JP6760855B2 - Transmission line switching device and method - Google Patents

Description

The present invention relates to a transmission line switching device and method used in a communication system that communicates by a current loop method.

Conventionally, a communication system that communicates by a current loop method has been used. The current loop method is a communication method for transmitting a signal by changing the current value, and is a communication terminal device connected in a transmission line by turning the loop current ON (for example, 30 mA) and OFF (for example, 2 mA). It is a communication method that transmits a communication signal to.

In this communication method, the communication signal when the loop current is turned on is called a mark signal, the loop current at that time is called a mark current, the communication signal when the loop current is turned off is called a space signal, and the loop current at that time is called a space current. (See, for example, Patent Document 1).

FIG. 8 is a diagram showing an example of a conventional communication system in which a transmission line adopting a current loop method is duplicated. In the figure, 1 is a power supply device, 2 is a communication terminal device group, and the transmission line between the power supply device 1 and the communication terminal device group 2 is duplicated. That is, in the communication system 100, the power supply device 1 and the communication terminal device group 2 are connected by the transmission line 3 of the A system and the transmission line 4 of the B system.

Although the communication terminal device group 2 is divided into two in FIG. 8 for convenience, the actual communication terminal device group 2 is one. The communication terminal device group 2 includes a master unit and a slave unit connected in series, and is connected as a common load in the transmission line 3 of the A system and the transmission line 4 of the B system.

Further, in this example, the A system transmission line 3 is provided with the switch 5, and the B system transmission line 4 is provided with the switch 6. Transistors are used as switches 5 and 6. The transmission line 3 of the A system is made into a main transmission line by putting the switch 5 in a marked state (a state in which a current easily flows). The B system transmission line 4 is a standby system transmission line by putting the switch 6 in a space state (a state in which current is difficult to flow (2 mA or less)).

In this communication system 100, the communication terminal device group 2 turns on the loop current of the transmission line 3 of the A system (main system) by changing the value of the current flowing through the transmission line 3 of the A system (main system). A message is transmitted by setting it to (for example, 30 mA) or OFF (for example, 2 mA).

[Transmission line switching device]
As shown in FIG. 9, the communication system 100 is provided with a transmission line switching device 7. The transmission line switching device 7 monitors the presence / absence of a message transmission request in the communication terminal device group 2, and if there is a message transmission request, the transmission line of the A system (main system) immediately before this message is transmitted. It is confirmed whether or not the loops of both the 3 and B (standby) transmission lines 4 are established.

Here, if the loop of the transmission line 3 of the A system (main system) is not established and the loop of the transmission line 4 of the B system (standby system) is established, the transmission line of the A system (main system) is established. It is determined that the wire 3 is broken, and the transmission line 4 of the B system (standby system) is switched to the main transmission line (see FIG. 10). That is, by putting the switch 5 in the space state and the switch 6 in the mark state, the main system is changed from the A system to the B system.

Japanese Unexamined Patent Publication No. 11-68856 Japanese Patent No. 4451718

Recently, as the power supply device 1, a method of adjusting the internal voltage VS'according to the load has been adopted (see, for example, Patent Document 2). If this method is adopted, the voltage adjustment work is eliminated and the operability is improved, but on the other hand, from the connection of the communication terminal device group 2 until the voltage VS'inside the power supply device 1 stabilizes (maximum 2 seconds). There will be a period during which communication is not possible.

Since it is rare that communication is required immediately after connecting the communication terminal device group 2, there is no problem in itself. However, in the communication system 100 in which the transmission lines are duplicated as described above, when the transmission line 3 of the A system (main system) is disconnected, the impedance load of the A system (main system) becomes maximum, and the voltage VS'inside the power supply device 1 The function to adjust is temporarily unstable. Therefore, when the transmission line 4 of the B system (standby system) is switched to the transmission line of the main system, it takes time for the voltage VS'inside the power supply device 1 to stabilize, and the time until communication can be resumed. The problem arises that it becomes long.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a transmission line switching device and a method capable of shortening the time until communication can be resumed. is there.

In order to achieve such an object, the present invention transmits the first transmission line (3), the second transmission line (4), the first transmission line, and the second transmission line as main transmissions, respectively. A communication terminal device group (2) configured to transmit a message by changing the value of the current flowing through the main transmission line as a line and standby transmission line, and the first transmission line and the first transmission line. Used in a communication system (200) equipped with a power supply device (1) whose internal voltage is adjusted according to a load, which supplies a power supply voltage to the second transmission line, and an abnormality has occurred in the first transmission line. In this case, in the transmission line switching device (7B) configured to switch the second transmission line to the main transmission line, there is no message transmission request in the communication terminal device group, and a current flows through the first transmission line. If the non-existence state continues for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line, and the transmission line switching unit (70) configured to switch the second transmission line to the main transmission line. , 70').

According to the present invention, when there is no message transmission request in the communication terminal device group and no current is flowing through the first transmission line (main transmission line) for a predetermined time or longer, the first transmission line (main transmission line) It is determined that an abnormality has occurred in the main system transmission line), and the second transmission line (standby system transmission line) is switched to the main system transmission line.

As a result, in the present invention, the second transmission line (standby transmission line) is switched to the main transmission line during the period when there is no message transmission request in the communication terminal device group. Further, the adjustment of the voltage inside the power supply device is also performed during the period when there is no message transmission request in the communication terminal device group. Therefore, when the next message is transmitted after switching the second transmission line (standby transmission line) to the main transmission line, it is not necessary to wait until the voltage adjustment inside the power supply becomes stable. Often, the time it takes to resume communication is shortened.

In the present invention, after the second transmission line (standby transmission line) is switched to the main transmission line, the second transmission line is the main transmission line and the first transmission line is on standby. It becomes the transmission line of the system. That is, after switching the second transmission line (standby transmission line) to the main transmission line, the second transmission line becomes the first transmission line (main transmission line) in the present invention. The first transmission line is the second transmission line (standby transmission line) in the present invention.

In the above description, as an example, the components on the drawing corresponding to the components of the invention are indicated by reference numerals in parentheses.

As described above, according to the present invention, there is no message transmission request in the communication terminal device group, and a state in which no current is flowing through the first transmission line (main transmission line) continues for a predetermined time or longer. , It was judged that an abnormality had occurred in the first transmission line (main transmission line), and the second transmission line (standby transmission line) was switched to the main transmission line. After switching the transmission line (standby transmission line) to the main transmission line, when transmitting the next message, it is not necessary to wait until the internal voltage adjustment of the power supply becomes stable, and communication resumes. It is possible to shorten the time until it can be done.

FIG. 1 is a diagram showing a main part of a communication system using a transmission line switching device according to an embodiment of the present invention. FIG. 2 is a diagram showing an outline of a hardware configuration of a transmission line switching device in this communication system. FIG. 3 is a flowchart showing a first example (Embodiment 1) of a processing operation executed by a CPU in this transmission line switching device. FIG. 4 is a diagram showing a state in which the transmission line of the B system (standby system) is switched to the main transmission line by this transmission line switching device (a state in which the main system is transitioned from the A system to the B system). .. FIG. 5 is a functional block diagram of a main part of the transmission line switching device that executes the processing operation of the first embodiment. FIG. 6 is a flowchart showing a second example (Embodiment 2) of the processing operation executed by the CPU in the transmission line switching device. FIG. 7 is a functional block diagram of a main part of the transmission line switching device that executes the second example of the processing operation of the second embodiment. FIG. 8 is a diagram showing an example of a conventional communication system in which a transmission line adopting a current loop method is duplicated. FIG. 9 is a diagram illustrating a state in which the transmission line of the B system (standby system) is switched to the transmission line of the main system (state before switching) in the conventional communication system. FIG. 10 is a diagram illustrating a state (state after switching) in which the transmission line of the B system (standby system) is switched to the transmission line of the main system in the conventional communication system.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing a main part of a communication system 200 using a transmission line switching device according to an embodiment of the present invention. In the figure, the same reference numerals as those in FIG. 9 indicate the same or equivalent components as those described with reference to FIG. 9, and the description thereof will be omitted.

Hereinafter, in order to distinguish from the transmission line switching device 7 in the conventional communication system 100 shown in FIG. 9, the transmission line switching device 7 in the conventional communication system 100 is indicated by reference numeral 7A, and the communication system 200 of the present embodiment is used. The transmission line switching device 7 is indicated by reference numeral 7B.

In the communication system 200 as well, as in the conventional communication system 100, the switch 5 is in the mark state (the state in which the current easily flows) in the transmission line 3 of the A system, and in the transmission line 4 of the B system. , The switch 6 is in a space state (a state in which current is difficult to flow (2 mA or less)). That is, the transmission line 3 of the A system is the transmission line of the main system, and the transmission line 4 of the B system is the transmission line of the standby system.

FIG. 2 shows an outline of the hardware configuration of the transmission line switching device 7B. The transmission line switching device 7B includes a central processing unit (CPU) 7-1, a random access memory (RAM) 7-2, a read-only memory (ROM) 7-3, and interfaces 7-4, 7-5. And a bus 7-6 connecting them.

A transmission line switching program is installed in the transmission line switching device 7B as a program peculiar to the present embodiment. The CPU 7-1 operates according to the installed transmission line switching program while accessing the RAM 7-2 and the ROM 7-3 by processing the information input via the interface 7-4.

[Embodiment 1]
Hereinafter, a first example (Embodiment 1) of the processing operation executed by the CPU 7-1 according to the transmission line switching program will be described with reference to the flowchart shown in FIG.

In the first embodiment, the CPU 7-1 confirms whether or not there is a message transmission request in the communication terminal device group 2 (step S101), and if there is no message transmission request, the CPU 7-1 is connected to the transmission line 3 of the A system (main system). Check the flowing current IM (IA) (step S102).

Here, a state in which there is no message transmission request in the communication terminal device group 2 (“none” in step S101) and no current is flowing through the transmission line 3 of the A system (main system) (IM = 0 state) is predetermined. When the time T (for example, 5 ms) or longer continues (YES in step S102), the CPU 7-1 determines that the transmission line 3 of the A system (main system) has a disconnection (abnormality) (step S103). The transmission line 4 of the B system (standby system) is switched to the transmission line of the main system (see step S104, FIG. 4). That is, by putting the switch 5 in the space state and the switch 6 in the mark state, the main system is changed from the A system to the B system.

As a result, in the present embodiment, the communication terminal device group 2 is switched to the main transmission line of the B system (standby system) transmission line 4 during the period when there is no message transmission request. Further, the adjustment of the voltage VS'inside the power supply device 1 is also performed during the period when there is no message transmission request in the communication terminal device group 2. Therefore, when the next message is transmitted after switching the transmission line 4 of the B system (standby system) to the main transmission line, it is not necessary to wait until the adjustment of the voltage VS'inside the power supply device 1 becomes stable. Also, the time until communication can be resumed is shortened.

FIG. 5 shows a functional block diagram of a main part of the transmission line switching device 7B that executes the first example (Embodiment 1) of the above-described processing operation. In the first embodiment, the transmission line switching device 7B includes a message transmission request presence / absence confirmation unit 71, an A system transmission line current confirmation unit 72, and a line switching unit 73 as the transmission line switching unit 70.

In the transmission line switching unit 70, the message transmission request presence / absence confirmation unit 71 confirms the presence / absence of the message transmission request in the communication terminal device group 2. The A system transmission line current confirmation unit 72 confirms whether or not the state in which no current is flowing through the transmission line 3 of the A system (main system) continues for a predetermined time T or more. In the line switching unit 73, the A system transmission line current confirmation unit 72 is the A system (main system) in a state where the message transmission request presence / absence confirmation unit 71 confirms that there is no message transmission request in the communication terminal device group 2. When it is confirmed that no current is flowing through the transmission line 3 of the above for a predetermined time T or more, it is determined that the transmission line 3 of the A system (main system) is disconnected, and the B system (standby system). The transmission line 4 of the above is switched to the main transmission line.

In the first embodiment, after the B system (standby system) transmission line 4 is switched to the main system transmission line, the B system transmission line 4 becomes the main system transmission line and the A system transmission line. Reference numeral 3 is a standby transmission line. That is, before switching the B system (standby system) transmission line 4 to the main system transmission line, the A system transmission line 3 is regarded as the first transmission line (main system transmission line) in the present invention, and B The system transmission line 4 is the second transmission line (standby system transmission line) in the present invention, but after switching, the B system transmission line 4 is the first transmission line (standby system transmission line) in the present invention. The main system transmission line), and the A system transmission line 3 becomes the second transmission line (standby system transmission line) in the present invention.

[Embodiment 2]
Next, a second example (Embodiment 2) of the processing operation executed by the CPU 7-1 according to the transmission line switching program will be described with reference to the flowchart shown in FIG.

In the first embodiment, the disconnection of the transmission line 3 of the A system (main system) is detected during the period when there is no message transmission request in the communication terminal device group 2, and the transmission line 4 of the B system (standby system) is mainly used. Added logic to switch to system transmission line.

However, in the first embodiment, when the disconnection of the transmission line 3 of the A system (main system) is detected, the transmission line 4 of the B system (standby system) is immediately switched to the transmission line of the main system. At this time, if the transmission line 4 of the B system (standby system) is disconnected, the disconnection of the transmission line 4 of the B system (standby system) is detected as a disconnection of the main transmission line, and the transition is immediate. It will return to its original state. Therefore, the transition of the main system from the A system to the B system and from the B system to the A system is repeated until the disconnection is improved.

Further, after the power is turned on, the overvoltage protection works (maximum 2 seconds) until the automatic adjustment of the voltage VS'inside the power supply device 1 is completed, and the current does not flow. Therefore, both the transmission line 3 of the A system (main system) and the transmission line 4 of the B system (standby system) are in a state of detecting disconnection. Even in such a case, the transition of the main system from the A system to the B system and from the B system to the A system is repeated, which may lead to a malfunction.

Therefore, in the second embodiment, there is no message transmission request in the communication terminal device group 2 (“none” in step S201), and no current is flowing through the transmission line 3 of the A system (main system) (IM = 0). (For example, 5 ms) or more (YES in step S202), after determining that the transmission line 3 of the A system (main system) has a disconnection (abnormality) (step S203). , It is confirmed whether or not the loop of the transmission line 4 of the B system (standby system) is established (step S204).

Here, only when it is confirmed that the loop of the transmission line 4 of the B system (standby system) is established (YES in step S204), the transmission of the main system of the transmission line 4 of the B system (standby system) Switching to the line is performed (step S205). That is, when it is not confirmed that the loop of the transmission line 4 of the B system (standby system) is established (NO in step S204), the transmission of the main system of the transmission line 4 of the B system (standby system) It does not switch to the line.

As a result, only when the B system (standby system) transmission line 4 is normal, the B system (standby system) transmission line 4 is switched to the main system transmission line, and the main system transition is repeated. Such a problem will not occur.

FIG. 7 shows a functional block diagram of a main part of the transmission line switching device 7B that executes the second example (embodiment 2) of the above-described processing operation. In the second embodiment, the transmission line switching device 7B has a message transmission request presence / absence confirmation unit 71, an A system transmission line current confirmation unit 72, a B system transmission line confirmation unit 74, and a line as the transmission line switching unit 70'. It is provided with a switching unit 75.

In the transmission line switching unit 70', the message transmission request presence / absence confirmation unit 71 confirms the presence / absence of the message transmission request in the communication terminal device group 2. The A system transmission line current confirmation unit 72 confirms whether or not the state in which no current is flowing through the transmission line 3 of the A system (main system) continues for a predetermined time T or more. The B system transmission line confirmation unit 74 confirms whether or not the B system (standby system) transmission line 4 is normal. In the line switching unit 75, the A system transmission line current confirmation unit 72 is the A system (main system) in a state where the message transmission request presence / absence confirmation unit 71 confirms that there is no message transmission request in the communication terminal device group 2. When it is confirmed that no current is flowing through the transmission line 3 of the above for a predetermined time T or more, it is determined that the transmission line 3 of the A system (main system) is disconnected, and the B system transmission line confirmation unit is used. The transmission line 4 of the B system (standby system) is switched to the main transmission line on condition that 74 confirms that the transmission line 4 of the B system (standby system) is normal.

Also in the second embodiment, after the B system (standby system) transmission line 4 is switched to the main system transmission line, the B system transmission line 4 is the main system transmission line and the A system transmission. Line 3 serves as a standby transmission line. That is, before switching the B system (standby system) transmission line 4 to the main system transmission line, the A system transmission line 3 is regarded as the first transmission line (main system transmission line) in the present invention, and B The system transmission line 4 is the second transmission line (standby system transmission line) in the present invention, but after switching, the B system transmission line 4 is the first transmission line (standby system transmission line) in the present invention. The main system transmission line), and the A system transmission line 3 becomes the second transmission line (standby system transmission line) in the present invention.

[Extension of Embodiment]
Although the present invention has been described above with reference to the embodiments, the present invention is not limited to the above embodiments. Various changes that can be understood by those skilled in the art can be made to the structure and details of the present invention within the scope of the technical idea of the present invention.

1 ... Power supply device, 2 ... Communication terminal device group (load), 3 ... A system transmission line, 4 ... B system transmission line, 5, 6 ... Switch, 7 (7B) ... Transmission line switching device, 7-1 ... CPU, 7-2 ... RAM, 7-3 ... ROM, 7-4, 7-5 ... Interface, 70, 70'... Transmission line switching unit, 71 ... Message transmission request presence / absence confirmation unit, 72 ... A system transmission line Current confirmation unit, 73 ... Line switching unit 73, 74 ... B system transmission line confirmation unit, 75 ... Line switching unit, 200 ... Communication system.

Claims (6)

The first transmission line, the second transmission line, the first transmission line, and the second transmission line are used as the main transmission line and the standby transmission line, respectively, and flow to the main transmission line. A group of communication terminal devices configured to transmit a message by changing the value of a current, and an internal voltage that supplies a power supply voltage to the first transmission line and the second transmission line are applied to the load. A transmission that is used in a communication system equipped with a power supply device that is adjusted accordingly, and is configured to switch the second transmission line to the main transmission line when an abnormality occurs in the first transmission line. In the line switching device
If there is no message transmission request in the communication terminal device group and the state in which no current is flowing through the first transmission line continues for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line. A transmission line switching device including a transmission line switching unit configured to switch the second transmission line to a main transmission line. In the transmission line switching device according to claim 1,
The transmission line switching unit is
If there is no message transmission request in the communication terminal device group and the state in which no current is flowing through the first transmission line continues for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line. A transmission line switching device characterized in that the second transmission line is configured to be switched to a main transmission line on condition that the second transmission line is normal. In the transmission line switching device according to claim 1,
The transmission line switching unit is
A message transmission request presence / absence confirmation unit configured to confirm the presence / absence of a message transmission request in the communication terminal device group, and
A first transmission line current confirmation unit configured to confirm whether or not a state in which no current is flowing through the first transmission line has continued for a predetermined time or longer.
In a state where the message transmission request presence / absence confirmation unit confirms that there is no message transmission request in the communication terminal device group, the first transmission line current confirmation unit does not allow current to flow in the first transmission line. When it is confirmed that the state has continued for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line, and the line switching configured to switch the second transmission line to the main transmission line. A transmission line switching device characterized by having a unit. In the transmission line switching device according to claim 1,
The transmission line switching unit is
A message transmission request presence / absence confirmation unit configured to confirm the presence / absence of a message transmission request in the communication terminal device group, and
A first transmission line current confirmation unit configured to confirm whether or not a state in which no current is flowing through the first transmission line has continued for a predetermined time or longer.
A second transmission line confirmation unit configured to confirm whether or not the second transmission line is normal, and a second transmission line confirmation unit.
In a state where the message transmission request presence / absence confirmation unit confirms that there is no message transmission request in the communication terminal device group, the first transmission line current confirmation unit does not allow current to flow in the first transmission line. When it is confirmed that the state has continued for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line, and the second transmission line confirmation unit confirms that the second transmission line is normal. A transmission line switching device including a line switching unit configured to switch the second transmission line to a main transmission line, provided that the second transmission line is switched to the main transmission line. The first transmission line, the second transmission line, the first transmission line, and the second transmission line are used as a main transmission line and a standby transmission line, respectively, and flow to the main transmission line. A group of communication terminal devices configured to transmit a message by changing the value of a current, and an internal voltage that supplies a power supply voltage to the first transmission line and the second transmission line are applied to the load. In a transmission line switching method for switching a second transmission line to a main transmission line when an abnormality occurs in the first transmission line, which is used in a communication system provided with a power supply device adjusted accordingly.
If there is no message transmission request in the communication terminal device group and the state in which no current is flowing through the first transmission line continues for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line. A transmission line switching method comprising a transmission line switching step for switching the second transmission line to a main transmission line. In the transmission line switching method according to claim 5,
The transmission line switching step is
If there is no message transmission request in the communication terminal device group and the state in which no current is flowing through the first transmission line continues for a predetermined time or longer, it is determined that an abnormality has occurred in the first transmission line. A transmission line switching method, characterized in that the second transmission line is switched to a main transmission line on condition that the second transmission line is normal.

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