KR20020021855A - Stacking method in ethernet switch system - Google Patents

Abstract

PURPOSE: A stacking method in an Ethernet switch system is provided to mount a stacking board having a PLD(Programmable Logic Device) on the Ethernet switch system, and to implement a stacking system with a switch system where a master and slaves are not distinguished, so as to operate the stacking system regardless of power-on order as well as reduce the number of signal lines by transceiving a reset signal only between systems connected by the stacking system. CONSTITUTION: If power of a switch system(20) is on, a PLD(26) of a cascade board(24) installed in the switch system(20) is initialized. A CPU(22) controls the PLD(26) to generate a system reset signal. The initialized PLD(26) generates the system reset signal by a self built-in program, and transmits the system reset signal to the CPU(22). The switch system(20) is reset under the control of the CPU(22) receiving the system reset signal. When the power of the switch system(20) is on, the PLD(26) transmits the reset signal to a neighboring switch system. Then, a PLD of a cascade board installed in the neighboring switch system receives the reset signal, and generates a reset signal for resetting a self switch system. One switch system has two cascade boards. If one of the cascade boards receives a reset signal, the other cascade board transmits the reset signal to a neighboring cascade board.

Description

Stacking Method in Ethernet Switch System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stacking method in an Ethernet switch system. In particular, a stacking cascade board equipped with a programmable logic device (PLD) is installed in an Ethernet switch system. The present invention relates to a stacking method in an Ethernet switch system that enables a stacking system having no distinction of slaves.

Ethernet is the most widely used local area network (LAN) technology. Ethernet is equipped with many switch systems, and several switch systems are connected by stacking to increase the data transmission speed and to easily adjust the size of the switch system as needed.

The stacking system refers to a system in which a network system having a limited number of input / output ports is cascaded to expand the number of input / output ports without degrading the performance of each system.

Referring to FIG. 1, a method of stacking systems, which are divided into a conventional master system and a slave system, will be described in detail.

The individual systems constituting the stacking system are divided into a master system 10 and a slave system 14, 16, and 18, and the microcontroller 12 provided in the master system 10 includes each slave system 14, A stacking system is implemented by transmitting a signal to 16 and 18).

The micro controller 12 included in the master system 10 transmits a reset signal, an enable signal, and a configuration data signal to each slave system 14, 16, and 18. ), Each slave system 14, 16, 18 operates upon receiving the signal.

In order to operate the entire stacking system, the slave system 14, 16, 18 must receive a reset signal transmitted by the master system 10 to reset the slave systems 14, 16, and 18. 16 and 18 must wait for the reset signal to be transmitted from the master system 10 while the master system 10 is already powered on before powering on and transmitting the reset signal.

As described above, the master system 10 unilaterally transmits signals to the slave systems 14, 16, and 18, and the slave systems 14, 16, and 18 receive the signals, thereby operating the entire stacking system. The 10 and the slave systems 14, 16, and 18 have different structures in hardware, and software installed in each system for system operation is also different.

A method of implementing a stacking system as the master system and the slave system has the following problems.

Since each system constituting the stacking system is divided into a master and a slave and the slave system is operated by a signal transmitted by the master, the slave system must be powered on before the master system when the stacking system is started. This is cumbersome because the user must follow the power-on sequence in powering on the master system and the slave system. If additional hardware logic is attached to protect the power-on sequence, it is not economical because additional costs are incurred.

In addition, since the master system and the slave system are structurally different and the software installed for system operation is different, the master system and the slave system must be distinguished from the beginning in the system manufacturing process, and accordingly, a separate manufacturing process is required. Production costs are bound to rise.

And since the master system transmits three signals to one slave system, the master system must have three signal lines for each slave system. Accordingly, when there are several slave systems receiving signals from one master system, the signal system corresponding to three times the number of slave systems should be provided in the master system. This is very uneconomical because of the large number of signal lines required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and its object is to provide a stacking board equipped with a PLD in an Ethernet switch system to implement a stacking system in a system without distinguishing between a master and a slave, and thus, in a power-on sequence. Regardless of whether it is possible to operate the system, it is possible to make only one type of system without distinguishing between master and slave, and only one type of software mounted on the system is economical, so it is possible to reset signals between stacking systems. It is to reduce the number of signal lines by transmitting and receiving only.

1 is an Ethernet switch stacking system composed of an Ethernet switch system with a distinction between a master and a slave

2 is a diagram illustrating an Ethernet switch system according to the present invention.

3 is a diagram illustrating a method of configuring a stacking system using an Ethernet switch system according to the present invention.

* Description of the symbols for the main parts of the drawings *

30, 32, 34, 36: Ethernet switch system

30-1: Cascade Board with Ethernet Switch System A

32-1, 32-2: cascade board with Ethernet switch system B

34-1, 32-2: Cascade board with Ethernet switch system C

36-1, 36-2: Cascade Board with Ethernet Switch System D

A feature of the present invention for solving the above object is the process of generating a reset signal for resetting the system by the PLD provided in the last powered on Ethernet switch system; Transmitting the reset signal to a PLD provided in an adjacent switch system; Generating a reset signal for resetting the neighbor switch system by the PLD of the neighbor switch system receiving the reset signal; The PLD provided in the switch system includes a process of transmitting a reset signal to a PLD provided in an adjacent switch system.

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

The stacking system can be implemented as a switch system without distinction between a master and a slave by mounting a cascading board for stacking with a PLD according to the present invention to each switch system and cascading each switch system.

2 is a diagram illustrating a configuration of a switch system according to the present invention. When the switch system 20 is powered on, the PLD 26 of the cascade board 24 included in the switch system 20 is initialized, and the CPU 22 controls the PLD to generate a system reset signal. The initialized PLD 26 generates a system reset signal by a program embedded therein, and when the PLD 26 transmits a system reset signal to the CPU 22, the control of the CPU 22 receives the system reset signal. The switch system 20 is reset.

The PLD 26 not only generates a system reset when the switch system is powered on, but also transmits a reset signal to an adjacent switch system, and the PLD of the cascade board provided in the adjacent switch system is It also functions to receive the transmitted reset signal and generate a reset signal for resetting the switch system to which it belongs.

One switch system includes two cascade boards. When one cascade board receives a reset signal, the other cascade board sends a reset signal to another adjacent cascade board.

The process of transmitting the reset signal will be described with reference to FIG. 3.

In a stacking system consisting of four identical switch systems 30, 32, 34, and 36, the cascade boards provided in each switch system are connected to the cascade boards of adjacent switch systems, and the connection between the cascade boards is two It consists of a signal line, one of which is a signal line for transmitting a reset signal and the other of which is a signal line for receiving a reset signal.

When the switch system is powered on in the order A → B → C → D, each switch system 30, 32, 34, 36 generates its own reset signal when it is powered on to reset itself. It sends reset signal to other adjacent switch system. However, a system reset signal is generated last in the switch system D 36 that was last powered on, and a system reset signal generated in the system D 36 resets the switch system D 36 and at the same time, It is transmitted to the cascade board c ₂ (34-2) and the system C 34 is finally reset. When system C (34) is reset, cascade board c ₁ (34-1) sends a reset signal to cascade board b ₂ (32-2) of switch system B (32) to finally reset switch system B (32). And the cascade board b ₁ (32-1) of the switch system B 32 transmits the reset signal to the cascade board a ₁ (30-1) of the switch system A 30, the system A 30 finally receives the reset signal. It is reset.

When the switch system is powered on in the order of A->B->D-> C, the system reset signal generated in the system C 34 is generated since the system reset signal is generated last in the switch system C 34 that was last powered on. Resets switch system C (34), cascade board c ₁ (34-1) sends a reset signal to cascade board b ₂ (32-2) of switch system B (32), and cascade board c ₂ (34-2) ) Finally resets switch system B 32 and switch system D 36 by sending a reset signal to cascade board d ₁ 34-1 of switch system D 36. When the switch system B 32 is reset, the cascade board b ₁ (32-1) transmits a reset signal to the cascade board a ₁ (30-1) of the switch system A 30 so that the switch system A 30 finally receives the reset signal. It is reset.

The switch system that receives the reset signal from the adjacent switch system transmits the reset signal to another switch system again. The reset signal is not transmitted to the system that sent the reset signal to the other switch system. Send it. When the power is turned on in the order of A → B → D → C, the switch system C 34 transmits a reset signal to the switch system B 32 and the switch system D 36. The received switch system B 32 does not transmit a reset signal to the switch system C 34 that has transmitted a reset signal to itself, but transmits a reset signal only to the adjacent switch system A 30.

On the other hand, all the switch system constituting the stacking system does not require the enable signal transmission between the switch system because the internal TIMER of the PLD provided on the cascade board provided in each system generates its own enable signal. In addition, there is no distinction between the master and the slave, which also does not require the transmission of configuration data signals. Therefore, only reset signals are transmitted and received between each switch system.

As described above, the present invention implements the stacking system as a switch system without the distinction between the master and the slave by mounting a stacking board equipped with a PLD in the Ethernet switch system, it is possible to operate the system regardless of the power-on order It is economical and requires only one type of software to be mounted on the switch system, and only sends and receives the reset signal between the systems connected by stacking. Reduce the number of signal lines.

Claims (2)

Generating a reset signal for resetting the system by a PLD included in the last powered-on Ethernet switch system among a plurality of cascaded Ethernet switch systems; Transmitting the reset signal to a PLD provided in an adjacent switch system; Generating a reset signal for resetting a neighbor switch system to which the PLD of the neighbor switch system receiving the reset signal belongs; Stacking method in the Ethernet switch system, characterized in that the PLD provided in the switch system comprising the step of transmitting a reset signal to the PLD provided in the adjacent switch system. The method of claim 1, In the process of transmitting the reset signal to the PLD provided to the adjacent switch system, the PLD provided to the switch system, the PLD receiving the reset signal does not transmit the reset signal to the switch system that has transmitted the reset signal to itself A stacking method for an Ethernet switch system, characterized in that the reset signal is transmitted only to the switch system that has not transmitted the reset signal.