JP2012095009A - Communication management device and communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption by controlling operation and, as a result, to increase the number of units connectable to a transmission path which receives power supply as compared with a conventional configuration.SOLUTION: A communication management device 5 where a server 3 is connected and a communication management device 6 where a terminal device 4 is connected are connected to a transmission path 7. A power supply device 10 which supplies power to the communication management devices 5, 6 is connected to the transmission path 7. When a transmission destination of a communication signal received from the transmission path 7 is the terminal device 4 connected to the communication management device 6, the communication management device 6 communicates with the terminal device 4 through a transmission path 9. While the communication management device 6 does not communicate with the terminal device 4, the communication management device 6 operates in a receiving standby mode which reduces power consumption.

Description

  The present invention relates to a communication management apparatus that relays communication contents between transmission paths when communication is performed with a plurality of transmission paths having different specifications between the communication apparatuses, and a communication system using the communication management apparatus. Is.

  In general, when communicating between communication devices, the communication content is transmitted via a transmission channel having a physical specification and protocol (hereinafter simply referred to as “specification”) that is different from the transmission channel to which the communication device is connected. There is. Now, a case is assumed in which a transmission path is laid in advance in a building, and communication is performed using a communication device that performs communication using a transmission path having specifications different from that of the transmission path. In this case, since the communication device cannot be directly connected to the transmission line, there is a communication management device that connects the communication device to a transmission line different from the installed transmission line and relays the communication contents between the two transmission lines. I need it.

  In a communication system using this type of communication management apparatus, a communication apparatus (using a transmission path for polling a plurality of terminals (first communication terminals) in which a transmission unit serving as a master unit serves as a slave unit) A configuration in which information is transmitted by a monitoring device or a monitored device is known (see, for example, Patent Document 1). In the communication system described in Patent Document 1, a communication management device (second communication terminal) is connected between a transmission path to which a communication device is connected and a transmission path to which a transmission unit and a terminal are connected. .

  A switch or a load is connected to the terminal connected to one transmission path, and the switch and the load are associated with each other using the identification information of the terminal in the transmission unit. In the transmission unit, polling is performed for each terminal, and when a change in the on / off state of the switch is notified from the terminal, the load is controlled for the terminal connected to the load associated with the switch. Instruct. With such a series of operations, the load is controlled according to the on / off state of the switch.

  In the transmission path to which the transmission unit and the terminal are connected, the transmission unit intermittently sends a communication signal (transmission signal) to poll the terminal, and also supplies power to the terminal using the transmission signal. ing. That is, the terminal supplies power to the internal circuit using the power of the transmission signal. Therefore, the transmission unit also functions as a power supply device for the terminal.

  On the other hand, the communication management apparatus performs communication by superimposing a communication signal (superimposition signal) having a higher frequency than the transmission signal on the transmission signal. That is, the superimposition signal can be transmitted by providing a superposition possible period in which the superposition signal is superposed in a part of the transmission signal.

  Here, when each communication device connected to the communication management device has identification information, communication can be performed using the identification information of the communication device, so the identification information is not required for the communication management device. It is. That is, the communication management device only needs to have a function of converting the signal format between the transmission path to which the communication apparatus is connected and the transmission path to which the transmission unit is connected. Also, since identification information is not required for the communication management device, communication by the communication device can be performed without setting identification information by simply connecting the communication management device to an existing transmission line to which the transmission unit is connected. So it becomes more convenient.

JP 2009-225328 A

  As described above, since the transmission unit can be used as the power supply device in the transmission path to which the transmission unit is connected, the power can be supplied from the transmission unit to the communication management apparatus connected to the same transmission path. It is desirable to do.

  On the other hand, since the communication management device is always operating, the communication management devices on the transmission path to which the transmission unit is connected consumes the power corresponding to the number. On the other hand, since the current capacity that can be supplied from the transmission unit to the transmission path is limited, the number of communication management devices that can be connected to the existing transmission path to which the transmission unit is connected is also limited.

  It is an object of the present invention to provide a communication management device that can reduce power consumption by controlling operations and consequently increase the number of units that can be connected to a transmission path that receives power supply, as compared with a conventional configuration. Furthermore, it aims at providing the communication system using the communication management apparatus.

  In order to achieve the above object, a communication management device according to the present invention transmits a first communication signal through a first transmission path and a second communication signal through a second transmission path. A second communication unit for transmission, a power supply unit to which power is supplied from the power supply device through the first transmission line, a storage unit for storing identification information of the communication device connected to the second transmission line, and a power supply unit When the first communication unit receives the first communication signal while operating in the reception standby mode in which the supply of power to the second communication unit is stopped, the communication device included in the received first communication signal The identification information is collated with the storage unit, and when the received first communication signal includes the identification information of the communication device, the supply of power from the power supply unit to the second communication unit is started to communicate with the communication device. And a processing unit to be performed.

  In order to achieve the above object, a communication system according to the present invention includes a plurality of communication management devices connected to a first transmission line, and each communication management device via a second transmission line. A communication device connected to the communication management device via the first transmission line; and the communication management device communicates with a destination of the first communication signal received from the first transmission line. It is characterized in that it has a function of communicating with a communication device through a second transmission path when it is a device and a function of operating in a reception standby mode for reducing power consumption when not communicating with the communication device.

  The communication management device includes: a first communication unit that transmits a first communication signal through a first transmission path; a second communication unit that communicates with the communication apparatus through a second transmission path; and a first transmission path. The power supply unit that is supplied with power from the power supply unit through the storage unit, the storage unit that stores the identification information of the communication device connected to the second transmission path, and the supply of power from the power supply unit to the second communication unit is stopped. When the first communication unit receives the first communication signal while operating in the reception standby mode, the identification information of the communication device included in the received first communication signal is collated with the storage unit, and the received first It is preferable to include a processing unit that starts communication with the communication device by starting the supply of power from the power supply unit to the second communication unit when the communication signal includes identification information of the communication device.

  In this case, the communication management device is connected to the second transmission line at a timing that is set to be appropriately different in each communication management device at least during startup and every predetermined time after startup. It is preferable to further include a connection management unit that collects identification information of the communication device and stores the collected identification information in the storage unit.

  When the communication management device detects the first communication signal transmitted from another communication management device in the first communication path, the second communication management device sets the second communication signal at a timing that is appropriately set differently in each communication management device. It is desirable to further include a connection management unit that collects identification information of the communication devices connected to the transmission path and stores the collected identification information in the storage unit.

  The first communication signal transmits a packet having a communication content and a termination after the identification information of the transmission destination, and the processing unit stores the identification information of the communication device included in the packet received by the first communication unit. When the coincidence with the identification information stored in the unit is confirmed, it is preferable to pass the received packet to the second communication unit up to the end.

  The first communication signal transmits a packet having communication contents and termination after the identification information of the transmission destination, and the processing unit is a packet received by the first communication unit is a broadcast packet for the communication device In addition, it is preferable to operate in the normal communication mode at a timing set differently in each communication management device, and to transmit the received packet from the second communication unit to the communication device as a second communication signal.

  Some of the plurality of communication management devices are connected to a server device as a communication device via a second transmission path, and the rest of the plurality of communication management devices are connected to a terminal device as a communication device via a second transmission channel. A communication system in which a server device and a terminal device communicate with each other via a communication management device. The communication management device to which the server device is connected is stored in a storage unit of the communication management device to which the terminal device is connected. It is preferable to collect the identification information of the terminal device that is being collected, and when the server device transmits a request to the terminal device, if the collected identification information is duplicated, the request is not transmitted.

  According to the configuration of the present invention, the power consumption is reduced by controlling the operation of the communication management device, and as a result, the number of communication management devices that can be connected to the transmission path that receives the power supply is increased compared to the conventional configuration. The effect of being able to be obtained.

It is a block diagram which shows embodiment. It is a block diagram which shows the communication management apparatus used for the same as the above. It is operation | movement explanatory drawing same as the above. It is operation | movement explanatory drawing same as the above. It is a figure which shows the example of the packet used for the same as the above. It is a figure which shows the other example of the packet used for the same as the above. It is operation | movement explanatory drawing same as the above. It is a block diagram which shows the whole structure same as the above. It is a figure which shows the example of the transmission signal used with the structure shown in FIG.

  As shown in FIG. 8, the communication system described below as an embodiment includes one transmission in communication between the transmission unit 1 and the terminal device 2 and communication between the server device 3 and the terminal device 4. Multiplexing that shares the path (first transmission path) 7 is performed. Although the transmission line 7 is assumed to be a two-wire type, the transmission line 7 may be constituted by three or more lines.

  One transmission unit 1 and one server device 3 are normally provided for the transmission line 7, and a plurality of terminal units 2 and terminal devices 4 are provided for the transmission line 7. Further, in order to multiplex two types of communications, the communication management devices 5 and 6 are connected to the transmission line 7, and the server device 3 and the terminal device 4 are connected to the communication management devices 5 and 6 with the transmission lines 8 and 9. Connected through. In many cases, a plurality of terminal devices 4 are connected to each transmission line 9. The transmission paths 8 and 9 are assumed to be the RS485 standard, but the transmission paths 8 and 9 such as the Ethernet (registered trademark) or the RS232C standard may be used.

  The communication signal transmitted through the transmission path 7 in the communication between the transmission unit 1 and the terminal device 2 and the communication signal transmitted through the transmission path 7 in the communication between the server apparatus 3 and the terminal apparatus 4 are physical specifications. And the protocol is different. The former communication signal is a pulse width modulated bipolar rectangular wave signal, and the latter communication signal uses a signal obtained by modulating a carrier wave having a frequency higher than that of the former communication signal. Hereinafter, the former communication signal is referred to as “transmission signal”, and the latter communication signal is referred to as “superimposition signal”.

  Note that it is desirable that the transmission unit 1 and the terminal device 2 are each provided with an impedance matching device between the transmission line 7. The impedance matching device is a circuit device that passes a transmission signal and has a high impedance with respect to the superimposed signal. By providing the impedance matching device, the attenuation of the superimposed signal is suppressed even when the transmission line 7 is long. be able to.

  A transmission signal used in communication between the transmission unit 1 and the terminal device 2 has a predetermined format, and the transmission unit 1 intermittently sends it to the transmission path 7. Each terminal device 2 has identification information (address). By including the identification information of each terminal device 2 in the transmission signal transmitted by the transmission unit 1, each terminal device 2 is designated and transmitted from the transmission unit 1. An instruction to the terminal device 2 is given. That is, an instruction can be individually given from the transmission unit 1 to each terminal 2 by time division multiplexing. The transmission signal is provided with a period for notifying the transmission unit 1 of information from the terminal 2.

  The terminal 2 is connected to a monitoring terminal that receives a monitoring input from a switch or a sensor (not shown) and requests the transmission unit 1 to control the load, and a load (not shown). There are two types of control terminals that control the load according to the instructions.

  The transmission unit 1 includes a relationship table that associates a switch or sensor (hereinafter referred to as “switch” unless otherwise specified) with a load. By registering the relationship between the switch and the load in the relationship table in advance, the transmission unit 1 controls the load associated with the switch in the relationship table in accordance with the operation of the switch (or change in sensor output). To do. The relation table may include the contents of load control for switch operation.

  When it is possible to connect a plurality of switches and loads to the terminal device 2, in association with the switches and loads in the relationship table, in addition to the identification information of the terminal device 2, The circuit number given for each port to which is connected is used. That is, the switch and the load are individually identified by using the identification information and the circuit number of the terminal device 2.

  More specifically, as shown in FIG. 9, the transmission signal 30 is a bipolar (± 24 V) signal having a synchronization pulse 31, a transmission period 32, a return period 33, an interruption period 34, and a short-circuit detection period 35. Is used. As described above, the transmission unit 1 intermittently sends the transmission signal 30. Therefore, there is a pause period 36 between frames of the transmission signal 30.

  The synchronization pulse 31 indicates the start of the frame of the transmission signal, and has two periods with different voltage polarities. The voltage polarity changes from positive to negative within the period of the synchronization pulse 31. The transmission period 32 is a period in which an instruction is transmitted from the transmission unit 1 to the terminal device 2, and mode information indicating the type of the transmission signal 30, identification information for individually specifying the terminal device 2, and an instruction for each circuit number. Control information indicating the contents of the. The return period 33 is a period in which information is notified from the terminal device 2 to the transmission unit 1 and is a period in which the transmission unit 1 waits without transmitting a signal.

  The interruption period 34 is a period for detecting an interruption signal output from the terminal device 2, and the short circuit detection period 35 is a period for detecting a short circuit of the transmission line 7. The interruption period 34 and the short circuit detection period 35 are paired with the synchronization pulse 31, and the synchronization pulse 31 is provided with a period corresponding to the interruption period 34 and the short circuit detection period 35.

  On the other hand, if each terminal device 2 includes its own identification information in the identification information included in the transmission period 32 of the transmission signal 30 received via the transmission path 7, the control information included in the transmission period 32 is included. Is used for each circuit number. That is, in the transmission signal 30 received by the control terminal, the control content for the load of each circuit number is included in the control information, so the load of each circuit number is controlled according to the control content. The switch operation in the monitoring terminal and the load control result in the control terminal are sent back to the transmission unit 1 as a current mode signal in synchronization with the return period 33. The current mode signal is transmitted using a binary value due to a current change between a state where an appropriate low impedance is connected between the lines of the transmission line 7 and a state where the line of the transmission line 7 is opened.

  The transmission unit 1 always performs polling to sequentially access the terminal device 2 by cyclically changing the identification information of the terminal device 2 included in the transmission signal 30. At the time of constant polling, the terminal device 2 whose identification information included in the transmission signal 30 matches the identification information of its own, operates if the control information is included in the transmission signal 30, and operates. The operating state is returned to the transmission unit 1 in the return period 33.

  By the way, when receiving a monitoring input from the switch, the monitoring terminal generates an interrupt signal on the transmission line 7 in synchronization with the interrupt period 34 of the transmission signal 30. When the transmission unit 1 detects this interrupt signal, the transmission unit 1 searches for the terminal device 2 that generated the interrupt signal, and accesses the terminal device 2 to obtain the identification information of the terminal device 2.

  When the identification information of the terminal 2 that has generated the interrupt signal is acquired by the transmission unit 1, the transmission unit 1 designates the identification information and causes the terminal 2 to return a monitoring input. Based on the monitoring input returned from the terminal device 2, the transmission unit 1 generates a transmission signal including control information for the terminal device 2 provided with a load previously associated with the switch (monitoring input) by the relation table. To the transmission line 7. Therefore, the load is controlled in accordance with a request from the terminal device 2 that generated the interrupt signal (switch operation or the like).

  As described above, the transmission unit 1 always performs polling at all times, accesses all terminals 2 in order, and receives an interrupt signal from any one of the terminals 2 (monitoring terminal). The terminal 2 that generated the message is accessed and a request from the terminal 2 is received. In this way, polling is always performed, and when an interrupt signal is generated, an operation for preferentially processing a request from the terminal device 2 that generated the interrupt signal is called interrupt polling.

  The terminal device 4 is, for example, a measuring device that measures the amount of power consumed by the load, a measuring device that measures the temperature during operation of the load, and the information acquired by the terminal device 4 is collected in the server device 3. The In many cases, information acquired by the terminal device 4 is collected by the server device 3 in response to a request from the server device 3.

  The communication between the server device 3 and the terminal device 4 uses a packet 20 including a transmission source address 22, a communication content 23, and a termination 24 after the transmission destination address 21, as shown in FIG. Further, the source address 22 may be omitted as shown in FIG. Alternatively, as shown in FIG. 6A, the destination address 21 is used for the packet 20 going from the server device 3 to the terminal device 4, and the packet 20 going from the terminal device 4 to the server device 3 is shown in FIG. As in b), the source address 22 may be used.

  In order to transmit the packet 20 described above using the transmission path 7, a superimposed signal that is superimposed on the transmission signal 30 and transmitted through the transmission path 7 is used. That is, a packet 20 including a request from the server device 3 to the terminal device 4 is converted into a superimposed signal by the communication management device 5 connected to the server device 3 and then transmitted to the communication management device 6 through the transmission path 7. . Further, the communication management device 6 converts the superimposed signal into a communication signal including a request to the terminal device 4. On the other hand, when the communication management device 6 collects information from the terminal device 4, the communication management device 6 converts a packet including the collected information into a superimposed signal and transmits it to the communication management device 5 through the transmission path 7. Further, the communication management device 5 converts the received superimposed signal into a communication signal to be transferred to the server device 3 and visualizes it in the server device 3.

  The superimposed signal transmitted through the transmission path 7 is superimposed on the transmission signal 30 described above. Specifically, the superimposed signal is transmitted in the superimposable period appropriately selected from the synchronization pulse 31 of the transmission signal 30, the return period 33, the interrupt period 34, the short-circuit detection period 35, and the pause period 36. When an impedance matching device for separating the superimposed signal from the transmission signal is provided between the transmission unit 1 and the terminal device 2 and the transmission line 7, the transmission unit 1 and the terminal device 2 are not affected by the superimposed signal. The transmission signal 30 can be transmitted between the transmission unit 1 and the terminal 2.

  On the other hand, the communication management devices 5 and 6 function as an interface or a modem for connecting to the transmission line 7 with respect to the server device 3 and the terminal device 4. By providing such communication management devices 5 and 6, the transmission path 7 can be shared in the transmission of two types of communication signals. That is, in order to use the transmission path 7 as a path for communication between the server apparatus 3 and the terminal apparatus 4, communication signals are converted using the communication management apparatuses 5 and 6 connected to the transmission path 7. In other words, a path that passes through the communication management apparatuses 5 and 6 and the transmission path 7 is employed for communication between the server apparatus 3 that is a communication apparatus and the terminal apparatus 4.

  In this case, the server device 3 and the terminal device 4 need identification information for communication, but the communication management devices 5 and 6 do not need identification information for communication. Therefore, the communication management device 6 always operates to wait for reception of a communication signal passing through the transmission path 7. In addition, when the terminal device 4 is a measuring device, the use which collects the information which the measuring device measured by communicating between the server device 3 and the terminal device 4 with the server device 3 can be considered. Depending on the type, the communication management devices 6 may communicate with each other.

  Since the transmission signal 30 for performing communication between the transmission unit 1 and the terminal device 2 is bipolar and is always polled, power is always supplied to the transmission line 7 by the transmission signal 30. . Therefore, by using the transmission signal 30, power can be supplied not only to the terminal device 2 but also to the communication management devices 5 and 6. However, since there is an upper limit to the power supplied by the transmission unit 1, the power that can be supplied simultaneously from the transmission unit 1 to the terminal 2 and the communication management devices 5 and 6 connected to the transmission path 7 is limited.

  Now, considering only communication performed between the server apparatus 3 and the terminal apparatus 4, the transmission unit 1 is regarded as a power supply apparatus that supplies power to the communication management apparatuses 5 and 6, and the configuration of FIG. Simplify as shown. The power supply device 10 in FIG. 1 corresponds to the transmission unit 1 in FIG.

  Here, the upper limit value of the current that can be supplied to the transmission line 7 by the power supply device 10 is Q [mA], and the current consumed by the communication management device 5 when the communication management device 5 communicates with the server device 3 is r1 [mA. The current consumed by the communication management device 6 when the communication management device 6 communicates with the terminal device 4 is assumed to be r2 [mA]. Under this condition, the number N of communication management devices 5 and 6 connectable to the transmission line 7 is N = 1 + int [(Q−r1) / r2]. int [X] means the integer part of X.

  For example, the maximum value of the current supplied from the power supply device 10 to the transmission line 7 is 200 [mA], the current consumed by the communication management device 5 is 10 [mA], and the current consumed by the communication management device 6 is 15 [mA]. To do. In this case, N = 1 + int [(200−10) / 15] = 13. That is, the maximum number of communication management apparatuses 6 that connect the terminal apparatus 4 can be connected to the transmission path 7 is 12. That is, when the conventional configuration is adopted, the maximum number of communication management devices 6 that can be connected to the transmission path 7 is 12 under the above-described conditions.

  Hereinafter, a technique for increasing the maximum number of communication management devices 6 that can be connected to the transmission path 7 will be described with reference to FIG.

  As shown in FIG. 2, the communication management device 6 to which the terminal device 4 is connected has a first communication unit 61 that transmits a communication signal through the transmission line 7 and a second communication unit that communicates with the terminal device 4 through the transmission line 9. And a communication unit 62. The first communication unit 61 transmits a packet transmitted between the server device 3 and the terminal device 4 by superimposing a superimposed signal on a transmission signal transmitted through the transmission path 7, and is superimposed on the transmission signal. The packet is received by separating the superimposed signal. Further, a process for determining whether or not to transmit a packet between the first communication unit 61 and the second communication unit 62 between the first communication unit 61 and the second communication unit 62. A portion 60 is provided. Further, the communication management device 6 includes identification information (hereinafter, referred to as a power supply unit 63) to which power is supplied from the power supply device 10 through the transmission path 7 and the terminal device 4 connected to the communication management apparatus 6 via the transmission path 9. And a storage unit 64 for storing “address”.

  The processing unit 60 operates in a normal communication mode in which power is supplied from the power supply unit 63 to the second communication unit 62 and a reception standby mode in which supply of power from the power supply unit 63 to the second communication unit 62 is stopped. Is provided. The processing unit 60 and the first communication unit 61 are supplied with power from the power supply unit 63 regardless of the operation mode of the processing unit 60.

  The processing unit 60 always selects the reception standby mode, and when the first communication unit 61 receives the superimposed signal in the reception standby mode, the address of the terminal device 4 included in the received packet extracted from the superimposed signal is set. It collates with the address memorize | stored in the memory | storage part 64. FIG. When the collated address is stored in the storage unit 64, the processing unit 60 starts the supply of power from the power supply unit 63 to the second communication unit 62 and performs communication with the terminal device 4. That is, when the processing unit 60 receives a packet including the content of communication with the terminal device 4 in the reception standby mode, the processing unit 60 shifts to the normal communication mode and causes the second communication unit 62 to supply power. The processing unit 60 also has a function of converting a protocol between the first communication unit 61 and the second communication unit 62.

  The communication management device 5 to which the server device 3 is connected has the same basic configuration as the communication management device 6. That is, a processing unit, a first communication unit, a second communication unit, a power supply unit, and a storage unit are provided. These configurations correspond to the processing unit 60, the first communication unit 61, the second communication unit 62, the power supply unit 63, and the storage unit 64 in the communication management device 6, respectively. However, since the server device 3 issues a request to the terminal device 4 in normal operation and collects information by a response from the terminal device 4, the processing unit of the communication management device 5 does not perform the operation in the reception standby mode. Further, the storage unit in the communication management device 5 is used for storing the address of the server device 3.

  As is clear from the above-described operation, the communication management device 6 is always operating in the reception standby mode, and the supply of power to the second communication unit 62 is stopped. In normal operation, since the server device 3 transmits a request for each terminal device 4, among the plurality of communication management devices 6 connected to the transmission path 7, the communication management device 6 that shifts to the normal communication mode is 1 It becomes one by one.

  Now, the upper limit value of the current that can be supplied to the transmission line 7 by the power supply device 10 (see FIG. 1) is Q [mA], and the current consumed by the communication management device 5 when the communication management device 5 communicates with the server device 3. Let r1 [mA]. Further, the current consumed when one communication management device 6 operates in the normal communication mode is r2 [mA], and the current consumed when operated in the reception standby mode is r3 [mA]. Under this condition, the number N of communication management devices 5 and 6 connectable to the transmission path 7 is N = 2 + int [(Q−r1−r2) / r3]. int [X] means the integer part of X.

  For example, the maximum value of the current supplied from the power supply device 10 to the transmission line 7 is 200 [mA], and the current consumed by the communication management device 5 is 10 [mA]. The current consumed by the communication management apparatus 6 in the normal communication mode is 15 [mA], and the current consumed by the communication management apparatus 6 in the reception standby mode is 10 [mA]. In this case, N = 2 + int [(200-10-15) / 10] = 19. That is, the maximum number of communication management devices 6 to which the terminal device 4 is connected is 18 that can be connected to the transmission path 7. That is, under the same conditions, it is possible to increase the number of communication management devices 6 connectable to the transmission path 7 as compared with a case where the communication management device 6 does not have a reception standby mode.

  By the way, in order to store the address of the terminal device 4 in the storage unit 64 provided in the communication management device 6, the terminal device 4 connected to each communication management device 6 is manually checked, and the terminal device 4 is manually connected. It is conceivable to store the address. However, when a large number of terminal devices 4 are provided and a plurality of terminal devices 4 are connected to a plurality of communication management devices 6, respectively, the address of the terminal device 4 is manually stored for each storage unit 64. It is inconvenient to memorize the memory because it requires a lot of labor. In particular, when an address is manually stored in the storage unit 64 when a change such as deletion or addition of the terminal device 4 is performed, the possibility of erroneous input increases and maintenance of the communication system becomes difficult.

  Therefore, by communicating with the terminal device 4 connected via the transmission line 9 for each communication management device 6, the address of the terminal device 4 is automatically collected, and the collected address is automatically stored in the storage unit 64. It is desirable to memorize automatically. Therefore, the processing unit 60 includes a connection management unit 601 that collects addresses of the terminal devices 4 connected via the transmission path 9. The timing at which the connection management unit 601 collects the address of the terminal device 4 is basically when the communication management device 6 is activated, but the connection management unit 601 automatically detects deletion or addition of the terminal device 4. 601 collects the address of the terminal device 4 every predetermined time even after activation.

  Here, in order for the processing unit 60 to collect the address of the terminal device 4, it is necessary to supply power from the power supply unit 63 to the second communication unit 62. Therefore, the power consumption of the communication management device 6 that collects the addresses of the terminal devices 4 increases. Therefore, in each communication management device 6, the timing for collecting the address of the terminal device 4 is appropriately changed.

  For example, the timing for collecting the address of the terminal device 4 after the time calculated from the activation of the communication management device 6 after the time is calculated from an address individually set in the communication management device 6 with an appropriate calculation rule Just start. Alternatively, each communication management device 6 may generate a random number, and calculate the start time of the time zone in which address collection is started from the random number according to an appropriate calculation rule. Here, as long as the current capacity of the power supply device 10 does not exceed the maximum value of the current supplied to the transmission line 7, it is allowed that the time zones for collecting the addresses of the terminal devices 4 are overlapped in a plurality of communication management devices 6. Is done.

  Although the above operation is described at the time of activation, the same operation is repeated every predetermined time after the activation. That is, the time is measured in each communication management device 6, and the start time of the time zone in which the address of the terminal device 4 is collected is determined at predetermined time intervals by the same operation as at the time of activation. Since the address of the terminal device 4 is acquired not only at startup but also every predetermined time after startup, it is not necessary to restart the communication system when the terminal device 4 is deleted or added, and convenience can be improved. .

  The time interval for calculating the time zone for acquiring the address of the terminal device 4 is managed not by each communication management device 6 but by another device such as the server device 3 and collects the address of the terminal device 4 in each communication management device 6. You may notify the time interval to do. Alternatively, the collection start timing for each communication management device 6 is determined in another device such as the server device 3 so that the timing of collecting the address of the terminal device 4 in each communication management device 6 is different, and communication management is performed. You may notify the apparatus 6 of time separately.

  The processing of collecting the address of the terminal device 4 and storing it in the storage unit 64 when the communication management device 6 is activated is collectively shown in FIG. The connection management unit 601 determines whether the address of the terminal device 4 is stored in the storage unit 64 at the time of activation (S1). When the address is stored in the storage unit 64 (S1: yes), this process is terminated. When the address is not stored in the storage unit 64 (S1: no), the start of the time period for collecting addresses The time is determined and waits until the start time (S2).

  Thereafter, power is supplied from the power supply unit 63 to the second communication unit 62, an address is designated, and a response is requested from each terminal device 4 (S3). If there is a response from the terminal device 4 (S4: yes), this address is stored in the storage unit 64 (S5). By performing the process of confirming the response from the terminal device 4 for all addresses (S6), the terminal device 4 connected to the communication management device 6 via the transmission path 9 can be stored in the storage unit 64. it can. When a response is requested from the terminal device 4 (S3), if there is no response from the terminal device 4 (S4: no), the response from the terminal device 4 is confirmed by designating the next address (S6). .

  In the above-described operation, the start time of the time zone for collecting the address of the terminal device 4 is shifted in each communication management device 6, but each time the presence or absence of connection of the terminal device 4 is confirmed for one address, the next address The waiting time for confirming the presence or absence may be changed at random. In this case, each communication management device 6 does not vary the start time of the time zone for collecting the address of the terminal device 4, but irregularly sets the time interval for verifying the presence or absence of one address in each communication management device 6. Will change.

  In this operation, as shown in FIG. 7, the communication management device 6 sequentially transmits the addresses (address 1, address 2,...) Of the terminal device 4 and requests a response from the terminal device 4. When the terminal device 4 having the address is connected to the transmission line 9, a response from the terminal device 4 is obtained. Here, each time an address is transmitted once, the waiting time until the next address is transmitted is randomly changed regardless of whether or not there is a response from the terminal device 4. With this operation, the time intervals for sending addresses become unequal, and the time at which each communication management device 6 operates the second communication unit 62 can be shifted.

  That is, there is a difference in the timing of collecting the addresses of the terminal devices 4 in each communication management device 6, and the total power consumption of the communication management device 6 can be suppressed. In other words, the current consumed by the communication management devices 5 and 6 connected to the transmission line 7 can be prevented from exceeding the current capacity allowed for the power supply device 10. Also in this operation, within the allowable range of the current capacity of the power supply device 10, the periods for collecting the addresses of the terminal devices 4 in the plurality of communication management devices 6 may overlap.

  By the way, in the communication management apparatus 6, the operation | movement which transmits the communication signal which responds to the communication management apparatus 5 connected to the server apparatus 3 and the operation | movement which acquires the address of the terminal device 4 may not be performed simultaneously. it is obvious. Therefore, during the period in which the other communication management device 6 is transmitting a communication signal that responds to the communication management device 5, the second communication unit 62 is not supplied with power in the other communication management device 6. It can be seen that the device is operating in a state where the power consumption is relatively small.

  From this, it can be said that the period during which the other communication management device 6 transmits a communication signal in response to the communication management device 5 is a suitable timing for performing the operation of acquiring the address of the terminal device 4. Therefore, the connection management unit 601 of each communication management device 6 monitors the communication signal transmitted through the transmission path 7 by the first communication unit 61, and when the communication signal directed to the communication management device 5 is detected, the address is determined. You may determine the start time of the time slot | zone to collect.

  In this operation, since the address of the terminal device 4 is collected by the communication management device 6 at the time of the response from the terminal device 4 to the server device 3, it is not necessary to time the time to collect the address. Further, it is not necessary to restart the communication system in order to collect the addresses of the terminal devices 4 with the deletion or addition of the terminal devices 4.

  In the operation described above, the address of the terminal device 4 is stored in the storage unit 64 of the communication management device 6. However, in the storage unit of the communication management device 5, it is necessary to store the address of the server device 3 in the storage unit. . The storage unit of the communication management device 5 stores the address of the server device 3 when the second communication unit receives a communication signal including a request for the terminal device 4 from the server device 3 at the time of starting the communication system. You may memorize in a part.

  By the way, in the operation | movement mentioned above, the case where the server apparatus 3 does not transmit a request | requirement simultaneously with respect to the terminal device 4 connected to the different communication management apparatus 6 is assumed. However, in practice, a communication signal may be transmitted by broadcast from the communication management device 5 connected to the server device 3 to the communication management device 6 to which the terminal device 4 is connected. In preparation for such a case, the processing unit 60 determines whether a communication signal from the communication management device 5 is broadcast or unicast, and appropriately transmits a request to the terminal device 4 at the time of broadcast. A transmission management unit 602 for differentiating is provided.

  The transmission management unit 602 determines the timing for transmitting a request to the terminal device 4 by an operation similar to the operation of the connection management unit 601. That is, the start time of the time zone in which the request from the server device 3 is transmitted to the terminal device 4 is determined by an appropriate calculation rule, or the time interval for transmitting the request from the server device 3 to the terminal device 4 is unequal. To do.

  By performing the above-described operation on the broadcast communication signal in the transmission management unit 602, it is possible to prevent the communication management devices 6 from simultaneously transmitting requests to the terminal device 4 with respect to the broadcast communication signal. it can. That is, the communication management device 6 can be operated within the range of the current capacity of the power supply device 10.

  The communication signal received by the communication management device 6 is monitored by the processing unit 60 and is normally delivered to the second communication unit 62 in units of received packets regardless of whether it is unicast or broadcast. Therefore, the processing unit 60 needs a buffer for storing received packets as a unit.

  On the other hand, the processing unit 60 is not provided with a buffer, and when the received packet is unicast and the transmission destination address 21 in the received packet exists in the storage unit 64, the packet is transmitted to the second communication. A configuration for outputting to the unit 62 may be adopted. In this case, since the processing unit 60 does not require a buffer, it is possible to shorten the time until the request from the server device 3 is delivered to the terminal device 4. As described above, since it is necessary to distribute the time for handing over the request from the server device 3 to the terminal device 4 for the broadcast packet, a buffer for waiting for the time is necessary.

  In the configuration described above, it is determined whether the communication signal received by the communication management device 6 to which the terminal device 4 is connected is a communication signal having the terminal device 4 as a transmission destination. Not only this operation but also the communication management device 5 connected to the server device 3 is considered not to send unnecessary communication signals (superimposed signals), it is possible to eliminate the wasteful operation of the communication management device 6. .

  Therefore, prior to transmitting a request from the server device 3 to the terminal device 4 via the communication management device 6, the processing unit of the communication management device 5 of the terminal device 4 connected to each communication management device 6. Performs operations to collect addresses. This operation is desirably performed every predetermined time, but may be performed before the communication signal is transmitted from the communication management device 5 to the communication management device 6. Alternatively, the address of the terminal device 4 is set to the communication management device 6 immediately after the communication signal is transmitted from the first communication unit to the transmission path 7 and immediately after the communication signal is transmitted from the second communication unit to the transmission path 8. May be collected from.

  Here, when the processing unit of the communication management device 5 detects that the addresses of the terminal devices 4 are duplicated in the plurality of communication management devices 6, the processing unit converts the packet having the corresponding terminal device 4 as a transmission destination into a superimposed signal. And sending out is prohibited. This operation can prevent a plurality of communication management devices 6 from communicating with the terminal device 4 at the same time. At this time, it is desirable that the communication management device 5 notifies the server device 3 that the address of the terminal device 4 is set in an overlapping manner. In addition, about the communication system which accept | permits duplication of the address of the terminal device 4, when the address of the terminal device 4 is duplicated, with respect to the communication management apparatus 6 to which each terminal device 4 with duplicate address is connected, A communication signal may be transmitted at a different time.

  In the above description, the communication management devices 5 and 6 are described separately in order to explain the difference in function between the communication management device 5 to which the server device 3 is connected and the communication management device 6 to which the terminal device 4 is connected. ing. However, in practice, the communication management device 5 and the communication management device 6 have the same configuration, and the server device 3 is connected or the terminal device 4 is connected depending on the communication state in the second communication unit. Each operation is performed by recognizing whether or not That is, which operation of the communication management device 5 or the communication management device 6 is performed is determined by communication with a device connected via the transmission lines 8 and 9.

  The operation of the communication management apparatus is summarized in FIG. FIG. 4 shows an operation for selecting which of the communication management device 5 and the communication management device 6 functions. In the following description, the reference numerals shown in FIG. 2 are adopted, but the description of the communication management apparatus 6 is not intended. For convenience, the reference numerals in FIG. 2 are used to show the configuration of the communication management apparatus. Used.

  In the communication management device, first, after starting processing (such as processing for collecting the address of the terminal device 4 shown in FIG. 3) (S1), the first communication unit 61 and the second communication unit 62 The presence or absence of a communication signal is confirmed (S2, S3). If there is a communication signal in the first communication unit 61 (S3: yes) and the request is for collecting the address of the terminal device 4 (S4: yes), the address of the terminal device 4 is read from the storage unit 64 and the communication management device 5 is returned (S5).

  If the communication signal received by the first communication unit 61 does not request address collection (S4: no), the destination address included in the received packet is confirmed (S6). Here, if the transmission destination address is broadcast, each communication management device 6 performs processing for changing the time of communication with the terminal device 4 (S7). If the transmission destination address is registered in the storage unit 64, the received packet is transferred to the second communication unit 62 (S8).

  Here, it is determined whether or not the communication management device is operating as the communication management device 5 connected to the server device 3 (S9). If the communication management device is the communication management device 5, the server is passed through the first communication unit 61. The apparatus 3 is requested to return an address (S10), and after confirming a response to this request (S11), the contents of the storage unit 64 are updated (S12). If the communication management device is not the communication management device 5 connected to the server device 3 (S9: no), the process returns to step S2, and the first communication unit 61 and the second communication unit 62 receive communication signals. Wait.

  On the other hand, in step S6, if the destination address is not registered in the storage unit 64 but not broadcast, the received packet is discarded (S13). If the communication management device is not operating as the communication management device 5 connected to the server device 3 (S14: no), and it is time to collect the address of the terminal device 4 (S15: yes), the second The address of the terminal device 4 is collected through the communication unit 62 (S16). If the communication management device 5 connected to the server device 3 is operating (S14: yes) or if it is not time to collect the address of the terminal device 4 (S15: no), the process returns to steps S2 and S3. The first communication unit 61 and the second communication unit 62 wait for reception of communication signals.

  By the way, when a communication signal is detected by the second communication unit 62 in step S2 (S2: yes), the source address of the received packet is confirmed (S17). Here, if the packet is received from the server device 3 (S17: yes), the communication management device 5 connected to the server device 3 is operated, and the address of the server device 3 is stored in the storage unit 64. (S18).

  Next, the duplication of the address of the terminal device 4 is confirmed by collating with the storage unit 64 (S19), and if the destination address of the received packet is duplicated (S19: yes), the packet is discarded (S20). . On the other hand, if duplication of the address is not detected (S19: no), the packet is transferred to the first communication unit 61 (S21), and the address of the terminal device 4 is requested through the first communication unit 61 (S22). That is, the communication management device 5 requests the address of the terminal device 4 from the communication management device 6. By receiving a response to this request (S23), the contents of the storage unit 64 are updated in the communication management device 5 connected to the server device 3 (S24).

  On the other hand, when a packet received from the terminal device 4 is detected in step S17 (S17: no), the address of the terminal device 4 connected to the communication management device is stored in the storage unit 64 (S25) and received. The packet is transferred to the first communication unit 61 (S26).

  Note that the packet 20 shown in FIG. 6 may be used when the communication management device 5 connected to the server device 3 and the communication management device 6 connected to the terminal device 4 are discriminated. That is, when the packet 20 of FIG. 6B is received as a response after the packet 20 of FIG. 6A is transmitted, it can be determined that the communication management device 5 is connected to the server device 3. Therefore, when a pair of transmission of the packet 20 including only the transmission destination address 21 and reception of the packet 20 including only the transmission source address 22 is detected by the communication management apparatus, it is connected to the server apparatus 3. Just judge. In this case, it functions as the communication management device 6 connected to the terminal device 4 by default.

3 Server device (communication device)
4 Terminal equipment (communication equipment)
DESCRIPTION OF SYMBOLS 5 Communication management apparatus 6 Communication management apparatus 7 (1st) transmission line 8 (2nd) transmission line 9 (2nd) transmission line 10 Power supply device 60 Processing part 61 1st communication part 62 2nd communication part 63 power supply unit 64 storage unit 601 connection management unit

Claims (8)

  A first communication unit that transmits a first communication signal through a first transmission line, a second communication unit that transmits a second communication signal through a second transmission line, and a power source through the first transmission line A power supply unit to which power is supplied from the device, a storage unit for storing identification information of the communication device connected to the second transmission path, and supply of power from the power supply unit to the second communication unit are stopped. When the first communication unit receives the first communication signal while operating in the reception standby mode, the identification information of the communication device included in the received first communication signal is collated with the storage unit, A processing unit that starts supply of power from the power supply unit to the second communication unit and performs communication with the communication device when the received first communication signal includes identification information of the communication device; A communication management device comprising:   A plurality of communication management devices connected to the first transmission line; a communication device connected to each of the communication management devices via a second transmission line; and the communication management device through the first transmission line. A power supply apparatus that supplies power to the communication management apparatus, wherein the communication management apparatus transmits the first communication signal received from the first transmission path through the second transmission path when the transmission destination of the first communication signal is the communication apparatus. A communication system comprising: a function of communicating with a communication device; and a function of operating in a reception standby mode for reducing power consumption when not communicating with the communication device.   The communication management device includes: a first communication unit that transmits a first communication signal through the first transmission path; a second communication unit that communicates with the communication apparatus through the second transmission path; A power supply unit to which power is supplied from the power supply device through a first transmission line, a storage unit for storing identification information of the communication device connected to the second transmission line, and the second from the power supply unit When the first communication unit receives the first communication signal while operating in the reception standby mode in which the supply of power to the communication unit is stopped, the communication device included in the received first communication signal The identification information is collated with the storage unit, and when the received first communication signal includes the identification information of the communication device, supply of power from the power supply unit to the second communication unit is started to perform the communication. A processing unit for communicating with the apparatus. Communication system according to claim 2, symptoms.   The communication management device is connected to the second transmission line at a timing that is set to be appropriately different in each communication management device at least at the time of start-up and every predetermined time after the start-up. The communication system according to claim 3, further comprising a connection management unit that collects identification information of the communication device and stores the collected identification information in the storage unit.   When the communication management device detects the first communication signal transmitted from the other communication management device in the first communication path, the communication management device is set to be appropriately different in each communication management device. 4. The communication according to claim 3, further comprising: a connection management unit that collects identification information of the communication device connected to the second transmission path and stores the collected identification information in the storage unit. system.   The first communication signal transmits a packet having communication content and termination after the identification information of the transmission destination, and the processing unit identifies the communication device included in the packet received by the first communication unit. 6. The apparatus according to claim 3, wherein when the information matches the identification information stored in the storage unit, the received packet is passed to the second communication unit to the end. 6. Communication system.   The first communication signal transmits a packet having a communication content and a termination after the destination identification information, and the processor receives a packet that is received by the first communication unit as a broadcast packet for the communication device. The communication management device operates in the normal communication mode at a timing that is appropriately set differently in each communication management device, and the received packet is transmitted from the second communication unit to the communication device as a second communication signal. The communication system according to claim 3, wherein the communication system is transmitted.   A part of the plurality of communication management devices is connected to a server device as the communication device via the second transmission path, and the rest of the plurality of communication management devices is connected to the communication via the second transmission path. A terminal device as a device is connected, and the server device and the terminal device communicate with each other via the communication management device. The communication management device to which the server device is connected includes the terminal device The identification information of the terminal device stored in the storage unit of the connected communication management device is collected, and when the server device transmits a request to the terminal device, the collected identification information is duplicated. The communication system according to any one of claims 3 to 7, wherein the request is not transmitted in some cases.

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