JP3583090B2 - Orderwire communication system and communication failure detection method therefor - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to an order wire communication system for performing a voice meeting. In particular, the present invention relates to a communication failure detection method for an orderwire communication system that automatically specifies an abnormal location when a line failure occurs in the orderwire communication system.
[0002]
[Prior art]
FIG. 13 is a diagram showing a schematic configuration of an order wire communication system on which the present invention is based. Note that the same components will be denoted by the same reference numerals and symbols throughout the drawings.
As shown in this drawing, it is assumed that a transmission system is configured by a plurality of transmission devices 21 to 26 connected in a straight line.
[0003]
In the transmission system, for example, the transmission / reception east side of the transmission device 21 is connected to the transmission / reception west side of the transmission device 22, the transmission / reception east side of the transmission device 22 is connected to the transmission / reception west side of the transmission device 23, The transmission / reception east side is connected to the transmission / reception west side of the transmission device 24, the transmission / reception east side of the transmission device 24 is connected to the transmission / reception west side of the transmission device 25, and the transmission / reception east side of the transmission device 25 is transmitted / received by the transmission device 26. It is connected to the west side and connected and arranged linearly.
[0004]
When constructing a transmission system in this way, an order wire communication system is installed without any inconvenience and connected between transmission devices. In this case, digital branch circuits 101 to 106 constituting an order wire communication system are connected to the transmission devices 21 to 26, respectively.
The order wire communication system is a system based on an E1 or E2 byte voice meeting function of SDH (Synchronous Digital Hierarchy) overhead.
[0005]
In particular, when constructing the transmission system, the maintenance staff must manually call the order wire from one transmission device to the other transmission devices that make up the transmission system to check the function. I have.
For example, digital branch circuits 102 and 104 are used in the transmission devices 22 and 24, and a voice meeting is performed between the digital branch circuits 102 and 104 via the transmission device 23 by order wire communication.
[0006]
FIG. 14 is a diagram illustrating an example in which a communication failure occurs in the order wire communication system due to a transmission line failure in FIG.
If there is one or more line faults of the order wire communication in the transmission path, for example, as shown in this figure, when a transmission path failure occurs between the transmission apparatus 23 and the transmission apparatus 24, at that time, Orderwire communication is disabled.
That is, orderwire communication cannot be performed between the transmission devices 24, 25, and 26 connected farther than the fault and the transmission devices 22 and 23 connected to the near side.
At the same time as a failure in the transmission path between the transmission devices 22 and 23 is found, a communication failure in the order wire communication system is found.
Regarding the communication failure of the order wire communication system in such a case, as disclosed in Japanese Patent Application Laid-Open No. 7-303149, if a transmission path failure occurs, the order wire communication becomes impossible and the maintenance person recognizes the failure line. After that, it is described that the orderwire communication is to be established, and further, it is disclosed that the orderwire communication connection of other parts except the part where the transmission path failure is detected is automatically performed.
[0007]
FIG. 15 is a diagram illustrating an example in which the orderwire communication is disabled due to a failure in the orderwire communication system itself in FIG.
As shown in this figure, even if there is no transmission path failure, there is a case where the order wire communication system including the digital branch circuit 104 has a failure and the order wire communication becomes impossible.
The order wire communication system failure is often found only when communication with the order wire communication system connected to the transmission device 24 is disabled.
[0008]
[Problems to be solved by the invention]
However, in the above-mentioned order wire communication system, since the order wire function monitoring has been performed manually, there is a problem that the discovery of a communication failure in the order wire communication system tends to be delayed.
In addition, if a failure is found even in one place in the order wire communication system of the transmission path system, the work must be repeated to the place where the transmission device is installed, and the operation of calling all the transmission devices again must be repeated. In other words, as the number of transmission devices constituting the transmission system increases, the amount of work increases.
[0009]
SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an orderwire communication system and a failure detection method thereof that can detect a communication failure of an orderwire communication system at an early stage in a transmission system.
[0010]
[Means for Solving the Problems]
The present invention, in order to solve the above problems, in an order wire communication system that performs order wire communication among a plurality of transmission devices, among the transmission devices connected linearly, from each transmission device at both ends other than both ends. When a call is made to each of the other transmission devices with a DTMF signal having a unique number, a connection monitoring unit that periodically transmits a DTMF signal of a fault monitoring number and a test voice signal, and a DTMF signal of the fault monitoring number is received. A reply unit that sends a reply to the effect that the connection monitoring unit has received the signal and that transmits a DTMF signal indicating whether the sound reproduction of the test sound signal has been normally performed. I do.
[0011]
By this means, it is possible to detect a communication failure of the order wire communication system in the transmission system at an early stage.
Preferably, the connection monitoring units of the transmission apparatuses at both ends perform the periodic calls asynchronously with each other and set the intervals of the periodic calls to be different.
[0012]
By this means, congestion can be prevented.
Preferably, when the plurality of transmission devices are connected in a ring shape, one portion between the transmission devices is separated so as not to perform line connection of order wire communication, and the connection monitoring unit is connected to the separated transmission device. Is provided.
[0013]
By this means, it is possible to prevent the oscillation phenomenon of the order wire communication caused by being connected in a ring shape, and to early find a communication failure of the order wire communication system.
Preferably, the reply unit of the transmission device other than the both ends is not called by the calling buzzer when it is called by the DTMF signal of the unique number and receives the DTMF signal of the fault monitoring number.
[0014]
According to this means, it is possible to identify and confuse the call of the voice meeting by the order wire communication with the call of the monitoring of the communication failure of the order wire communication system.
Preferably, when the connection monitoring unit does not receive a reply from the return unit in response to the transmission of the DTMF signal of the failure monitoring number, the connection monitoring unit issues an alarm indicating that there is a communication failure of the order wire communication system due to a transmission line failure. appear.
[0015]
By this means, the occurrence of a failure in order wire communication due to a transmission path failure can be found at an early stage.
Preferably, when the connection monitoring unit receives a reply from the reply unit in response to the transmission of the DTMF signal of the fault monitoring number, and receives a DTMF signal indicating that sound reproduction of the test sound signal is abnormal. , An alarm indicating that there is a communication failure in the order wire communication system itself is generated.
[0016]
By this means, the occurrence of a communication failure in the order wire communication system itself can be found early.
Preferably, the connection monitoring device is provided in a transmission device located in the middle of the plurality of transmission devices connected in a linear or ring shape.
By this means, even if the number of transmission devices increases, the occurrence of a communication failure in a large number of order wire communication systems can be found at an early stage.
[0017]
Preferably, the connection monitoring unit is provided in a transmission device at an intersection formed by connecting a plurality of transmission devices connected in a straight line.
By this means, even if the number of transmission devices increases, the occurrence of a communication failure in a large number of order wire communication systems can be found at an early stage.
[0018]
Preferably, the connection monitoring unit is connected to a transmission device at an intersection formed by connecting a plurality of ring-shaped transmission devices and a plurality of linear transmission devices in combination.
By this means, even if the number of transmission devices increases, the occurrence of a communication failure in a large number of order wire communication systems can be found at an early stage.
[0019]
Furthermore, the present invention relates to a communication failure detection method for an orderwire communication system in which orderwire communication is performed between a plurality of transmission devices, wherein the transmission devices connected in a straight line include a transmission device other than both ends. Periodically transmitting a call with a DTMF signal having a unique number to each transmission device, transmitting a DTMF signal having a fault monitoring number and a test voice signal after the call, and A step of receiving a DTMF signal of the fault monitoring number, a step of sending a reply indicating that the DTMF signal of the fault monitoring number has been received to the transmission devices at both ends, and a step of checking whether the audio reproduction of the test audio signal has been normally performed. Returning a DTMF signal; and generating a first alarm if a response indicating that the DTMF signal of the fault monitoring number has been received is not received. If the audio reproduction of the test audio signal receives a reply indicating that abnormal provides communication failure detection method orderwire communication system, comprising the step of generating a second alarm.
[0020]
By this means, it becomes possible to detect a communication failure of the order wire communication system in the transmission system at an early stage, as in the above invention.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a schematic configuration of an order wire communication system according to the present invention. As shown in FIG. 12, compared to FIG. 12, the connection monitoring units 21A and 26A are connected to the transmission devices 21 and 26 located at both ends of the transmission system including a plurality of transmission devices 21 to 26 connected linearly. Are provided, and reply units 22B to 25B are provided in the other transmission devices 22 to 25 which are monitored devices.
[0022]
The connection monitoring units 21A and 26A of the transmission devices 21 and 26 respectively monitor the subordinate transmission devices 22 to 25 for communication failure of the order wire communication system.
The return units 22B to 25B of the transmission devices 22 to 25 return reports of monitoring results to the connection monitoring units 21A and 26A, respectively.
FIG. 2 is a block diagram showing a schematic configuration of the connection monitoring units 21A and 26A and the reply units 22B to 25B, and FIG. 3 is held in the unique number holding unit 61 and the voice data holding unit 62 for voice communication text of FIG. FIG. 4 is a diagram showing an example of data.
[0023]
As shown in FIG. 3A, each of the connection monitoring units 21A and 26A is provided with a unique number holding unit 61. As shown in FIG. It holds a unique number, which is a calling number of the devices 22 to 25, and a fault monitoring number. The connection monitoring units 21A and 26A of the transmission devices 21 and 26 periodically call a unique number of each of the transmission devices 22 to 25 with a DTMF (Dial Tone MultiFrequency) signal and transmit a DTMF signal of a failure monitoring number. As a result, a failure monitoring command is transmitted.
[0024]
In this case, the connection monitoring units 21A and 26A may perform the periodic calls asynchronously with each other, and may set the intervals of the periodic calls to be different. This is to prevent congestion.
In addition, each of the connection monitoring units 21A and 26A is provided with a voice data holding unit 62 for voice meeting text, and the voice data holding unit 62 for voice meeting text is, as an example, as shown in FIG. Next, the voice data for the voice collation test of "The test of the order wire communication system is being performed." This audio data is used for audio meeting of the E1 or E2 byte of the SDH overhead.
[0025]
Further, each of the connection monitoring units 21A and 26A is provided with a reply judgment unit 63. The reply judgment unit 63, based on the reply status of the monitoring results from the subordinate transmission devices 22 to 25, as described later, can receive an order wire. It is determined whether there is a communication failure in the communication system. As shown in FIG. 3B, each of the reply units 22B to 25B is provided with a fault monitoring number identification unit 64, and the fault monitoring number identification unit 64 identifies a fault monitoring number from the received signal.
[0026]
When the fault monitoring number identification unit 64 identifies the fault monitoring number from the received signal, each of the reply units 22B to 25B sends a reply to the effect that the fault monitoring number has been received to the connection monitoring units 21A and 26A.
Note that if a signal including a failure monitoring number cannot be received due to a transmission path failure, the above reply cannot be made.
Further, each of the reply units 22B to 25B is provided with an audio data reproduction detection unit 65. The audio data reproduction detection unit 65 converts the audio data used for the audio meeting into an analog signal and reproduces the analog signal. Sound reproduction is detected based on the signal level.
[0027]
That is, the audio data reproduction detection unit 65 determines that the audio reproduction is normal when the level of the analog signal is higher than a predetermined value, and conversely determines that the audio reproduction is abnormal when the level is lower.
Each of the reply units 22B to 25B returns a DTMF signal indicating a normal state to the connection monitoring units 21A and 26A when the audio data reproduction detection unit 65 determines that the audio reproduction is normal, and conversely, the audio reproduction Is determined to be abnormal, a DTMF signal indicating the abnormality is returned.
[0028]
The reply judging unit 63 of the connection monitoring units 21A and 26A sends a fault monitoring command to the transmission devices 22 to 25. Is determined to have caused a communication failure in the order wire communication system.
Further, the reply judging section 63 of the connection monitoring sections 21A and 26A determines that the sound reproduction of the sound data used for the sound meeting is abnormal even if there is a reply from the reply sections 22B to 25B in response to the transmission of the failure monitoring command. , It is determined that a communication failure has occurred in the orderwire communication system itself.
[0029]
FIG. 4 is a diagram illustrating an example of a case where a communication failure occurs in the order wire communication system due to a transmission line failure in FIG.
As shown in the figure, in the connection monitoring unit 21A, a DTMF signal indicating a normal state is returned from the return units 22B and 23B, and when there is no response from the return units 24B and 25B, the transmission device 23 which is the monitored device is returned. And 24, it is possible to determine that a communication failure of the order wire communication system has occurred due to the transmission path failure.
[0030]
Similarly, in the connection monitoring unit 26A, a DTMF signal indicating a normal state is returned from the return units 25B and 24B, and if there is no response from the return units 23B and 22B, the transmission monitoring units 23 and 24 Thus, it is possible to determine that a communication failure has occurred in the order wire communication system due to the transmission path failure.
FIG. 5 is a diagram showing an example of a case where there is no communication failure in the order wire communication system including the digital branch circuit without the transmission line failure in FIG.
[0031]
As shown in the figure, in the connection monitoring unit 21A, when a DTMF signal indicating a normal state is returned from the reply units 22B, 23B, and 25B, and a DTMF signal indicating an abnormality is returned from the reply unit 24B, the transmission device 24A is returned. It is determined that a communication failure has occurred in the order wire communication system.
[0032]
Similarly, in the connection monitoring unit 26A, when a DTMF signal indicating a normal state is returned from the reply units 25B, 23B, and 22B and a DTMF signal indicating an abnormality is returned from the reply unit 24B, the order wire communication of the transmission device 24 is performed. It is determined that a communication failure has occurred in the system.
As described above, even if a signal including a failure monitoring number is received from the return units 22B, 23B, 24B, and 25B for the connection monitoring units 21A and 26A without a transmission path failure, the return units 22B, 23B, 24B, If a DTMF signal indicating an abnormality is returned from any of the communication devices 25B, it is determined that a communication failure has occurred in the order wire communication system of the transmission device.
[0033]
FIG. 6 is a flowchart illustrating a series of operations of the connection monitoring units 21A and 26A in FIG.
In step S31, each of the connection monitoring units 21A and 26A waits for the elapse of a certain time T in order to periodically perform the connection monitoring function operation.
In step S32, n = 22 is set.
[0034]
In step S33, calling is performed using the DTMF signal of the unique number of the transmission device n held in the unique number holding unit 61.
In step S34, the DTMF signal of the fault monitoring number is transmitted, and the voice data for the voice communication test held in the voice data storage unit 62 for the voice communication test is set to the E1 or E2 byte of the overhead. Transmit the frame.
[0035]
In step S35, the reply determination unit 63 determines whether a reply DTMF signal has been received from one of the reply units 22B to 25B with respect to the transmitted DTMF signal of the fault monitoring number. If not, the process proceeds to step S39.
In step S36, when the return DTMF signal is received, it is determined whether or not the received DTMF signal indicates a normal state. If it cannot be determined that it indicates a normal state, the process proceeds to step S40.
[0036]
If it is determined in step S37 that the state indicates a normal state, it is determined whether n = 5 holds. If the above expression is satisfied, the process proceeds to step S41. If the above equation does not hold in step S38, n = n + 1 is set, the process returns to step S33, and the above procedure is repeated.
In step S39, an alarm is generated between the transmission device n-1 and the transmission device n indicating that there is a communication failure in the order wire communication system caused by the transmission path failure. This is to prevent the discovery of the communication failure of the order wire communication system from being delayed.
[0037]
In step S40, an alarm is generated indicating that there is a communication failure in the order wire communication system itself of the transmission device n.
In step S41, the above-mentioned certain time is set to T = 0, and the processing is ended.
FIG. 7 is a flowchart for explaining a series of operations of each of the reply units 22B to 25B in FIG.
In step S51, each of the reply units 22B to 25B determines whether or not the connection monitoring units 21A and 26A have been called. If there is no call, the process ends.
[0038]
In step S52, when there is the above call, the fault monitoring number identification unit 64 determines whether the DTMF signal of the fault monitoring number has been received. If it is determined that the information has not been received, the process proceeds to step S56.
In step S53, when the DTMF signal of the fault monitoring number is received, the voice data of the voice meeting is extracted from the transmitted E1 or E2 byte of the SDH overhead.
[0039]
In step S54, the extracted audio data is reproduced.
In step S55, the audio data reproduction detection unit 65 determines whether or not the audio has been normally reproduced. When the sound reproduction is performed normally, the process proceeds to step S58, and when the sound reproduction is not performed normally, the process proceeds to step S57.
If the DTMF signal of the fault monitoring number is not received in step S56, the calling buzzer is sounded, and the process proceeds to step S58.
[0040]
When the DTMF signal of the fault monitoring number is received, the buzzer for calling is not sounded. This is because there is no need to respond to the call.
In step S57, a DTMF signal indicating an abnormal state is returned, and the process proceeds to step S58.
In step S58, the line is disconnected, and the process ends.
[0041]
Thus, according to the present invention, the communication failure of the order wire communication system of the transmission system is monitored, and if there is a communication failure in the order wire communication system, an alarm is issued by the connection monitoring units 21A and 26A. Even when the orderwire communication is not used, a communication failure can be found, and the communication failure can be dealt with immediately.
FIG. 8 is a first modified example of FIG. 1 and is a diagram showing a schematic configuration for explaining an order wire communication function of a plurality of transmission devices connected in a ring.
[0042]
The present invention is also applicable to a function of order wire communication between a plurality of transmission devices 21 to 26 connected in a ring as shown in FIG.
Due to the characteristics of the digital branch lines 101 and 102 connected to the line of the order wire communication, if they are connected in a ring shape, an oscillation phenomenon occurs, which causes a communication failure.
[0043]
Therefore, in the case where a plurality of transmission devices 21 to 26 are connected in a ring shape, in order to prevent the above-described trouble, one place between the transmission devices is intentionally communicated between the transmission device 1 and the transmission device 6, for example, by order wire communication. So that no line connection is made.
When viewed from the transmission system, it is a ring-shaped transmission system, but when viewed from the order wire communication function, it can be treated as a linear transmission system.
[0044]
In the above example, the connection monitoring units 21A and 26A having a monitoring function are provided in the transmission devices 21 and 26, and the reply units 22B to 25B are provided in the other transmission devices 22 to 25.
FIG. 9 is a second modified example of FIG. 1 and is a diagram showing a schematic configuration for explaining an order wire communication function when the number of transmission devices connected in a straight line is large.
[0045]
As shown in the figure, when the number of the plurality of transmission devices 21 to n connected in a straight line is large, the connection monitoring units 21A and nA are provided in the transmission devices 21 and n at both ends of the transmission system. The transmission monitoring unit kA is also provided in the transmission device k at the intermediate position.
By additionally providing the connection monitoring unit kA, even if the number of transmission devices increases in a linear transmission system, it is possible to early find a communication failure occurrence point of a large number of order wire communication systems.
[0046]
FIG. 10 is a third modified example of FIG. 1 and is a diagram showing a schematic configuration for explaining an order wire communication function when a large number of transmission devices are connected in a ring.
As shown in the figure, when the number of the plurality of transmission devices 21 to n connected in a ring is large, the transmission devices 21 and n are separated so that the line connection of the order wire communication is not intentionally performed. A connection monitoring unit 21A, nA is provided, and a connection monitoring unit kA is also provided for the transmission device k at the intermediate position.
[0047]
By additionally providing the connection monitoring unit kA in this manner, even if the number of transmission devices increases in the ring transmission system, it is possible to early find a communication failure occurrence point of a large number of order wire communication systems. .
FIG. 11 is a modified example of FIG. 9 and is a diagram showing an example in which a plurality of transmission devices connected in a straight line are combined.
[0048]
As shown in FIG. 9, as compared with FIG. 9, a plurality of transmission devices 21 to n connected linearly and a transmission device k at an intermediate position in the plurality of linear transmission devices 21 to n are further set as intersections. It is assumed that a transmission system is configured by a plurality of transmission devices n + 1 to n + m connected in a straight line.
In this case, the connection monitoring units 21A, kA, nA, and (n + m) A are provided at the end of the transmission system, the transmission devices 21, k, n, and n + m at the intermediate positions.
[0049]
By providing the connection monitoring units 21A, kA, nA, and (n + m) A at the intersections formed at the linear ends and intermediate positions in the transmission system, the transmission system combines a plurality of linear transmission devices. In this case, even if the number of transmission devices increases, it is possible to early find a communication failure location in a large number of order wire communication systems.
FIG. 12 is a modified example of FIG. 10 and shows an example in which a plurality of transmission devices connected in a ring and in a straight line are combined.
[0050]
As shown in FIG. 10, as compared with FIG. 10, a plurality of transmission devices 21 to n connected in a ring shape and a transmission device k at an intermediate position among the plurality of transmission devices 21 to n connected in a ring shape are illustrated. It is assumed that a transmission system is composed of a plurality of transmission devices n + 1 to n + m that are further linearly connected as intersections.
In this case, the connection monitoring units 21A, kA, nA, and (n + m) A are connected to the transmission devices 21, n, k, and n + m at the ends separated in a ring shape, the intersections formed at the intermediate positions, and the linear ends. Provided.
[0051]
As described above, the connection monitoring units 21A, kA, nA, (n + m) are connected to the ring-shaped separation unit in the transmission system, the intersection formed at the intermediate position, and the transmission devices 21, n, k, and n + m at the linear ends. By providing A, even in a transmission system in which a plurality of ring-shaped or straight-line transmission devices are combined, even if the number of transmission devices increases, it is possible to early find a communication failure location of a large number of order wire communication systems. Become.
[0052]
Note that the above is an explanation of an example, and the present invention is not limited thereto, and a combination of a ring-shaped and a ring-shaped transmission system, further, a combination of a plurality of ring-shaped transmission systems, and a plurality of linear transmission systems , And a combination of a plurality of linear transmission systems and a plurality of ring transmission systems.
[0053]
That is, the present invention can be applied to a complicated transmission system and a transmission system in which the number of transmission devices is increased.
[0054]
【The invention's effect】
As described above, according to the present invention, of the transmission devices connected in a straight line, each transmission device at both ends is periodically called by a DTMF signal of a unique number to each of the transmission devices other than both ends. After the call, the DTMF signal of the fault monitoring number and the test voice signal are transmitted, and the DTMF signal of the fault monitoring number is received by the other transmission devices other than the both ends. A reply indicating that the signal has been received is returned, a DTMF signal indicating whether the sound reproduction of the test sound signal has been normally performed is returned, and if a reply indicating that the DTMF signal of the fault monitoring number has not been received is received, the first signal is returned. When an alarm is generated and a reply indicating that the audio reproduction of the test audio signal is abnormal is received, a second alarm is generated. It is possible to discover the communication failure of the beam at an early stage.
[0055]
When a plurality of transmission devices are connected in a ring, one location between the transmission devices is separated so that the line connection of the order wire communication is not performed, and a connection monitoring unit is provided in the separated transmission device. Therefore, it is possible to prevent an oscillation phenomenon caused by being connected in a ring shape and to find a communication failure of the order wire communication system at an early stage.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of an order wire communication system according to the present invention.
FIG. 2 is a block diagram illustrating a schematic configuration of connection monitoring units 21A and 26A and reply units 22B to 25B.
FIG. 3 is a diagram showing an example of data stored in a unique number storage unit 61 and a voice communication text voice data storage unit 62 of FIG. 2;
FIG. 4 is a diagram illustrating an example where a communication failure occurs in the order wire communication system due to a transmission line failure in FIG.
FIG. 5 is a diagram illustrating an example of a case where there is no communication failure in the order wire communication system including the digital branch circuit without a transmission line failure in FIG. 1;
FIG. 6 is a flowchart illustrating a series of operations of connection monitoring units 21A and 26A in FIG.
FIG. 7 is a flowchart illustrating a series of operations of reply units 22B to 25B in FIG. 1;
FIG. 8 is a first modification of FIG. 1, and is a diagram showing a schematic configuration for explaining an order wire communication function of a plurality of transmission devices connected in a ring shape.
FIG. 9 is a second modification of FIG. 1 and is a diagram illustrating a schematic configuration for explaining an order wire communication function when the number of a plurality of transmission devices connected in a straight line is large.
FIG. 10 is a third modification of FIG. 1, and is a diagram showing a schematic configuration for explaining an order wire communication function when the number of transmission devices connected in a ring is large.
11 is a modified example of FIG. 9 and shows an example in which a plurality of transmission devices connected in a straight line are combined.
FIG. 12 is a modification of FIG. 10 and shows an example in which a plurality of transmission devices connected in a ring and in a straight line are combined.
FIG. 13 is a diagram showing a schematic configuration of an order wire communication system which is a premise of the present invention.
FIG. 14 is a diagram illustrating order wire communication when a communication failure occurs in the order wire communication system due to a transmission line failure in FIG.
FIG. 15 is a diagram illustrating order wire communication when a communication failure occurs in the order wire communication system due to a failure in the order wire communication system itself in FIG.
[Explanation of symbols]
21-26-n- (n + m) ... Transmission device
21A, 26A, kA, nA, (n + m) A ... connection monitoring unit
22B to 25B to (k-1) B, (k + 1) B to (n-1) B, (n + 1) B to (n + m-1) B ... reply section
101, 102 ... Digital branch circuit

Claims (10)

In an order wire communication system that performs order wire communication between a plurality of transmission devices,
Of the transmission devices connected in a straight line, each transmission device at both ends calls each transmission device other than both ends with a DTMF signal of a unique number, a DTMF signal of a fault monitoring number, and a test voice signal. A connection monitoring unit that periodically sends
Upon receiving the DTMF signal of the fault monitoring number, the reply unit notifies the connection monitoring unit that the DTMF signal has been received, and transmits a DTMF signal indicating whether the audio reproduction of the test audio signal has been normally performed. An order wire communication system, comprising: 2. The order wire according to claim 1, wherein the connection monitoring units of the transmission devices at both ends perform periodic calls asynchronously with each other, and set intervals of the periodic calls to be different from each other. 3. Communications system. When the plurality of transmission devices are connected in a ring, one connection between the transmission devices is separated so as not to perform line connection of order wire communication, and the connection monitoring unit is provided in the separated transmission device. The orderwire communication system according to claim 1, characterized in that: The said return part of the transmission apparatus other than both ends is called by the DTMF signal of the unique number, and does not ring the buzzer for calling when the DTMF signal of the fault monitoring number is received. 2. The order wire communication system according to 1. The connection monitoring unit may generate an alarm indicating that there is a communication failure in the order wire communication system due to a transmission line failure when receiving no response from the return unit in response to the transmission of the DTMF signal of the failure monitoring number. The order wire communication system according to claim 1, wherein: The connection monitoring unit, in response to the transmission of the DTMF signal of the fault monitoring number, receives a reply from the reply unit, and receives a DTMF signal indicating that the audio reproduction of the test audio signal is abnormal. 2. The order wire communication system according to claim 1, wherein an alarm indicating that a communication failure exists in the communication system itself is generated. 4. The order wire communication system according to claim 1, wherein the connection monitoring device is provided in a transmission device located between a plurality of the transmission devices connected in a straight line or a ring shape. 5. 2. The order wire communication system according to claim 1, wherein the connection monitoring unit is provided in a transmission device at an intersection formed by connecting a plurality of transmission devices connected in a straight line. 3. The connection monitoring unit is provided in a transmission device at an intersection formed by connecting a plurality of ring-shaped transmission devices and a plurality of linear transmission devices in a plurality of combinations, wherein the connection monitoring unit is provided. Item 4. The order wire communication system according to Item 3. In a communication failure detection method of an order wire communication system that performs order wire communication between a plurality of transmission devices,
Of the transmission devices connected in a straight line, a process of periodically calling a DTMF signal of a unique number from each transmission device at both ends to each transmission device other than both ends,
Transmitting a DTMF signal of the fault monitoring number and a test voice signal after the call;
Receiving a DTMF signal of the fault monitoring number at another transmission device other than both ends;
Sending back to the transmission devices at both ends a notification that the DTMF signal of the fault monitoring number has been received;
Returning a DTMF signal indicating whether the audio reproduction of the test audio signal has been normally performed;
Generating a first alarm when not receiving a reply indicating that the DTMF signal of the fault monitoring number has been received;
Generating a second alarm if a reply indicating that the audio reproduction of the test audio signal is abnormal is received.

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