KR100241882B1 - An apparatus and method for derecting status signal in the system with dual module - Google Patents

Abstract

The present invention relates to an apparatus for recognizing a state signal according to an event occurrence in a redundant module system. In particular, each module in a redundant operation of a redundant module system having a redundant processor and a functional module used as a switching module of the processor. An apparatus for accurately recognizing a state signal of. The present invention is to perform the redundancy according to the application of the status signal according to the occurrence of the event, and at least one processor module, the same number as the processor module and the switching is performed according to the redundancy, the applied state An apparatus for recognizing a state signal of a redundancy module system having a function module for determining switching according to redundancy as a result of impedance detection of a signal, comprising: generating an event according to initiation of a redundancy operation and generating the event by the processor modules and function modules An event generator for outputting a corresponding state signal of the event, an impedance between the state signal and the paths of the processors, and an impedance between the state signal and the function module path are determined to be resistance values satisfying Equation 1 below. Detection result of the corresponding impedance according to the specified resistance value Standing parallel resistance section for supplying a state signal according to the switching of the functional module is characterized by made of an (R1, R2).

Where Vcc; Applied voltage

Vs; Status signal detection reference value

Accordingly, the apparatus and method for recognizing the state signal of each module in the redundant system enables the module state to be generated accurately and can be recognized. In addition, when an event occurs in the active module in the communication system operating in the active / standby state, the standby module accurately recognizes the status signal of the active module so that the active module can continue the service without disconnecting the service.

Description

An apparatus and method for derecting status signal in the system with dual module

The present invention relates to an apparatus for recognizing a state signal according to an event occurrence in a redundant module system. In particular, each module in a redundant operation of a redundant module system having a redundant processor and a functional module used as a switching module of the processor. An apparatus for accurately recognizing a state signal of.

In general, a communication system uses a redundant system using two modules for the purpose of survivability and reliability. That is, one module is an active state module that currently provides a communication service, and the other module is continuously authorized by the active module when the communication service cannot be continuously provided due to a failure or other reason of the active module. Standby module that provides communication services. The internal configuration of the above-described redundancy module used in the conventional communication system is as follows.

First, a main controller (CPU) and a memory in charge of all the control are provided, and have an input / output device and an interrupt controller composed of hardware for informing the main controller of the counterpart's status in real time, and various hands between each redundant module. It has a handshake control unit for controlling the shake signal.

In addition, a redundancy operation for a redundancy system composed of an active state redundancy module and a standby state redundancy module will be briefly described below. When an unexpected failure occurs in the active state redundancy module, the handshake state in the active state redundancy module is notified to the handshake control unit of the standby state redundancy module. The handshake control unit of the standby state redundancy module receiving the handshake signal detects the fact that a failure has occurred, and provides a condition for the interrupt control unit to generate an interrupt as a result of the detection. The interrupt controller then issues an interrupt to the main controller to indicate that the active state redundancy module has failed. The standby state redundancy module analyzes what kind of disability is provided based on the information provided by the handshake control unit in response to the interrupt from the interrupt control unit. Decide Through this operation, the active state redundancy module is switched from the active state to the inactive state, and the redundancy module in the inactive state is transferred to the active state.

In performing an operation as described above, in a redundant system, in order to recognize a status signal of each module, a pull-up is maintained by directly connecting a state signal or attaching a register of a constant value to the directly connected signal.

In the case of the STARACER system to which the present invention is applied-The STARACER is a representative example of a communication system manufactured and sold by the present application, which also has a conventional redundant system configuration. The STARACER system is used as ATM switching equipment. In the same manner, the signal received from the STARACER Processor Unit (SPU), the STARACER Interface Unit (SIU), and the STARACER Switching Unit (SSU) is received and transmitted to the network management system or the status is displayed through a monitor. If both the SPU active module and the standby module are mounted, the SPU is well aware of the power failure signal even if one of the SSU active module and the standby module has a power failure. However, the power failure signal is output from each board's rare board and must be independent of the front signal. However, the SSU front has a self power fail that sends its own power failure to the other side. At this time, if the right or left side SSU fails, the power supply itself is grounded and grounded. On the other side, the front side SSU front pulls up a 1 kΩ resistor to the remote power failure signal.

The state is described first, when the SPU fronts are all in the ON state, the 2.55 kΩ is pulled up because 5.1 kΩ resistors are connected in parallel to the SPU. At this time, 1kΩ is pulled up in the SSU. When one of the SSUs fails, the voltage applied to 1kΩ in the remote power failure signal to the other side is 1.4 volts, and even if the power supply itself is broken, The power failure signal is recognized as a high state.

Next, when only one SPU front is in the ON state, a resistance of 5.1 kΩ is pulled up in the SPU. At this time, 1 kΩ is pulled up in the SSU. When the voltage of 1 kΩ is 0.82 volts, and the power failure itself occurs, the voltage of the power failure signal of the other side becomes about the threshold voltage and is regarded as low state.

As a result, due to the phenomenon caused by the operation as described above, in a conventional redundant system, there is a problem of malfunction that can recognize the counterpart SSU as a power failure, which causes the voltage across the SPU and the registers in the SSU to be high. There is a problem of operational inconvenience in that the register must be changed to be recognized as a state.

In summary, an apparatus for accurately recognizing a status signal of each module in a redundant operation of a redundant module system having a redundant processor and a function module used as a switching module of the processor is required. Although the impedance detection result of the applied state signal can be made appropriately, such a state signal recognition device has not been implemented in the related art.

Accordingly, the present invention has been devised to solve the above-mentioned problems, and accurately recognizes the status signal of each module in the redundant module system that can recognize whether the status of the redundant module is high or low in each processor module. An object of the present invention is to provide a device.

In another aspect, an object of the present invention is to implement an apparatus for accurately recognizing a state signal of each module in a duplex operation of a duplex module system having a duplexed processor and a functional module used as a switching module of the processor. It's in the ship.

1 is an internal configuration diagram of a redundancy system to which the present invention is applied

2 is a view showing a state signal detection circuit in a state signal recognition apparatus according to a preferred embodiment of the present invention.

An apparatus for recognizing a state signal in a redundant module system according to the present invention for achieving the above object includes: a processor module configured to perform redundancy according to an application of a state signal according to an occurrence of an event; An apparatus for recognizing a state signal of a redundant module system, comprising: a function module configured to perform the switching according to the redundancy and determine the switching according to the redundancy as a result of the impedance detection of the applied state signal. An event generator for generating an event according to the start and outputting a corresponding state signal of the generated event to the processor modules and function modules, an impedance between the state signal and the paths of the processors, the state signal, and the function Impedance between the module paths It is characterized by consisting of parallel resistors (R1, R2) is determined to satisfy the resistance value, and supplies a status signal according to the switching of the functional module as a result of the detection of the impedance according to the predetermined resistance value.

Where Vcc; Applied voltage

Vs; Status signal detection reference value

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. 1 is an internal configuration diagram of a redundancy system to which the present invention is applied.

Referring to this, processor modules # 1 (100) and # 2 (110) are parts in which management and application software of a system operate in a STARACER system to which the present invention is applied. The function modules # 1 (200) and # 2 (210) have a function of switching an ATM path to a switching module having a redundancy function. The processor modules # 1 (100) and # 2 (110) have a redundancy function, one of which is active, and the other of which is standby. Therefore, the part that can detect the generated event will be the processor unit that is active in the processor module # 1 (100) and # 2 (110), the processor unit operating in standby is the transfer of the event signal But not detected. In other words, the generated event is delivered to and detected by the processor unit that is active.

An operation of the redundant system having the above-described configuration will be described below as an example, and the processor module # 1 100 may be active and the processor module # 2 110 may operate in a standby mode. In this case, when an event occurs from the event 1 (300) operating as a rear of the function module # 1 (200), the event occurs in the function module # 1 (200) in the processor module # 1 (100). In order to make it correctly recognize that the DID has been generated, the following conditions should be set in order not to recognize that the event has occurred in the function module # 2 (100). The voltage values in the following are values applied in the STARACER system commercially manufactured by the present applicant, and variations thereof may be different in each of the applied systems of the present invention.

First, under normal conditions, the voltage across R2 should be R2> 0.8V, i.e., when the state of the event detector goes high (more than 0.8V), it is normal and when the state is low (below 0.8V), an event has occurred. . That is, when the voltage of the signal detection point in each module is lower than a threshold voltage of 0.8 volts, it is recognized as a low state, and when it is high, it is recognized as a high state. When the event occurs by the resistance values R1 and R2, the event is recognized that the event occurs even in the states of the remote modules of the function modules # 1 (200) and # 2 (210). The state of the remote module must not be made aware that an event has occurred.

For example, a 5.1 kΩ resistor is connected in parallel to R1, so it is pulled up to 2.55 kΩ. At this time, if 1kΩ is pulled up in R2, the voltage applied to one of the modules with R2 is determined by Equation 3 below.

In this case, even if an event occurs, the event occurrence is accurately recognized even in the states of the remote modules of the function modules # 1 (200) and # 2 (210).

However, there may be a case where there is only one module connected to R1. In this case, when an event occurs, the voltage applied to R2 is returned as shown in Equation 4 below.

In this case, even the state of the remote module of the function module # 1 (200), # 2 (210) is incorrectly recognized as an event occurred. That is, the occurrence of the event is recognized based on 0.8V. In this case, the result is 0.82V. Therefore, the result cannot be clearly recognized. Such a result may be obtained.

In addition, the signal detection unit voltage levels of the processor modules # 1 and # 2 constituted by the redundant module are connected in parallel to each other so that the total register value becomes R1 / 2. In this case, the voltage applied to R2 where an event occurs is represented by Equation 5 below. Becomes

As a result, the result value of Equation 5 should be equal to Equation 6 below to transmit the state of only the module in which the event occurs without affecting the state of the remote module of the function modules # 1 (200) and # 2 (210). It will be possible.

Summarizing the above-described implementation of the present invention, first, the redundancy operation can be started according to the occurrence of an event. If the event is an event related to a power off, any one of the modules may be powered off. Then, the impedance role of the resistor (R1 or R2) provided in the off module disappears, so that it may not be correctly lean to each module of the status signal generated from the event generator (300, 310). As shown in the figure, if all four modules are generated when an event that may be in a power-on state occurs, it does not matter. However, when the power is turned off only for the function module # 1 (200), the function module # This is because 2 210 has a value similar to that of Equation 4, so that the state signal may not be correctly recognized.

After all, the implementation of the present invention is to adjust the appropriate resistance value (R1, R2) so that the status signal output from the event generating unit (300, 310) can be accurately recognized in the respective modules.

As described above, the apparatus for recognizing the state signal of each module in the redundancy system according to the present invention allows the module to accurately generate and recognize the state. In addition, when an event occurs in an active module in a communication system operating in an active / standby state, the standby module accurately recognizes a status signal of the active module so that the active module can continue service without disconnecting the service.

Claims (1)

Redundancy according to the application of the status signal according to the event occurrence and at least one processor module, the same number as the processor module and the switching is performed according to the redundancy, the impedance detection result of the applied state signal An apparatus for recognizing a state signal of a redundancy module system having a function module for determining switching according to redundancy, An event generator for generating an event according to a duplication operation and outputting a corresponding state signal of the generated event to the processor modules and function modules; The impedance between the state signal and the paths of the processors and the impedance between the state signal and the function module path are determined to be resistance values satisfying Equation 7 below, and the function module is detected as a result of detection of the corresponding impedance according to the determined resistance value. Status signal recognition device, characterized in that consisting of parallel resistors (R1, R2) for supplying a status signal according to the switching of

Where Vcc; Applied voltage Vs; Detection reference value of status signal

Images