KR200183293Y1 - recovery device of abnormality occurrence for persnal computer - Google Patents

Abstract

The present invention relates to a personal computer abnormality recovery device, the PC 20 connected between the unmanned device unit 30 and the control computer 10 to control the signal desired time of each device in the unmanned device unit 30 From the CPU 26 and the output signal of the CPU 26, the program being set and executed therein so that the operation can be performed at the same time and the program can be responded to the sudden power failure or the program and system operation stop. A power relay 27 for temporarily shutting off power, an F-ROM 23 for storing a date and a number of malfunctions in response to a malfunction state of a program by an output signal of the CPU 26, and the CPU 26 of the CPU 26. The buzzer 24 which outputs a warning sound for a malfunction state by an output signal and the control computer 10 and the unmanned device unit 30 are mutually communicated by the output signal of the CPU 26 and are unmanned at the same time. By notifying the program malfunction status from the register, it records the cause and the date and time when the system was stopped. It checks the time when the system is stopped and checks the cause of abnormality and data reliability and system error. It has the effect of preventing the unstable system of the system operated for a long time by unmanned factories such as factory or outdoor mountain wallpaper unmanned facility, unmanned automatic data collection facility server, and ARS device.

Description

Recovery device of abnormality occurrence for persnal computer}

The present invention relates to a personal computer abnormality recovery device, more specifically, to search at regular intervals of time to check whether the signal of the system stop or program such as PC or server, and forced at system stop or program stop Output the forced stop signal so that it can be stopped and shut it down so that it can be reset softly. Record the cause and the stopped date time when the system stops and check the time when the system is stopped. The present invention relates to a personal computer abnormality recovery device capable of identifying a system error and preventing an unstable system such as a factory or an outdoor mountain wall unmanned facility that has a poor power supply or power condition.

A general computer is used for various word processors, illustrations, CAD, CAM, etc., graphics, games, and education, depending on the user's intention. The trend is to use e-mail to send or receive messages.

Such a conventional computer has an unexpected accident while the computer or server is running under an operating system such as Windows, DOS, NT, Relux, and Unix, such as static electricity, power failure noise program error, and so on. When the operation is stopped, the operating system is shut down and the file is closed, and the entire system is shut down and reset so that the program can be automatically executed.

The present invention is intended to solve such problems in the related art. The purpose of the present invention is to periodically check whether the system stops or stops a program such as a personal computer (hereinafter referred to as a PC) or a server. The system can be operated by recording the cause and the date of stop when the system is stopped by outputting the forced stop signal and shutting down by outputting the forced stop signal so that the system can be forcibly stopped when the system stops or stops the program. It is possible to check the cause of failure and data reliability and system error by checking the stopped time and operate unattended for long time by unmanned automatic data collection facility server, ARS device, etc. The instability of the system is to prevent the system from running.

1 is a configuration diagram to control the occurrence of abnormalities between external devices through a personal computer according to an embodiment of the present invention.

FIG. 2 is a partial block diagram of the personal computer shown in FIG.

3A, 3B, and 3C are flowcharts for controlling abnormalities between external devices through a personal computer according to an embodiment of the present invention.

Code descriptions for the main parts of the drawings

10; control computer 20; PC

23; f-rom 24; buzzer

25; communication unit 26; CPU

27; power relay 30; unmanned device unit

S1-S18; step

Hereinafter, the technical configuration of the present invention by the accompanying drawings in detail.

1 is a configuration diagram for controlling abnormalities between external devices through a personal computer according to an embodiment of the present invention, Figure 2 is a partial block diagram of the personal computer of Figure 1, Figure 3a, Figure 3B and 3C are flowcharts for controlling abnormalities between external devices through a personal computer according to an embodiment of the present invention.

The present invention relates to a device that can be restarted when the system operating state and the program state in the computer is inoperable state. Referring to FIG. 1 or FIG. 2, the input and output between external devices through internal programs A control computer 10 for transmitting a signal, an unmanned device unit 30 for transmitting and receiving an input / output signal between each linking device according to an output signal of the control computer 10, and an operation thereof; It is connected between the unmanned device unit 30 and the control computer 10 so that the user can operate each device in the unmanned device unit 30 at the desired time, and sudden power failure or program and system of each device Power from the CPU 26, which is set and executed inside the program, and the output signal of the CPU 26 so that a response to the operation stop can be made A power relay 27 for temporarily shutting off, an F-ROM 23 for storing a date and a number of malfunctions in response to a malfunction state of a program by an output signal of the CPU 26, and a thrust signal of the CPU 26 By means of the buzzer 24 for outputting a warning signal for a malfunction state and the control computer 10 and the unmanned device unit 30 by the output signal of the CPU 26, and at the same time PC 20 is made up of a communication unit 25 to inform the program malfunction state from the configuration.

As shown in FIGS. 3A, 3B, and 3C, the PC 20 according to the present invention may determine whether the date and the number of the abnormal signals generated during the execution of the operation before the operation are executed through the F-ROM 23 through the CPU ( After checking by 26, the CPU 26 can check the power state and operating system operation state from the signal input through the other input terminal, and when the program execution time is exceeded when executing the program, the CPU ( (26) notifies the F-ROM 23 of the time and the number of times of the abnormal operation caused by the program abnormality, and informs the user of the signal of the abnormality to the buzzer connected to the output terminal and communicates each unmanned device unit ( 30) and control computer 10, and control command signal is output and can be controlled so that each port connected to the end of the OS and the program being executed can be closed, and the OS And resetting the system so that the power reset and the program can be executed again after a predetermined delay time after the end of the program.

Referring to the effect of the present invention configured in this way in detail as follows.

The present invention relates to a device that can be restarted when the system operating state and program state in the computer is inoperable state, as described with reference to FIG.

The user checks whether the PC 20 is capable of data input and output with the control computer 10, and then connects to each device of the unmanned apparatus unit 30 to be controlled by the user to enable signal control.

Here, the PC 20 or the control computer 10 read the initial values for inputting and outputting mutual data, respectively. At this time, the PC 10 and the control computer 10 do not operate as an initial value '00' and search through the internal FRASH-ROM 23 to see if there is a previously set value. (S1).

On the other hand, if there is a previously set setting value in the internal F-ROM 23, the PC 20 reads the set setting value and waits for the program execution after delaying by the set initial time. In this case, the CPU 26 does not operate the program by setting the internal password and the set value to '0' so that the PC 20 does not operate (S2).

After that, the PC 20 checks the power supply state and the operating system operation state through the CPU 26 after delaying the initial set time, but if the operating system operation state is not checked, the PC 20 is first started. Since the signal is not input, the number of previously retries is checked to determine whether the set number of times is exceeded in order to stop the forced stop and the power after recording the reason for the stop if the set value is higher than the reference set value (S3).

When the PC 20 checks the operating system operating status, the CPU 26 inputs a signal for checking the operating status to the internal address address, becomes the first startup, and executes the second waiting time to check the operation of the internal address address again. Simultaneously with the addition of the signal, the check time is zeroed to operate (S4).

After the PC 20 performs the second waiting time, when the setting program start signal for checking the initial program is checked, if the setting program start signal is not confirmed, the initial setting is again performed to reconfirm the setting program start signal. After waiting for the delay time, the setting program start signal is checked (S5).

When the setting program start signal is confirmed, the PC 20 reinitializes the counter value to execute the initial program and sets it to zero (0) to remove the previously set time data, and then the initial program (screen save mode and Hard disk sleep mode, etc.) (S6).

The PC 20 running the program checks whether the program operation state is normal or abnormal at a predetermined time interval (S7).

In addition, the PC 20 executes a communication program through the CPU 26 when a communication signal is input from the outside so that communication can be performed between the PC 20 and the unmanned devices of the external unmanned device unit 30 ( S8).

When the communication program is executed, the CPU 26 of the PC 20 simultaneously or individually requests the input of an individual ID or password to confirm whether the data matches the data stored in the F-ROM 23.

In addition, the CPU 26 of the PC 20 searches for a command for a program that can communicate with each device by personal ID or password confirmation (S10).

The CPU 26 of the PC 20 retrieves the communication command of the program and executes the selected command so that the data input / output states can be continuously connected between the devices, and then waits until the next communication data is received or by the user. To stop the communication according to the intention (S11)

At this time, if the check signal check of the abnormal program operation state is not made, the PC 20 continuously checks whether the counter time is exceeded for the program execution through the CPU 26, and then the program is exceeded. And the OS state is checked (S12).

On the other hand, if the PC 20 exceeds the number of times for program execution, the CPU 26 receives the error code sent from the system motherboard or OS (OPERATE SYSTEM) program, which is the cause of the abnormal state, and causes the current date and time. After recording up to 10 or more types, according to a preset program, the CPU 26 outputs a warning message to the user through the buzzer as a warning sound, and the external control computer 10 or the unmanned device unit. A warning signal is outputted through a communication program connected to each unmanned device of the device 30 through a communication program. When the number of times of setting is not exceeded, the power supply is driven by driving the power relay 27 through the CPU 26. At the same time, the program progress state that is being executed can be stopped (S13).

In addition, the PC 20 outputs a signal for the end operation of the internal OS program and the initial execution program through the CPU 26 so that termination can be performed (S14), and the CPU 26 is connected to each port, that is, for control purposes. Each port file connected to the computer 10 and the unmanned device 30 is forcibly released from the connection state and executed to close the command (S15).

At this time, the PC 20 waits to execute the next control program after delaying a predetermined time after closing the open pod (S16), and the PC 20 automatically via the power relay 27 through the CPU 26. After the reset is executed, the entire system is executed again (S17).

In addition, the PC 20 checks the system reset state through the CPU so that the initial program can be executed (S18).

The present invention acting as described above is a forced stop signal so that it can be forcibly stopped when the system stops or stops by searching at regular intervals to check whether the system stops or stops a program such as a PC or a server. By shutting down the system, it can be reset softly after recording.The cause and the date of stopping the system are recorded to check the time when the system is not operating, so that abnormal causes and data reliability and system errors can be checked. It has the effect of preventing the unstable system of the system that is operated for a long time by unattended facilities such as factory, outdoor mountain wall unmanned facilities, unmanned automatic data collection facility server, ARS device, etc. in case of power failure.

Claims (2)

The control computer 10 allows the external devices to transmit the I / O signals to each other through an internal program, and the operation is performed by transmitting the I / O signals between the associated devices according to the output signal of the control computer 10. In the unmanned device unit 30 and the PC 20 connected between the unmanned device unit 30 and the control computer 10 for signal control, the PC 20 is an unmanned device unit 30. A CPU 26 in which a program is set and executed internally so that each device in the device can be operated at a desired time and a response to a sudden power failure or a program and system stoppage of each device can be achieved, and the CPU The power supply relay 27 for temporarily shutting off the power from the output signal of (26) and the date and the number of malfunctions are stored for the malfunction state of the program by the output signal of the CPU 26. The control computer 10 is controlled by the F-ROM 23, the buzzer 24 which outputs a warning signal sound for a malfunction state by the output signal of the CPU 26, and the output signal of the CPU 26. And an unmanned device unit 30 are mutually communicated with each other and composed of a communication unit 25 to notify the program malfunction status from the unmanned device unit 30 connected to the personal computer abnormality occurrence recovery device. The CPU 20 of claim 1, wherein the PC 20 checks whether the date and the number of the abnormality occurrence signal generated during the execution of the PC 20 before the operation are executed by the CPU 26 through the F-ROM 23. 26) enables the power state and the operating system operation state to be checked from the signal input through the other input terminal, and if the time for the program execution operation is exceeded when executing the program afterwards, the CPU 26 causes the current program error. In addition, the time and the number of times of abnormal operation are stored in the F-ROM 23, and the user is notified of the signal of the abnormality to the buzzer 24 connected to the output terminal, and the unmanned apparatus of each unmanned apparatus unit 30 as a communication signal. The control computer 10 can be notified and the control command signal can be outputted and controlled so that each port connected to the end of the OS and the program being executed can be closed. End became no longer occurs in the personal computer system, which is connected to run a reset to be the former principle set and re-run the program after a predetermined delay time recovery device.