting the off of the second transmission lane (602).

The first multi-lane control module 301 generates a loss signal for the second reception lane of the first multi-lane control module 301 (603), and the first multi-lane control module 301 corresponding to the second reception lane. Turn off the first transmission lane (604). In addition, when the flag is 1, the first multi-lane control module 301 may turn off the second reception lane according to generation of a loss signal for the second reception lane (605). As a result, the first multi-lane control module 301 may turn off the second reception lane because a defect occurs in the first transmission lane of the first multi-lane control module 301 and the flag is 1.

The multi-lane control method using the control signal of the physical layer according to an embodiment of the present invention may be implemented in the form of program instructions that can be executed by various computer means and recorded in a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and magnetic disks, such as floppy disks. Magneto-optical media, and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

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 embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

200: multi-lane control system using a control signal of the physical layer
201: first multi lane control module
203: first detection unit
205: first control unit
211: second multi-lane control module
213: second detector
215: second control unit

Claims (8)

A detector configured to generate a loss signal for a first reception lane physically connected to the first transmission lane when detecting a defect in a first transmission lane of a counterpart module; And
A controller configured to turn off a second transmission lane corresponding to the first reception lane according to generation of the loss signal
Multiple lane control module device using a control signal of a physical layer comprising a. The method of claim 1,
The detection unit,
And detecting a loss of the first transmission lane of the counterpart module, generating a loss signal for the first reception lane. The method of claim 1,
The control unit,
And turning off the first reception lane according to the loss signal generation. A flag generator configured to generate a defect flag to a set value when a defect occurs in the first transmission lane;
When detecting the off of the second transmission lane of the counterpart module corresponding to the first reception lane of the counterpart module physically connected to the first transmission lane, the second reception lane is physically connected to the second transmission lane. A detector for generating a loss signal for the signal; And
A controller configured to turn off the first transmission lane corresponding to the second reception lane according to generation of the loss signal
Multiple lane control module device using a control signal of a physical layer comprising a. The method of claim 4, wherein
The detection unit,
And detecting a defect in the second transmission lane of the counterpart module, generating a loss signal for the second reception lane. The method of claim 4, wherein
The control unit,
When the defect flag is the set value, the second reception lane is turned off, and when the defect flag is not the set value, the control layer of the physical layer is used to maintain the second reception lane on. Multi lane control module device. Generating a loss signal for the first reception lane, physically connected with the first transmission lane, upon detecting a defect in the first transmission lane of the counterpart module; And
Turning off a second transmission lane corresponding to the first reception lane according to generation of the loss signal;
Multiple lane control method using a control signal of a physical layer comprising a. Generating a defect flag with a set value when a defect occurs in the first transmission lane;
When detecting the off of the second transmission lane of the counterpart module corresponding to the first reception lane of the counterpart module physically connected to the first transmission lane, the second reception lane is physically connected to the second transmission lane. Generating a loss signal for the signal; And
Turning off the first transmission lane corresponding to the second reception lane according to the generation of the loss signal;
Multiple lane control method using a control signal of a physical layer comprising a.

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