JPH0583781A - Trouble monitor - Google Patents

Abstract

PURPOSE:To decrease the load of a main control part, to shorten the confirming time of the normality of the unused connecting channel of a switch part and to specify a trouble place. CONSTITUTION:A switch control part 12 detects the utilization condition of the port of a switch 31 by the content of a memory part 11 and outputs a switching control signal. When the normality of the unused connecting channel is confirmed, at the time of the internal part of a switch 311, confirmation is performed by a pattern generator 1511, selectors 1311 and 1312, and a detector 1611 based on a switching control signal, and at the time of the section between a switch 311 and a switch 312, the confirmation is performed by a pattern generator 1512, selectors 1411 and 1422 and a detector 1622 based on a switching control signal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used in a fault monitoring device for a matrix switch having a multistage structure. In particular, the present invention relates to a fault monitoring device capable of confirming the normality of all unused connection paths of a multistage switch in a short time.

[0002]

2. Description of the Related Art FIG. 3 is a block diagram of a conventional fault monitoring apparatus.

Conventionally, as shown in FIG. 3, a fault monitoring apparatus has an interface unit 40 ₁ for inputting an external signal.
And an interface unit 40 ₂ for outputting a signal to the outside,
The switch unit 30 has a switch size of M × N (where the total number of input terminals is M and the total number of output terminals is N), a pattern generator 60 for transmitting a fault monitoring test signal, and a pattern generator 60 for transmitting the fault monitor test signal. A detector 70 that receives the received signal and determines the normality of the signal, a selector 41 ₁ that selects an input terminal of the switch unit 30 that is configured by M 2-1 selectors and that detects a failure, and a N selector 2 1. a selector 41 ₂ for selecting the output terminal of the switch unit 30 that performs -1 selectors and one of N-1 selectors than the configured fault monitoring, connection setup and the selector 4 switches 30
It is composed of a main control unit 50 which performs connection setting of 1 ₁ and 41 ₂ .

When monitoring the normality of unused connection paths, the main control unit 50 sets the input / output connection settings of the switch unit 30 and the connection settings of the selectors 41 ₁ and 41 ₂ whose normality should be confirmed. This is performed by software. After setting the connection path, the pattern generator 60 sends a test signal, the detector 70 detects a signal failure, and confirms the normality of the target unused connection path. For confirming the normality of the above, the procedure as described above was repeated.

[0005]

However, in such a conventional fault monitoring apparatus, M incoming lines and N outgoing lines are arbitrarily connected. In a switch of size M × N, the number M of incoming lines or the number N of outgoing lines becomes large,
When the switch size becomes large, there are the following problems.

(1) The main control unit performs centralized control,
In order to confirm the normality of all unused connection paths, the load on the software of the main control unit becomes large, the control becomes complicated, and the time required to confirm the normality becomes very long.

(2) It is expected that a new connection path will be set up without confirming the normality of all unused connection paths, and a failure will occur when the connection paths are actually used. There is a danger, and the reliability of the switch part is reduced.

(3) In addition, m incoming lines and n outgoing lines (m
≦ M, n ≦ N) are arbitrarily connected. Switch size is m
A switch having a switch size of M × N is realized by connecting a plurality of × n switches in combination. In a switch having a multi-stage configuration, the fault monitoring device as described above can confirm the fault between the input and the output of the entire multi-stage switch, but cannot identify where in the multi-stage switch the fault has occurred. ..

The present invention solves the above-mentioned drawbacks by reducing the load on the software of the main control unit, shortening the confirmation time of the normality of the unused connection path of the switch unit, and improving the reliability of the switch unit. It is an object of the present invention to provide a fault monitoring device capable of identifying a fault location.

[0010]

According to the present invention, there is provided a fault monitoring apparatus comprising a switch section including a switch having a multi-stage structure and a confirmation means for confirming the normality of an unused connection path of the switch section. Means, each of which stores the connection information of each switch, a switch control unit that detects the use state of the port of each switch based on the contents of this memory, and outputs a corresponding switching control signal,
First pattern sending means for sending a first fault monitoring test signal from all unused input ports of each switch to all unused output ports of each switch based on the corresponding switching control signal. The first pattern detecting means for receiving the outputs of the corresponding first pattern sending means at all unused output ports of the respective switches on the basis of the corresponding switching control signal and judging the pattern, Second pattern sending means for sending a second fault monitoring test signal from all unused output ports of one of the switches to subsequent switches based on the switching control signal, and the corresponding switching control. Based on the signal, the second input for receiving the outputs of the second pattern sending means at all the unused input ports of the latter-stage switches to judge the pattern, respectively. Characterized in that it comprises a tongue detecting unit.

Further, according to the present invention, the switch section selects and connects the natural number M of incoming lines and the natural number N of outgoing lines.
The switch size is × N, and the switch size for selecting and connecting a natural number m of incoming lines and a natural number n of outgoing lines is m.
Xn switches are configured in multiple stages, and the first pattern sending means includes a first pattern generator for generating the predetermined first random pattern and all of the switches on the basis of the corresponding switching control signal. A first selector for sending out the first fault monitoring test signal from the unused input port to the switch, and the first pattern detecting means corresponds to the switch based on the corresponding switching control signal. A second selector that receives the output of the first selector at all unused output ports of the second selector, and a first detector that receives the output of the second selector and determines a pattern, The second pattern sending means includes a second pattern generator for generating the second fault monitoring test signal and each of the switches based on the corresponding switching control signal. A second selector for transmitting the second fault monitoring test signal from all unused output ports to the subsequent switches, respectively, and the second pattern detection means outputs the second switching control signal to the corresponding switching control signal. Based on the fourth selector that receives the output of the third selector at all unused input ports of the switch in the latter stage, and the second detector that inputs the output of the fourth selector and determines the pattern. Can be included.

Further, according to the present invention, the first selector selects and disconnects m input lines of the switch based on the corresponding switching control signal, and the disconnected switch-side input lines are connected to the first pattern generator. Including means for connecting to
The second selector selects and disconnects n output lines of the switch based on the corresponding switching control signal, and selects one of the disconnected switch-side output lines to select the first detector. Means for connecting to the n switch of the switch based on the corresponding switching control signal.
Means for connecting the second switch to the second pattern generator by selecting and disconnecting the output line of the book and connecting the output line on the side opposite to the switch to the second pattern generator, wherein the fourth selector of the switch is based on the corresponding switching control signal. Means may be included for selecting and disconnecting the m input lines and selecting one of the disconnected input lines on the non-switch side to connect to the second detector.

The switch controller may be a decoder.

Further, the second selector and the fourth selector can be AND gates.

[0015]

The confirming means stores the connection information of each switch in the memory, detects the usage state of the port of each switch in the switch control section based on the contents of the memory, and outputs the corresponding switching control signal. The first pattern sending means sends the first fault monitoring test signal from all unused input ports of each switch to all unused output ports of each switch based on the corresponding switching control signal. The output of the corresponding first pattern sending means is received by all the unused output ports of each switch on the basis of the corresponding switching control signal by the first pattern detecting means to determine the pattern. Further, the second pattern sending means sends a second monitoring test signal from each unused output port of one of the switches to the subsequent switch based on the corresponding switching control signal, Based on the corresponding switching control signal, the pattern detecting means receives the outputs of the second pattern sending means at all the unused input ports of the switches at the latter stage, and judges the pattern.

As described above, the load on the software of the main control unit can be reduced, the confirmation time of the normality of the unused connection path of the switch unit can be shortened, the reliability of the switch unit can be improved, and the failure point can be specified. ..

[0017]

Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram of a fault monitoring device according to an embodiment of the present invention.

In FIG. 1, the fault monitoring apparatus comprises a switch section 30 including switches 31 ₁ and 31 ₂ having a multi-stage structure, and a confirmation means for confirming the normality of an unused connection path of the switch section 30.

Here, a feature of the present invention is that the confirmation means is memory units 11 ₁ and 11 ₂ and memory units 11 ₁ and 11 ₂ as memories for storing connection information of the switches 31 ₁ and 31 ₂ , respectively. Based on the contents of each switch 3
A switch control unit 12 ₁ , which detects the use states of the ports 1 ₁ and 31 ₂ and outputs corresponding switching control signals,
And 12 _2, switch control signals from all the unused input port of each switch 31 _1, 31 ₂ based on for the first fault monitor to each switch 31 _1, 31 ₂ all unused output ports of this corresponding The first pattern transmitting means for transmitting the test signal and the outputs of the corresponding first pattern transmitting means at all the unused output ports of the switches 31 ₁ , 31 ₂ are respectively received based on the corresponding switching control signals. Based on the first pattern detection means for judging the pattern and all the unused output ports of one of the switches 31 (here, switch 31 ₁ ) based on the corresponding switching control signal, the switch 31 at the subsequent stage (here in 31 ₂₎ in a second pattern transmitting means for transmitting a second test signal for failure monitoring each and all of the non-subsequent stage of the switch 31 ₂ based on the switching control signal to the corresponding It is intended to include second pattern detecting means for receiving the output of the second pattern transmitting means at the used input port and determining the pattern.

The switch unit 30 has a switch size of 5 × 5 for selecting and connecting 5 natural numbers of incoming lines and 5 natural numbers of outgoing lines, and 5 natural numbers of incoming lines and 5 natural numbers of outgoing lines. Is connected in multiple stages and the first pattern sending means is a pattern generator 15 as a first pattern generator for generating the first fault monitoring test signal. ₁₁ (15 ₁₂ )
And the switch 31 ₁ based on the corresponding switching control signal.
Switch from all unused input ports of (31 ₂ ) to switch 31
₁ (31 ₂ ) includes a selector 13 ₁₁ (13 ₂₁ ) as a first selector for sending the first fault monitoring test signal random pattern, respectively, and the first pattern detection means is provided with the corresponding switch. Based on the control signal, all unused output ports of the corresponding switch 31 ₁ (31 ₂ ) receive the output of the selector 13 ₁₁ (13 ₂₁ ) as a second selector, and the selector 13 ₁₂ (13 ₂₂ ) and the selector 13 _The detector 16 ₁₁ (16 ₂₁ ) is included as a first detector that receives the output of ₁₂ (13 ₂₂ ) and determines the pattern, and the second pattern sending means outputs the second fault monitoring test signal. a pattern generator 15 ₁₂ as a second pattern generator for generating, in a subsequent stage from all unused output ports of the switch 31 ₁ on the basis of the switching control signal to the corresponding And a selector 14 ₁₁ as a third selector to deliver a respective test signal for monitoring the second failure switch 31 _2, the second pattern detection means, subsequent switch based on the switching control signal to the corresponding 31 ₂
As a fourth selector that receives the outputs of the selector 14 ₁₁ at all unused input ports of the selector 14
_22, includes a detector 16 ₂₂ as a second detector for determining the pattern type the output of the selector 14 _22.

Further, the selector 13 ₁₁ (13 ₂₁ ) switches the switch 31 ₁ (3 ₂₁ ) based on the corresponding switching control signal.
The selector 13 includes five 2-1 selectors as a means for selecting and disconnecting 5 incoming lines of 1 ₂ ) and connecting the cut incoming lines on the switch side to the pattern generator 15 _11.
12 (13 ₂₂ ) selects five outgoing lines of the switch 31 ₁ (31 ₂ ) based on the corresponding switching control signal and disconnects them, and selects one of the disconnected outgoing lines on the switch side. As a means for connecting to the detector 16 ₁₁ (16 ₂₁ ), 5 pieces of 2
-1 selector and one 5-1 selector, and the selector 14 ₁₁ selects and disconnects five outgoing lines of the switch 31 ₁ based on the corresponding switching control signal, and cuts the outgoing line on the side opposite to the switch. Is connected to the pattern generator 15 ₁₂ by including five 2-1 selectors.
₂₂ is a switch 31 ₂ based on the corresponding switching control signal.
As a means for connecting the detector 16 ₂₂ by selecting one of the 5 incoming lines and disconnecting it, and then selecting one of the disconnected incoming lines on the side opposite to the switch and one 5-
Includes 1 selector.

The operation of the fault monitoring apparatus having such a configuration will be described. FIG. 2 is a block configuration diagram of the switch unit of the fault monitoring apparatus of the present invention.

In FIG. 2, the switch unit 30 has a switch size of M × N (total number of input terminals is M, total number of output terminals is N).
In the above case) and a main controller 4 for controlling the three-stage link switch. The three-stage link switch has p primary switches 1 (p = M / m) having m input terminals and r output terminals.
, R secondary switches 2 having p input terminals and q output terminals, and q tertiary switches 3 having r input terminals and n output terminals (q = N / n) and. Here, a thick line shows a connection path in use, and a thin line shows an unused connection path between the switches. In the present invention, the normality of unused connection paths between all the switches indicated by thin lines and the normality of connection paths inside the switches having unused inputs and outputs are confirmed.

Next, referring to FIG. 1, the normality of unused connection paths is confirmed by confirming the normality of unused connection paths between the switches and the normality of unused connection paths inside each switch. It will be explained separately for the case of confirming the sex.

(1) When confirming the normality of an unused connection path between switches, for example, in failure monitoring of an unused connection path between the switch 31 ₁ and the switch 31 ₂ ,
In the switch part in the preceding stage, the switch control part 12 ₁ searches the memory part 11 ₁ for an unused output terminal, and uses the selector 14 ₁₁ to set the pattern generator 15 ₁₂ to the output terminal having the unused connection path. Connect and pattern generator 1
5 ₁₂ sends a test signal for fault monitoring.

In the switch part at the subsequent stage, the switch control part 12 ₂ uses the selector 14 ₂₂ to connect the detector 16 ₂₂ to an unused connection path, and the pattern generator 15 ₁₂
The normality of the fault monitoring test signal transmitted in step S6 is judged by the detector 16 ₂₂ to confirm the normality of the unused connection path.

When there are a plurality of unused connection paths between the switches, the switch control section 12 ₁ and the switch control section 12 ₂ automatically repeat the above-mentioned procedure to establish an unused connection between all the switches. Check the normality of the route.

(2) When confirming the normality of the unused connection path inside the switch, for example, in the switch part in the preceding stage, the switch control part 12 ₁ has the memory part 11
₁ searches an unused input and output terminals of the switch 31 _1, the setting up a connection unused input and output terminals in the switch 31 _1.

_On the input side of the switch 31 ₁ , the selector 13 is connected to an unused input terminal selected by the switch controller 12.
_The pattern generator 15 ₁₁ is connected using ₁₁ and the test signal for fault monitoring is sent from the pattern generator 15 ₁₁ .

[0030] In the switch 31 ₁ on the output side, the unused output terminal of the switch controller 12 ₁ is selected, the selector 1
3 ₁₂ connects the detector 16 ₁₁ with a, receives the test signal transmitted by the pattern generator 15 ₁₁ by the detector 16 _11, to determine the normality of the signal, to confirm the normality of the unused connection paths of the internal switch ..

When there are a plurality of unused connection paths inside the switch, the switch control unit 12 ₁₁ automatically repeats the above procedure to check the normality of all the unused connection paths inside the switch.

Further, the present invention can be realized by using a decoder as the switch control unit and using AND gates as the second selector and the fourth selector.

[0033]

As described above, the present invention has the following excellent effects even in a multi-stage switch.

(1) It is possible to confirm the normality of all unused connection paths including the unused connection path inside each switch and the unused connection path between the switches.

(2) When a fault is detected, the fault location can be specified.

(3) Since the failure is automatically detected by the hardware in each connection path, the failure can be detected in a short time and the reliability of the switch section can be improved. The load of the main control unit that controls the switch can be reduced because it is not necessary to perform complicated processing.

[Brief description of drawings]

FIG. 1 is a block configuration diagram of a fault monitoring device according to an embodiment of the present invention.

FIG. 2 is a block configuration diagram of a switch unit of the fault monitoring device.

FIG. 3 is a block configuration diagram of a conventional fault monitoring device.

[Explanation of symbols]

1 Primary Switch 2 Secondary Switch 3 Tertiary Switch 4, 50 Main Control Unit 11 ₁ , 11 ₂ Memory Unit 12 ₁ , 12 ₂ Switch Control Unit 13 ₁₁ , 13 ₁₂ , 13 ₂₁ , 13 ₂₂ , 14, _{11 11} , 14 ₁₂ , 1
4 ₂₁ , 14 ₂₂ , 41 ₁ , 41 ₂ Selectors 15 ₁₁ , 15 ₁₂ , 15 ₂₁ , 15 ₂₂ , 60 Pattern generator 16 ₁₁ , 16 ₁₂ , 16 ₂₁ , 16 ₂₂ , 70 Detector 30 Switch section 31 ₁ , 31 ₂ , 31 ₁₁ , 31 _1K , 31 _1p , 31 ₂₁ and 3
1 _2A , 31 _2r , 31 ₃₁ , 31 _3L , 31 _3q switch 40 ₁ , 40 ₂ interface section

Claims (5)

[Claims] 1. A fault monitoring apparatus comprising a switch unit including a switch having a multi-stage structure and a confirmation unit for confirming the normality of an unused connection path of the switch unit, wherein the confirmation unit is connection information of each switch. Respectively, a switch control section for detecting a use state of a port of each switch based on the contents of the memory and outputting a corresponding switching control signal, and each switch based on the corresponding switching control signal. A first pattern sending means for sending a first fault monitoring test signal from all unused input ports of the switch to all unused output ports of each switch, and the above-mentioned switching control signals based on the corresponding switching control signals. First pattern detection in which the outputs of the corresponding first pattern transmission means are respectively received by all unused output ports of the switch to judge the pattern And a second pattern sending means for sending a second fault monitoring test signal from all unused output ports of one of the switches to the subsequent switch based on the corresponding switching control signal. , A second pattern detecting means for receiving the outputs of the second pattern sending means at all unused input ports of the latter-stage switch on the basis of the corresponding switching control signal and determining the pattern. Characteristic fault monitoring device. 2. The switch unit is an M × N switch size for selecting and connecting a natural number M of incoming lines and a natural number N of outgoing lines, and a natural number m of incoming lines and a natural number of n outgoing lines. Are connected in a multi-stage manner with switches having a switch size of m × n (where m ≦ M and n ≦ N), and the first pattern sending means is the first fault monitoring test signal. Generating a first pattern generator and a first selector for transmitting the first fault monitoring test signal from each unused input port of each switch to the switch based on the corresponding switching control signal. The first pattern detecting means includes a second selector that receives the output of the first selector at all unused output ports of the corresponding switch based on the corresponding switching control signal, and A second detector that receives the output of the second selector and determines a pattern, and the second pattern sending means is a second pattern generator that generates the second fault monitoring test signal. A third selector for transmitting the second fault monitoring test signal from each unused output port of each switch to the subsequent switch based on the corresponding switching control signal, The pattern detection means includes a fourth selector that receives the outputs of the third selectors at all unused input ports of the latter-stage switches on the basis of the corresponding switching control signals, and an output of the fourth selector. 2. The fault monitoring apparatus according to claim 1, further comprising a second detector that inputs the value and determines a pattern. 3. The means for selecting and disconnecting m input lines of the switch based on the corresponding switching control signal, and connecting the disconnected switch-side input lines to the first pattern generator. The second selector selects and disconnects n output lines of the switch based on the corresponding switching control signal and selects one of the disconnected switch-side output lines. Means for connecting to one detector, the third selector selects and disconnects n output lines of the switch based on the corresponding switching control signal and disconnects the disconnected output line on the side opposite to the switch. Means for connecting to the second pattern generator, wherein the fourth selector selects and disconnects m input lines of the switch based on the corresponding switching control signal, and cuts the input lines on the non-switch side. 3. The fault monitoring device according to claim 2, further comprising means for selecting one and connecting to the second detector. 4. The fault monitoring device according to claim 1, wherein the switch control unit is a decoder. 5. The fault monitoring device according to claim 2, wherein the second selector and the fourth selector are AND gates.