JP2000196555A - Self-diagnostic system for multiplexer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To execute self-diagnosis for multiplex functions without interrupting transmission of other busy channels. SOLUTION: The self-diagnostic system is provided with a diagnostic data generating section 3 that outputs diagnostic data to a channel designated as a diagnostic channel, an expected value generating section 4 that generates a format multiplexed by a multiplexer section 2 on the basis of the diagnostic data as an expected value and an extract section 5 that extracts only the diagnostic data of a channel designated as the diagnostic channel on the basis of a channel identifier. The diagnostic data are compared with expected value data generated by the expected value generating section 4 and a diagnostic channel control section designates an extracted channel and a diagnostic channel on the basis of the channel busy information.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a self-diagnosis system for a multiplexing apparatus for generating time-division multiplexed data from input data.

[0002]

2. Description of the Related Art As a conventional method of diagnosing a multiplexing apparatus, there is a method disclosed in, for example, Japanese Patent Application Laid-Open No. 10-150425. This is because a test signal is transmitted to a predetermined path at a predetermined timing after the power is turned on and before the operation of the multiplexing apparatus, and the test signal is compared with the test signal obtained by turning the path back. The method includes detecting a failure in the route according to the following. In addition, the main feature is that the internal transmission path is released so that diagnostic data can be collected at the time of diagnosis so that all diagnoses can be performed before the operation of the multiplexer.

[0003]

However, in such a conventional method for diagnosing a multiplexing device, there is no problem in releasing the internal transmission line before the multiplexing device is operated, but the operation of the multiplexing device is not problematic. Even if it is desired to diagnose only a specific channel after the start, it is necessary to stop all operations, and there is a problem that transmission of the channel being used must be interrupted. Further, the diagnosis is performed as part of an initial check at the time of starting the multiplexing device, and a method of performing a diagnosis by stopping all operations during normal operation is adopted. However, there is an inconvenience that the operator needs to perform a command operation for starting diagnosis.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems, and can perform a self-diagnosis of a multiplex function without interrupting transmission of another used channel, and can always diagnose only an unused channel to start diagnosis. It is an object of the present invention to provide a multiplexing device self-diagnosis system that can input a diagnosis result during normal operation for each channel without performing an instruction operation, and can further facilitate maintenance such as replacement of a failed channel.

[0005]

To achieve the above object,
A self-diagnosis system for a multiplexing device according to the first aspect of the present invention includes: an input selection switch for switching and inputting any of input data of a plurality of channels and diagnostic data used for self-diagnosis to a multiplexing unit; A diagnostic data generating unit that generates diagnostic data and outputs the diagnostic data to a channel specified by a diagnostic channel; and a multiplexing unit that multiplexes the diagnostic data based on the diagnostic data generated by the diagnostic data generating unit. An expected value generation unit that generates a later format as an expected value, and an extraction unit that extracts only disconnection data of the channel specified by the diagnostic channel based on a channel identifier in multiplexed data output by the multiplexing unit. The comparator is provided with all bits of the diagnostic data extracted by the extraction unit and the expected value data generated by the expected value generation unit. And causing the diagnostic channel control unit to determine a diagnostic channel based on channel usage information from the man-machine interface, and to specify an extraction channel for the extracting unit and a diagnostic channel for the diagnostic data generating unit. It is like that.

The self-diagnosis system for a multiplexing device according to the present invention causes the expected value generation unit to generate an expected value of diagnostic data according to a format before being multiplexed in the multiplexing unit. The comparison unit is configured to compare the known diagnosis source data used for the self-diagnosis with the expected value data generated by the expected value generation unit for all bits.

In a third aspect of the present invention, there is provided a self-diagnosis system for a multiplexing apparatus, wherein the extracting unit is configured to extract diagnostic data having a predetermined time-division multiplex format.

According to a fourth aspect of the present invention, there is provided a self-diagnosis system for a multiplexing apparatus, wherein the multiplexing unit includes: an input processing unit for synchronizing input data or diagnostic data for each channel with internal processing timing; A multiplexed channel switch for switching and outputting data output from the input processing unit so as to perform time-division multiplexing output, and adding the channel identifier to data of each channel switched and output by the multiplexed channel switch; And an output processing unit for outputting as multiplexed data.

According to a fifth aspect of the present invention, there is provided the self-diagnosis system for a multiplexing apparatus, wherein the designation of the diagnostic channel by the diagnostic channel control unit is performed only for an unused channel to which no external data is input. It is like that.

The self-diagnosis system for a multiplexing apparatus according to the invention of claim 6 checks whether or not the channel use information has been changed from the man-machine interface every time the diagnosis of one channel is completed. In this case, the changed channel use information is transmitted to switch the input selection switch.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. The multiplexed data output by the multiplexing device is multiplexed by a method of switching and outputting input data from a plurality of channels at certain time intervals, and an identifier for identifying the input channel is added to each channel data. ing. Further, in such multiplexed data, since input (transmission) data before multiplexing and output (reception) data separated based on a channel identifier are transmitted transparently, transmission Although it is physically multiplexed on one channel in the middle of, it looks as if there are virtually a plurality of channels (virtual channels). In the present invention, the self-diagnosis of the multiplexing device is performed for each virtual channel by utilizing the property of the virtual channel, so that data transmission on a channel to which data is externally input (used channel) is not interrupted. Diagnosis of other channels to which data is not input (unused channels) is always performed.

FIG. 1 is a block diagram showing a self-diagnosis system for a multiplexer according to the present invention. In FIG. 1, reference numeral 1 denotes a channel (ch) 1 to a channel (c) input to the multiplexer.
h) An input selection switch for selectively transmitting any of the n input data I1 to In and the diagnostic data used in the self-diagnosis to the multiplexing unit 2, which is composed of a plurality of selectors. If the side is selected, the diagnostic data
When the side is selected, the input data is transmitted to the multiplexing unit. That is, for a channel to which data is input from the outside (hereinafter referred to as a used channel), the selector selects the b side, while for a channel to which no data is input from the outside (hereinafter referred to as an unused channel),
The selector selects the a side. This channel /
Switching of unused channels is controlled according to channel usage information from the control unit 7.

A multiplexing unit 2 realizes a multiplexing function. The input processing units 20-1 to 20-2
-N, a multiplexed channel control unit 21, a multiplexed channel switch 22, and an output processing unit 23. Among these, the input processing units 20-1 to 20-n function as buffers provided for each input channel, and the input data or diagnostic data is completely synchronized with the internal processing timing. Further, the multiplexing channel control unit 21 generates a channel switching instruction when the data of the channels 1 to n buffered by the input processing units 20-1 to 20-n is output to the output control unit 23 in a time division manner. . The switch 22 performs switch switching according to the channel switching instruction generated by the multiplexing channel control unit 21 and transmits the time-division multiplexed data to the output processing unit 23 in the switching order.

On the other hand, the output processing section 23 adds an identifier (channel identifier) for identifying each input channel to each of the time-division multiplexed channel data to generate multiplexed data M. Reference numeral 3 denotes a diagnostic data generator which generates known data used for self-diagnosis, and starts outputting diagnostic data to a channel designated by the diagnostic channel controller 8 as a diagnostic channel. The diagnosis channel is specified only for the “unused channel”, and one diagnosis selects one channel. That is, the diagnostic channel is selected from the “unused channels” while circulating one channel at a time.

Further, reference numeral 4 denotes an expected value generating section for generating a format multiplexed by the multiplexing section as an expected value based on the diagnostic data generated by the diagnostic data generating section 3; An extracting unit that extracts only data of a channel designated as a diagnostic channel based on a channel identifier in M, 6 is expected to be data extracted by the extracting unit 5 (diagnostic data formatted as multiplexed data). A comparison unit that performs comparison with the expected value data generated by the value generation unit 4, and functions to transmit the comparison result to the control unit 7.

The control unit 7 controls the entire diagnostic function of the multiplexing device, and transmits channel use information from the man-machine interface 9 to the input selection switch 1 and the diagnostic channel control unit 8. In addition, the comparison result for each diagnosis channel from the comparison unit 6 is put together and output to the man-machine interface 9 as the current diagnosis result of the multiplexer. The diagnostic channel control unit 8 determines a diagnostic channel based on the channel usage information from the control unit 7,
The extraction unit 5 is instructed on an extraction channel, and the diagnostic data generation unit 3 is instructed to output data to a channel for performing diagnosis. The man-machine interface 9 is an interface for interfacing with an operator of the multiplexing apparatus. The man-machine interface 9 transmits channel use information from the operator to the controller 7, receives a diagnosis result from the controller 7, and notifies the operator. I do.

Next, the operation will be described in detail with reference to FIGS. Here, FIG. 2 is a flowchart of the self-diagnosis processing of the multiplexing apparatus, and FIG. 3 is an explanatory diagram of the operation of the extracting unit for extracting diagnostic data from the multiplexed data M output from the multiplexing apparatus. First, in the multiplexing apparatus, input data of “used channel” among ch1 to chn is input to the multiplexing unit,
A process for outputting the multiplexed data M is performed. On the other hand, for the “unused channel”, the diagnostic data from the diagnostic data generator 3 is periodically inputted, and the self-diagnosis processing is performed. These “used channels” and “unused channels” are set based on channel usage information from the operator.

The control unit 7 confirms whether or not there is a change in the channel use information from the operator each time the diagnosis of one channel is completed (step 100). The changed channel use information is transmitted to. Based on this, the input selection switch 1 is instructed to switch the switch to the “b” side for “used channel” and to switch the switch to “a” for “used channel” (step 101). If there is no change in step 100, the process of step 101 is not performed.

The channels designated as "unused channels" in the channel usage information from the operator are diagnosed one by one sequentially. The channel use information is also transmitted to the diagnostic channel control unit 8 to determine which of the “unused channels” is to be diagnosed (Step 102). Here, when the diagnostic channel is determined to be the channel k, the diagnostic channel control unit 8 first sets “extracted channel = diagnostic channel” in the extraction unit 5 so that only the data of the channel k can be extracted from the multiplexed data M. (Step 103). When the extraction channel is set to the channel k, the extraction unit 5 can extract only the diagnostic data corresponding to the channel k based on the channel identifier in the multiplexed data M. This establishes all diagnostic paths for diagnostic data input and extracted data output.

Next, the diagnostic channel controller 8 instructs the diagnostic data generator 3 to generate diagnostic data and output the diagnostic data to the diagnostic channel (step 104). The diagnostic data generator 3 generates known data used for self-diagnosis,
Data output to the channel k port of the input selection switch 1 is started. The diagnostic data input from the port of the channel k is multiplexed by the multiplexing unit 2 into another “used channel”.
Is multiplexed with the input data to generate multiplexed data M. In the extraction unit 5, only the data of the channel k is extracted based on the channel identifier of the channel k and transmitted to the comparison unit 6. .

The diagnostic data generated and output by the diagnostic data generator 3 is directly converted into an expected format after multiplexing by the expected value generator 4 and transmitted to the comparator 6 as well. In the comparison unit 6, the multiplexed data M
Is compared with the expected value data generated from the diagnostic data (step 105).
The comparison result is notified to the control unit 7 (step 106), and the result is transmitted as a diagnosis result to the man-machine interface 9.
Is notified to the operator (step 107). After the diagnosis of one channel is completed, the process proceeds to the diagnosis of the next channel determined by the diagnosis channel control unit 8.

Next, the flow of data in the extraction unit 5, expected value generation unit 4, and comparison unit 6 will be described with reference to FIG. In the multiplexed data M, input data I1 to In are switched and multiplexed at certain time intervals. FIG.
, K channels are multiplexed. Each data is provided with a channel identifier so that it is possible to identify which channel each data belongs to. By setting the extraction unit 5 to extract the data of the channel k, the extraction unit 5 performs an operation of extracting the data of the identifier k from the multiplexed data M (Step 200). On the other hand, the expected value generator 4 generates an expected output value of the diagnostic data in accordance with the format after multiplexing, using the diagnosis source data as a source. (Step 20
1). Then, the comparing unit 6 compares the extracted data output by the extracting unit 5 with the expected value data output by the expected value generating unit 4 (Step 202). The comparison result is notified to the operator as a diagnosis result as described above.

In the above-described embodiment, a method of creating an expected value in a format after multiplexing from diagnostic data has been described. On the other hand, as shown in FIG.
Conversely, a method of comparing the extracted data to the input data format and then comparing the data may be considered. That is, the extraction unit 5 performs an operation of extracting the data of the identifier k from the multiplexed data M (step 300), and the expected value generation unit 4 uses the output of the extraction unit 5 as a source and performs diagnosis data according to the format before multiplexing. Is generated (step 30).
1) The comparison unit 6 compares the expected value data output from the expected value generation unit 4 with the diagnosis source data (step 302), so that the diagnosis can be performed as described above. In addition, although the extraction unit 5 extracts the diagnostic data based on the channel identifier, a case where the format of the time division multiplexing is determined as shown in FIG. 5 instead of the identifier may be considered. In such a case, by performing the extraction of the operation of the extraction unit 5 based on a predetermined format, it is possible to realize a diagnosis capable of obtaining the same effect as described above.

[0024]

As described above, according to the present invention, the input selection switch for switching and inputting any of the input data of a plurality of channels and the diagnostic data used in the self-diagnosis to the multiplexing section, and used for the self-diagnosis. A diagnostic data generating unit that generates the diagnostic data and outputs the diagnostic data to a channel specified by a diagnostic channel; and a multiplexing unit that multiplexes the diagnostic data based on the diagnostic data generated by the diagnostic data generating unit. An expected value generating unit that generates an expected value of diagnostic data according to a format before being generated or multiplexed as an expected value, based on a channel identifier in the multiplexed data output by the multiplexing unit. Extracting only diagnostic data of the channel specified by the diagnostic channel or extracting known diagnostic source data used for self-diagnosis. Alternatively, an extractor for extracting diagnostic data having a predetermined time-division multiplex format is provided, and the diagnostic data extracted by the extractor and the expected value generated by the expected value generator are provided to the comparator. Value data with respect to all bits, and causes the diagnostic channel control unit to determine a diagnostic channel based on channel usage information from the man-machine interface, to specify an extraction channel for the extraction unit and to diagnose the diagnostic data generation unit. Since it is configured to specify the channel, the self-diagnosis of the multiplex function can be performed for each virtual channel, and it is not necessary to interrupt the transmission of other used channels at the time of diagnosis,
Diagnosis can always be performed in the operating state. Furthermore, since only unused channels can be diagnosed at all times, the multiplexing apparatus can be self-diagnosed during initial startup when all channels are unused, or during normal operation when both used and unused channels are mixed. Diagnosis results can always be obtained without instructing the start of diagnosis, and diagnosis results can be obtained for each channel, which can be useful information for maintenance such as replacement of a failed channel. The effect is obtained.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a self-diagnosis system for a multiplexing device according to an embodiment of the present invention.

FIG. 2 is a flowchart showing a self-diagnosis procedure according to the present invention.

FIG. 3 is an explanatory diagram illustrating operations of an expected value generation unit, a comparison unit, and an extraction unit according to the present invention.

FIG. 4 is an explanatory diagram showing another operation of the expected value generation unit, the comparison unit, and the extraction unit according to the present invention.

FIG. 5 is an explanatory diagram showing a time-division multiplexing format and an operation of an extraction unit according to another embodiment of the present invention.

[Explanation of symbols]

 I1 to In Input data 1 Input selection switch 2 Multiplexer 3 Diagnostic data generator 4 Expected value generator 5 Extractor 6 Comparer 8 Diagnostic channel controller 9 Man-machine interface 20-1 to 20-n Input processor 22 Multiplexer Channel switch 23 Output processing unit

Claims (6)

[Claims] An input selection switch for switching and inputting any of input data of a plurality of channels and diagnostic data used in a self-diagnosis to a multiplexing unit, generating the diagnostic data used for a self-diagnosis, and generating the diagnostic data A diagnostic data generating unit that outputs to a channel specified by a diagnostic channel; and an expected value that generates a format multiplexed in the multiplexing unit as an expected value based on the diagnostic data generated by the diagnostic data generating unit. A generating unit, based on a channel identifier in the multiplexed data output by the multiplexing unit, an extracting unit that extracts only diagnostic data of the channel specified by the diagnostic channel, and diagnostic data extracted by the extracting unit. A comparison unit that compares all the bits with the expected value data generated by the expected value generation unit; A diagnostic channel control unit that determines a diagnostic channel based on the channel usage information, specifies an extracted channel for the extracting unit, and specifies a diagnostic channel to the diagnostic data generating unit. Self-diagnosis system. 2. An input selection switch for switching and inputting any of input data of a plurality of channels and diagnostic data used in a self-diagnosis to a multiplexing unit, generating the diagnostic data used for a self-diagnosis, and generating the diagnostic data. A diagnostic data generator for outputting a channel specified by a diagnostic channel; an expected value generator for generating an expected value of diagnostic data in accordance with a format before being multiplexed in the multiplexing unit; and a multiplex output by the multiplexing unit. An extraction unit for extracting only the diagnostic data of the channel specified by the diagnostic channel based on the channel identifier in the coded data; known diagnostic source data used for self-diagnosis; and an expected value generated by the expected value generating unit. A comparison unit that compares data with all bits and a diagnosis based on channel usage information from the man-machine interface Determining the channel, the self-diagnosis system of the multiplex device is characterized in that a diagnostic channel control unit for specifying the diagnosis channel to the specified and the diagnostic data generation unit of the extraction channel with respect to the extraction unit. 3. An input selection switch for switching and inputting any of input data of a plurality of channels and diagnostic data used at the time of self-diagnosis to a multiplexing unit, and generating the diagnostic data used for the self-diagnosis. An expected value for generating, as an expected value, a format multiplexed in the multiplexing unit based on a diagnostic data generating unit to be output to a channel specified by a diagnostic channel and diagnostic data generated by the diagnostic data generating unit; A generating unit, an extracting unit for extracting diagnostic data having a predetermined time-division multiplex format, and all bits of the diagnostic data extracted by the extracting unit and the expected value data generated by the expected value generating unit. And a comparing unit for comparing the diagnostic channel based on the channel usage information from the man-machine interface. Self-diagnostic system for multiplexing apparatus characterized by comprising a diagnostic channel control unit for specifying the diagnosis channel to the specified and the diagnostic data generation unit of the extraction channel against. 4. An input processing unit for synchronizing input data or diagnostic data for each channel with internal processing timing, and the multiplexing unit outputs data output from the input processing unit in a time division multiplexed manner. And a multiplexing channel switch for switching and outputting the data, and an output processing unit for adding the channel identifier to the data of each channel switched and output by the multiplexing channel switch and outputting the data as the multiplexed data. The self-diagnosis system for a multiplex apparatus according to any one of claims 1 to 3. 5. The diagnostic channel control unit according to claim 1, wherein the designation of the diagnostic channel by the diagnostic channel control unit is performed only for an unused channel to which no external data is input. 5. A self-diagnosis system for a multiplex device according to 6. Whenever the diagnosis of one channel is completed, it is checked whether or not the channel use information has been changed from the man-machine interface. If there is a change, the changed channel use information is transmitted. The self-diagnosis system for a multiplexing device according to claim 1, wherein the input selection switch is controlled by switching.