KR19980026066A - How to detect system failure - Google Patents

Abstract

The present invention relates to a system failure detection method. The present invention includes the steps of outputting a memory code to the IIC bus, checking the IIC bus control signal, initializing an error counter if the IIC bus control signal is normal, and increasing the error code by '1' if the IIC bus control signal is abnormal. And determining whether the error counter is greater than 5, and outputting the memory code to the IIC bus if the error counter is greater than 5, and if the error counter is greater than 5, outputting the memory code back to the IIC bus. Can be detected.

Description

How to detect system failure

The present invention relates to a system failure checking method, and more particularly, to a failure checking method of a system for exchanging information using IIC.

With the development of semiconductor chips, the use of household products is increasing. Color television and video tape recorders (VTRs), for example, are becoming a necessity in the home. If a failure occurs in such a system, the parts to be repaired vary depending on the failure phenomenon and situation. In order to repair the fault, the repairman may find the fault based on his or her own experience or check the service manual for the fault. In this way, if you use your experience or service manual to find the fault, it is very difficult to find the fault. Furthermore, in the event of a failure that does not include your own experience or the service manual, you will spend a lot of time and money finding the site of failure.

As described above, when a failure occurs in the system in the related art, it is difficult to misjudge or find a failure site through the user's experience or service manual, which may cause a lot of time and money.

Therefore, the technical problem to be achieved by the present invention is to provide a system failure detection method that can quickly find the exact failure site.

1 is a block diagram of a color television.

2 is a flow chart for checking the EEPROM of FIG.

3 is a flow chart for checking the tuner of FIG.

4 is a flowchart for checking the chroma of FIG.

FIG. 5 is a flowchart for inspecting the sound unit of FIG. 1. FIG.

In order to achieve the above object, the present invention provides a method of outputting a memory code to an IIC bus, checking an IIC bus control signal, and initializing an error counter if the IIC bus control signal is normal, and if the IIC bus control signal is abnormal. Increasing the error code to '1', checking if the error counter is greater than 5, and if the error counter is greater than 5, indicates that the memory part is bad on the monitor, and outputting the memory code back to the IIC bus if less than 5. It provides a system failure detection method comprising.

In order to achieve the above object, the present invention also provides a step of outputting a tuner code to the IIC bus, checking the IIC bus control signal, and initializing an error counter if the IIC bus control signal is normal, and the IIC bus control signal is abnormal. , Increasing the error code by '1', checking if the error counter is greater than 5, and if the error counter is greater than 5, indicates that the tuner is bad on the monitor and outputting the tuner code back to the IIC bus if it is less than 5. It provides a system failure detection method comprising a.

In order to achieve the above object, the present invention also provides a method of outputting a chroma code to an IIC bus, checking an IIC bus control signal, and initializing an error counter if the IIC bus control signal is normal and causing an abnormal IIC bus control signal. In this case, increase the error code by '1', check if the error counter is greater than 5, and if the error counter is greater than 5, the monitor indicates that the chroma is bad and if it is less than 5, output the chroma code to the IIC bus again. It provides a system failure detection method comprising the step.

In order to achieve the above object, the present invention also provides a method of outputting an acoustic code to an IIC bus, checking an IIC bus control signal, and initializing an error counter if the IIC bus control signal is normal, If it is abnormal, increase the error code by '1', check if the error counter is greater than 5, and if the error counter is greater than 5, the sound is bad on the monitor, and if less than 5, return the sound code to the IIC bus. It provides a system failure detection method comprising the step of outputting.

According to the present invention, it is possible to quickly find the exact failure site.

Hereinafter, the present invention will be described in detail through examples.

1 is a schematic block diagram of a color television. The structure includes a tuner 13 for receiving a signal output from an external antenna 11, a chroma 15 for reproducing an image signal included in the signal by inputting the output of the tuner 13, and the chroma. An acoustic unit 17 for inputting the output of the tuner 13 and an output of the tuner 13, a speaker 19 for reproducing an audible sound with the output of the acoustic unit 17 as an input, and EEPROM 21 for storing data of tuner 13 and chroma 15, MICOM (Micro-computer) 23 for controlling the tuner 13, chroma 15 and EEPROM 21; And a CRT (25) connected to the chroma (15) and the microcomputer (23) to reproduce an image, a keypad (27) connected to the microcomputer (23), and an IR detector (29). Here, the tuner 13, chroma 15, sound unit 17, CRT 25, and EEPROM 21 are connected to the microcomputer 23 through the IIC bus 31, respectively, by the microcomputer 23. The operation is controlled.

In the block diagram shown in FIG. 1, a description will be given of a method of detecting a failure in the tuner 13, the chroma 15, the acoustic unit 17, and the EEPROM 21.

First, a case where a failure occurs in the EEPROM 21 will be described. The microcomputer 23 causes the EEPROM 21 to output the EEPROM code to the IIC bus 31 (step 101). The microcomputer 23 then checks the ALK signal, which is an IIC bus control signal (step 103). Here, ALK is a signal indicating whether or not communication is correctly performed between the devices connected to the IIC bus 31 on the IIC bus 31. The ALK is at a logic low level if the communication is being done correctly and at a logic high level if the communication is not being done correctly. If the ALK signal is at the logic low level, the error counter in the microcomputer 23 is initialized, and if the ALK signal is at the logic high level, the error code is incremented by one (step 105). Next, it is checked whether the error counter is greater than five. If the error counter is larger than 5, the CRT 25 indicates that the EEPROM 21 is defective. If the error counter is smaller than 5, the microcomputer 23 outputs the EEPROM code to the IIC bus 31 again. )

Second, the case where a failure occurs in the tuner 13 will be described. The microcomputer 23 causes the tuner 13 to output the tuner code to the IIC bus 31 (step 201). The microcomputer 23 then checks the ALK signal (step 203). It is a signal indicating whether or not communication is correctly performed between the devices connected to the IIC bus 31 on the bus 31. ALK is at a logic low level if the communication is correctly established and at a logic high level if the communication is not established correctly. If the ALK signal is at a logic low level, the error counter is initialized. If the ALK signal is at a logic high level, the error code is incremented by one (step 205). Next, it is checked whether the error counter is greater than five (step 207). If the error counter is greater than 5, the tuner 13 is bad in the CRT 25, and if less than 5, the microcomputer 23 outputs the tuner code to the IIC bus 31 again (step 209).

Third, a case where a failure occurs in the chroma 15 will be described. The microcomputer 23 causes the chroma 15 to output the chroma code to the IIC bus 31 (step 301). Then, the microcomputer 23 checks the ALK signal (step 303). It is a signal indicating whether or not communication is correctly performed between each element on the bus 31. ALK is at a logic low level if the communication is correctly established and at a logic high level if the communication is not established correctly. If the ALK signal is at a logic low level, the error counter in the microcomputer 23 is initialized. If the ALK signal is at a logic high level, the error code is incremented by one (step 305). Next, it is checked whether the error counter is greater than five. If the error counter is greater than 5, the chroma tube 25 is deemed bad and if it is less than 5, the microcomputer outputs the chroma code to the IIC bus (step 309).

Fourth, a case where a failure occurs in the acoustic unit 17 will be described. The microcomputer 23 causes the audio unit 103 to output the audio unit code to the IIC bus (step 401). The microcomputer 23 then checks the ALK signal. (Step 403) where ALK is the IIC bus. In (31), it is a signal indicating whether the communication between each element is correct or not. ALK is at a logic low level if the communication is correctly established and at a logic high level if the communication is not established correctly. If the ALK signal is at a logic low level, the error counter is initialized. If the ALK signal is at a logic high level, the error code is incremented by one (step 405). Next, it is checked whether the error counter is greater than five (step 407). If the error counter is greater than 5, the sound unit 17 is inferior to the CRT 25, and if less than 5, the microcomputer 23 outputs the sound unit code to the IIC bus 31 again (step 409).

The present invention is not limited to the above embodiments, and it is apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

As described above, according to the present invention, when one of the EEPROM 21, the tuner 13, the chroma 15, and the acoustic unit 17 connected to the IIC 31 using the microcomputer 23 has failed. The broken part can be displayed on the CRT 25 quickly and accurately.

Claims (4)

Outputting the memory code to the IIC bus; Identifying an IIC bus control signal; Initializing an error counter if the IIC bus control signal is normal and incrementing an error code '1' if the IIC bus control signal is abnormal; Checking if the error counter is greater than five; And And if the error counter is greater than 5, indicating that the memory portion is bad on the monitor, and if the error counter is smaller than 5, outputting the memory code back to the IIC bus. Outputting a tuner code to the IIC bus; Identifying an IIC bus control signal; Initializing an error counter if the IIC bus control signal is normal and incrementing an error code '1' if the IIC bus control signal is abnormal; Checking if the error counter is greater than five; And If the error counter is greater than 5, indicating that the tuner is bad on the monitor, and if it is less than 5, outputting the tuner code to the IIC bus again. Outputting the chroma code to the IIC bus; Identifying an IIC bus control signal; Initializing an error counter if the IIC bus control signal is normal and incrementing an error code '1' if the IIC bus control signal is abnormal; Checking if the error counter is greater than five; And If the error counter is greater than 5, indicating that the chroma is bad on the monitor and if less than 5, outputting the chroma code back to the IIC bus. Outputting an acoustic code to the IIC bus; Identifying an IIC bus control signal; Initializing an error counter if the IIC bus control signal is normal and incrementing an error code '1' if the IIC bus control signal is abnormal; Checking if the error counter is greater than five; And And if the error counter is greater than 5, indicating that the sound unit is defective on the monitor, and if less than 5, outputting the sound unit code to the IIC bus.