JP4594843B2 - Power line carrier communication bridge device and relay method of power line carrier communication bridge device - Google Patents

Description

  The present invention relates to a bridge device, and relates to a bridge device for power line carrier communication used when a power line carrier communication network is constructed. And it is related with the relay method of this bridge device for power line carrier communications.

  In recent years, networking has progressed in various technical fields due to advances in communication technology, and various devices in a building are being connected to the network. Such devices are networked by organically linking these devices, and further instructing these devices from an external communication terminal by interconnecting the network outside the building and the network inside the building. By doing so, it is intended to provide a safe and comfortable life while responding to energy saving and remote control.

  When constructing a network, for example, a local area network (LAN), communication signals are simply transferred between ports in order to wire communication terminals in a radial pattern (star shape) or connect segments to each other. Repeater hub device that performs communication, or a bridge device (switching hub device, LAN switch device that performs communication analysis only when transferring a communication signal between ports and transfers a communication signal only to a port to which a destination communication terminal is connected ) And Ethernet (registered trademark) repeater hub devices and bridge devices are widely used. Since the bridge device transfers the communication signal only to the port to which the destination communication terminal is connected, the utilization efficiency in the communication band of the network is improved. For this reason, the bridge device has an advantage of improving the transmission capability of the network as compared with the repeater hub device.

  On the other hand, there are various methods for transmitting communication signals. However, there is an advantage that it is not necessary to install a new transmission line because existing wiring is used, and the initial cost associated with the introduction is accordingly low. Power line communication (hereinafter abbreviated as “PLC”) using wiring (power line) for supplying power to these devices as a transmission line because of the advantage that the aesthetics of the building is not impaired. May be adopted.

A repeater hub device and a bridge device are also desired when a network is constructed by PLC. For example, Patent Document 1 discloses an outlet with a LAN switch function that relays information terminals and a plurality of terminals connected by a power line that carries a superimposed wave in which an information signal is superimposed on a power carrier wave. A memory for storing a MAC address table that describes a correspondence relationship between a separating / superimposing unit that separates signals and superimposes an information signal on a power carrier, a MAC address of each terminal, and a port to which the terminal is connected And when receiving the IP packet including the destination MAC address via the separating / superimposing means, it is connected to the terminal that is the destination of the IP packet from the MAC address table and the destination MAC address of the IP packet. A switch that recognizes a port and transmits the IP packet through the recognized port and the separating / superimposing means. LAN switch function outlet is disclosed in which a ring means.
JP 2003-152757 A

  By the way, since the outlet with the LAN switch function described in Patent Document 1 recognizes a port for transmitting an IP packet by referring to the header of the Ethernet frame, there is room for speeding up the processing. Further, the above Patent Document 1 does not mention frequency division multiplexing or full-duplex communication capable of simultaneous transmission and reception in both directions.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a bridge device for power line carrier communication and a relay method for the bridge device for power line carrier communication capable of speeding up the processing. . And it aims at providing the bridge apparatus for power line carrier communications which can communicate by frequency division multiplexing. It is another object of the present invention to provide a power line carrier communication bridge device capable of full-duplex communication.

As a result of various studies, the present inventor has found that the above object is achieved by the present invention described below. That is, the power line communication bridge device according to one embodiment of the present invention separates the communication signal of the power line communication by adding a header of a power line carrier communication to communication signals in an upper layer than the power line communication layer from the power line The power line carrier communication header is taken out, and a plurality of power line carrier communication transceiver units that superimpose power line carrier communication signals on the power line, an identifier for identifying the power line carrier communication transceiver unit, and the power line carrier A transfer destination information storage unit that stores a correspondence relationship with a MAC address for power line carrier communication in a power line carrier communication terminal connected to a communication transceiver unit, and a power line carrier communication signal is received by the power line carrier communication transceiver unit In this case, by referring to the correspondence, the power line carrier communication header in the received communication signal of the power line carrier communication is obtained. Housed corresponding to the MAC address of the power line carrier communication destination is determined the identifier, the power line carrier communication transceiver of identifier the determination, bridge processing for transferring the communication signal of the power line communication thus received and a section, MAC address of the power line carrier communication is characterized physical addresses der Rukoto that is used to send and receive communication signals in the power line communication layer.

And, in another aspect of the present invention, the header of the power line carrier communication by separating the communication signal of the power line communication by adding a header of a power line carrier communication to communication signals in an upper layer than the power line communication from the power line A plurality of power line carrier communication transceiver units that superimpose power line carrier communication signals on the power line, an identifier for identifying the power line carrier communication transceiver unit, and a power line connected to the power line carrier transceiver unit A transfer destination information storage unit for storing a correspondence relationship with a MAC address for power line carrier communication in a communication terminal for carrier communication, and a bridge processing unit for transferring a communication signal for power line carrier communication between the plurality of power line carrier communication transceiver units with the door, MAC address of the power line carrier communication is physically a that is used to send and receive communication signals in the power line communication layer In relay method less der Ru power line communication bridge device, when receiving a communication signal of the power line communication in the power line carrier communication transceiver, by the power line carrier communication transceiver, a power line communication from the power line Separating the communication signal; extracting the power line carrier communication header from the separated communication signal of the power line carrier communication by the power line carrier communication transceiver; and the bridge processing unit to the transfer information storage unit. Determining the identifier corresponding to the destination MAC address for power line carrier communication accommodated in the extracted header for power line carrier communication by referring to the stored correspondence relationship; and the bridge processing By the power transmission / reception unit for the power line carrier communication of the determined identifier. And transferring the communication signal carrier communication by power line carrier communication transceiver of identifier the determination, characterized in that it comprises the steps of superimposing a communication signal of the transferred power line communication to the power line.

  The power line carrier communication bridge device and the relay method of the power line carrier communication bridge device configured as described above can be used to transfer the power line carrier communication signal between the power line carrier communication transceiver units as in the background art. Communication terminal for destination power line carrier communication based on MAC address for destination power line carrier communication accommodated in header for power line carrier communication in power line carrier communication lower than Ethernet (registered trademark) Since the communication signal is transferred only to the power line carrier communication transmitter / receiver connected to each other, the relay processing can be further speeded up.

  In the power line carrier communication bridge device described above, the frequencies used for power line carrier communication in the plurality of power line carrier communication transceiver units are different from each other.

  The power line carrier communication bridging device configured as described above can transmit a communication signal through the power line by frequency division multiplexing because the frequencies used for power line carrier communication in each power line carrier communication transceiver are different from each other. For this reason, one power line can be used simultaneously as a plurality of transmission lines.

  In the above-described power line carrier communication bridge device, the transmission frequency used for the power line carrier communication in the power line carrier communication transceiver unit is the power line carrier communication in the power line carrier communication terminal connected to the power line carrier transceiver unit. The transmission frequency is different from that used in

  The power line carrier communication bridging device configured as described above is used for power line carrier communication in a power line carrier communication terminal connected to the power line carrier communication transceiver and the frequency used for power line carrier communication in the power line carrier transceiver. Since the frequencies to be used are different from each other, the frequency used for the downlink power line carrier communication from the power line carrier communication bridge device to the power line carrier communication terminal and the power line carrier communication terminal to the power line carrier bridge device Since the frequencies used for the power line carrier communication in the upstream direction are different from each other, full duplex communication can be performed.

Furthermore, in the above-described bridge device for power line carrier communication, the bridge processing unit sets the MAC address for power line carrier communication of the destination accommodated in the header for power line carrier communication in the received communication signal of power line carrier communication. When the corresponding MAC address is not in the correspondence, the power line carrier communication transceiver unit connected to the power line carrier communication terminal having the destination MAC address for power line carrier communication is searched, and the searched power line The identifier of the transmission / reception unit for carrier communication and the MAC address for power line carrier communication of the destination are associated with each other and stored as the correspondence in the transfer destination information storage unit.

  In the bridge device for power line carrier communication having such a configuration, the MAC address corresponding to the destination MAC address accommodated in the header for power line carrier communication in the received communication signal of power line carrier communication is not in the correspondence relationship. In this case, since the correspondence relationship is automatically generated, relay processing can be performed even when the correspondence relationship does not exist.

  The power line carrier communication bridge device and the relay method of the power line carrier communication bridge device having such a configuration can speed up the processing.

Embodiments according to the present invention will be described below with reference to the drawings. In addition, the structure which attached | subjected the same code | symbol in each figure shows that it is the same structure, The description is abbreviate | omitted.
(Configuration of the first embodiment)
FIG. 1 is a diagram showing a schematic configuration of a power line carrier communication network according to the first embodiment. FIG. 2 is a block diagram showing a configuration of the power line carrier communication bridge device according to the first embodiment. FIG. 3 is a block diagram illustrating a configuration of the power line carrier communication transceiver according to the embodiment. FIG. 4 is a diagram illustrating a format of a communication signal for power line carrier communication. FIG. 4A is an overall view thereof, and FIG. 4B is a partial view showing a header portion. FIG. 5 is a diagram illustrating a configuration of a transfer destination information table according to the embodiment.

  In FIG. 1, a power line carrier communication network (hereinafter abbreviated as “PLC network”) N is a power line carrier communication bridge device (hereinafter abbreviated as “PLC bridge device”) 1 and an outlet 2 (2 -A, 2-B, 2-C,..., 2-F), power line 3 (3-A, 3-B, 3-C,..., 3-F) and outlet 4 (4-A , 4-B, 4-C1, 4-C2,..., 4-F1, 4-F2, 4-F3) and power line carrier communication modem (hereinafter abbreviated as “PLC modem”) 5 ( 5-A, 5-B, 5-C1, 5-C2,..., 5-F1, 5-F2, 5-F3) and communication terminal 6 (6-A, 6-B, 6-C1, 6) -C2, ..., 6-F1,6-F2,6-F3).

  In the present specification, when referring generically, it is indicated by a reference symbol without a suffix, and when referring to an individual configuration, it is indicated by a reference symbol with a suffix.

  The PLC bridge device 1 is a device according to the present invention. In the PLC, the PLC performs electrical regenerative relay of received communication signals and abbreviates a header for power line carrier communication (hereinafter referred to as “PLC header”). ) Is a communication terminal for power line carrier communication that performs PLC and has a destination MAC address in the PLC header (hereinafter referred to as “PLC”). A power line carrier communication transmitter / receiver (hereinafter abbreviated as “PLC transmitter / receiver”) 14 to which a communication signal is connected, which is connected to the power line 3. Alternatively, a plurality of power line connection portions 15 (six power line connection portions 15-A to 15-F in FIGS. 1 and 2) are arranged on one side surface of a substantially box-shaped housing. That. The configuration of the PLC bridge device 1 will be described later.

  The outlet 2 is a connector that electrically connects the PLC bridge device 1 and the power line 3 constituting the power system. The power line 3 is a conductor line laid for the purpose of supplying power to the device, and is used as a transmission line in the PCL. The outlet 4 is a connector that electrically connects the power line 3 and the PLC modem 5.

  The power line 3 is laid for each system, and outlets 2 and 4 are connected to both ends thereof. In the example shown in FIG. 1, the power line 3-A is used for the power system A and the outlets 2-A and 4-A are connected to both ends thereof, and the power line 3-B is used for the power system B and The outlets 2-B and 4-B are connected to both ends, respectively, and the power line 3-C is used for the power system C. The outlet 2-C is connected to one end of the power line 3-C and branches into two in the middle. Then, outlets 4-C1 and 4-C2 are connected to the respective ends, and the power line 3-F is used for the power system F, and the outlet 2-F is connected to one end of the power line 3-F. The branch branches into three on the way, and outlets 4-F1, 4-F2, and 4-F3 are connected to the respective ends.

  The PLC modem 5 is a device for performing PLC. The PLC modem 5 adds a PLC header to an upper layer communication signal (for example, an Ethernet frame) received from the communication terminal 6 to generate a PLC communication signal. A communication signal is transmitted to the power line 3 via the outlet 4, and a PLC header is removed from the PLC communication signal received from the power line 3 via the outlet 4, thereby generating an upper layer communication signal (for example, an Ethernet frame). The upper layer communication signal is transmitted to the communication terminal 6. The MAC address for power line carrier communication is a physical address used when transmitting and receiving communication signals in the power line carrier communication layer, and is uniquely assigned to the network card for power line carrier communication for performing PLC in the world. . In the description of the best mode for carrying out the present invention, unless otherwise specified, the MAC address indicates a MAC address for power line carrier communication. The PLC modem 5 is assigned with a PLC MAC address. The communication terminal 6 is a device that performs communication in an upper layer than the PLC, and is a device that performs communication using, for example, an Ethernet frame in which an Ethernet card is incorporated.

  In the example shown in FIG. 1, the communication terminals 6-A, 6-B, 6-C1, 6-C2, 6-F1, 6-F2, and 6-F3 are PLC modems 5-A, 5-B, 5 -To outlets 4-A, 4-B, 4-C1, 4-C2, 4-F1, 4-F2, 4-F3 via C1, 5-C2, 5-F1, 5-F2, 5-F3 It is connected.

  The PLC modem 5 and the communication terminal 6 are collectively regarded as a PLC communication terminal 7. In the present embodiment, the PLC modem 5 and the communication terminal 6 are separate bodies, but the PLC modem 5 and the communication terminal 6 may be configured integrally. The PLC modem 5 or the PLC communication terminal 7 corresponds to a communication terminal for power line carrier communication in the claims.

  In FIG. 2, the PLC bridge device 1 includes a processing unit 11, a storage unit 12, a power line carrier communication transmission / reception unit selection unit (hereinafter abbreviated as “PLC transmission / reception unit selection unit”) 13, and a PLC. The transmission / reception unit 14, the power line connection unit 15, and the power supply unit 16 are configured. The processing unit 11, the storage unit 12, the PLC transmission / reception unit selection unit 13, the PLC transmission / reception unit 14 and the power supply unit 16 are described above. Housed in a box-type housing.

  The power line connection unit 15 is a device for connecting to the power line 3. For example, in the present embodiment, the power line connection unit 15 is configured by a cord having a plug at one end and the other end connected to the PLC transmission / reception unit 14. Further, for example, it may be configured by an outlet (not shown) disposed on one side surface of the above-described box-type housing so as to expose the outlet port (outlet socket) (not shown). The terminal may be configured to connect the PLC transceiver 14 and the power line 3 (not shown).

  The PLC transmission / reception unit 14 separates the PLC communication signal from the power line 3 connected via the power line connection unit 15 and the outlet 2, takes out the PLC header, and outputs the PLC communication signal to the power line using a predetermined frequency. It is a device that superimposes on.

  For example, the PLC transmits the communication signal having a frequency higher than the commercial frequency on the power waveform of the commercial frequency, or transmits the communication signal of the PLC by separating the high frequency communication signal from the power waveform. This is a communication method for transmitting and receiving signals via the power line 3. The format of the PLC communication signal has a structure in which a PLC header is added to a communication signal in an upper layer than the PLC. For example, in this embodiment, Ethernet (registered trademark) is used in the upper layer, as shown in FIG. In addition, a PLC header 31 is added to the Ethernet frame 32. The PLC header 31 is a part that accommodates information necessary for performing PLC such as a transmission source address and a destination address. As shown in FIG. 4B, a PLC communication terminal of the transmission source (in this embodiment, a PLC is used). Power line carrier communication MAC address 311 that accommodates the MAC address for power line carrier communication in the modem 5) and the MAC address for power line carrier communication in the destination PLC communication terminal (the PLC modem 5 in this embodiment). And a MAC address 312 for power line carrier communication of a destination that accommodates. The Ethernet frame 32 has a structure in which an Ethernet header 321 is added to an IP datagram 33, and the IP datagram 33 has a structure in which an IP header 331 is added to data 332 to be transmitted.

  For example, as shown in FIG. 3, the PLC transmission / reception unit 14 includes a coupling circuit 141, an analog front end unit 142, a digital signal processing unit 143, and a buffer storage unit 144.

  The coupling circuit 141 separates the PLC communication signal from the power line 3 connected via the power line connection unit 15 and outputs the PLC communication signal to the analog front end unit 142, and the PLC communication signal input from the analog front end unit 142. This circuit is superimposed on the power line 3.

  The analog front end unit 142 is a device that mutually converts an analog signal and a digital signal with respect to a PLC communication signal, and includes a modulation / demodulation circuit 1421 and an oscillation circuit 1422.

  The oscillation circuit 1422 is a circuit that oscillates a sine wave having a predetermined frequency. For example, a known oscillation circuit such as a Colpitts oscillation circuit, a Hartley oscillation circuit, or a PLL (Phase Lock Loop) oscillation circuit is used. The modem circuit 1421 demodulates the PLC communication signal of the analog signal input from the coupling circuit 141 into a digital signal, outputs the digital signal to the digital signal processing unit 143, and transmits the data to be transmitted input from the digital signal processing unit 143. This is a circuit that generates a PLC communication signal of an analog signal by modulating a sine wave from the oscillation circuit 1422 in accordance with a digital signal and outputs the communication signal to the coupling circuit 141.

  The digital signal processing unit 143 stores the PLC communication signal of the digital signal input from the analog front end unit 142 in the buffer storage unit 144, and extracts the PLC header from the PLC communication signal of the digital signal, and processes the processing unit. 11 is an apparatus for outputting to the apparatus.

  The buffer storage unit 144 is a buffer that temporarily stores a PLC communication signal of a digital signal, and includes a readable / writable storage element such as a RAM (Random Access Memory), for example.

  The number of the PLC transmission / reception units 14 having such a configuration is determined by the specifications of the PLC bridge device 1. In the example illustrated in FIGS. 1 and 2, the PLC transmission / reception unit 14 -A to the PLC transmission / reception unit 14 -F. It is six. The power line connection unit 15 is provided on the PLC transmission / reception unit 14 on a one-to-one basis.

  The storage unit 12 functionally includes a transfer destination information storage unit 121 that stores transfer destination information, and PLC communication is performed between the PLC transmission and reception units 14 according to the destination MAC address accommodated in the PLC header. Various programs such as a relay program for relaying PLC communication signals between PLC communication terminals by transferring signals, a control program for controlling each part of the PLC bridge device 1, and each of the PLC bridge devices 1 Various data such as data necessary for execution of various programs such as a MAC address for power line carrier communication allocated to the PLC transmission / reception units 14-A to 14-F and data generated during the execution are stored. The storage unit 12 is a rewritable nonvolatile storage such as a volatile storage element such as a RAM serving as a so-called working memory of the processing unit 11 or an EEPROM (Electrically Erasable Programmable Read Only Memory) that stores various data. The device includes a non-volatile storage element such as a ROM (Read Only Memory) for storing elements and various programs and various data.

  The transfer destination information relays the PLC communication signal between the PLC communication terminals by transferring the PLC communication signal between the PLC transmission / reception units 14 according to the destination MAC address accommodated in the PLC header. For example, in the present embodiment, an identifier for identifying the PLC transceiver 14 and a PLC communication terminal 7 (PLC) connected to the PLC transceiver 14 via the power line connection unit 15 and the power line 3 are described. Information indicating the correspondence with the PLC MAC address in the communication modem 5 and the communication terminal 6). The identifier for identifying the PLC transceiver 14 may be an arbitrary code string (including one), but in this embodiment, the identifier is assigned to each PLC transceiver 14-A to 14-F. Number (hereinafter referred to as “port number”), and numbers from 0 to 5 are assigned in order from the PLC transceiver 14-A to the PLC transceiver 14-F.

  In this embodiment, the transfer destination information is stored in the transfer destination information storage unit 121 in a table format, for example, as shown in FIG. The transfer destination information table 51 shown in FIG. 5 for registering the transfer destination information includes a port number field 511 for registering a port number in the transfer destination PLC transceiver 14 and a MAC address for registering the destination PLC MAC address. Field 512. In the transfer destination information table 51, a record 513 is created for each PLC transmission / reception unit 14 of the transfer destination in the port number field 511, and this created in the MAC address field 512 corresponding to the created record 513. PLC communication terminal 7 (PLC modem 5 and communication terminal) connected to the PLC transmission / reception unit 14 having the port number registered in the port number field 511 of the record 513 via the power line connection unit 15 and the power line 3. A record 514 is created for each MAC address for power line carrier communication (MAC address allocated to the PLC modem 5) in 6).

  In the example illustrated in FIG. 5, as illustrated in FIG. 1, for example, one PLC communication terminal 7 is connected to the PLC transceiver unit 14 -A having the port number 0 via the power line connection unit 15 -A, the power line 3 -A, and the like. Since -A (PLC modem 5-A and communication terminal 6-A) is connected, assuming that the PLC MAC address of the PLC modem 5-A is MACA1, the transfer destination information table 51 includes a port number. One record 514-1 for registering MACA1 in the MAC address field 512 is created corresponding to one record 513-1 in which 0 is registered in the field 511. Further, for example, two PLC communication terminals 7-C1 and 7-C2 (PLC modem 5-C1 are connected to the PLC transceiver 14-C having the port number 2 via the power line connection unit 15-C and the power line 3-C. And the communication terminal 6-C1, the PLC modem 5-C2, and the communication terminal 6-C2), the PLC MAC addresses of the PLC modems 5-C1 and 5-C2 are MACC1 and MACC2. In the transfer destination information table 51, two records 514-31 and 514 for registering MACC1 and MACC2 in the MAC address field 512 corresponding to one record 513-3 in which 2 is registered in the port number field 511, respectively. A record 514-3 consisting of -32 is created.

  The processing unit 11 includes, for example, a microprocessor and its peripheral circuits. When the PLC transmission / reception unit 14 receives a PLC communication signal, the processing unit 11 stores the transfer destination information stored in the transfer destination information storage unit 121. In the present embodiment, by referring to the transfer destination information table 51, the port number corresponding to the destination MAC address accommodated in the PLC header in the received PLC communication signal is determined, and the determined port number is determined. Is provided with a transfer processing unit 111 for controlling the PLC transmission / reception selection unit 13 so that the received PLC communication signal is transferred to the PLC transmission / reception unit 14. The transmission / reception unit 14 is controlled according to the function.

  The PLC transmission / reception unit selection unit 13 receives the PLC communication signal from the PLC transmission / reception unit 14 so that the received PLC communication signal is transferred to the transfer destination PLC transmission / reception unit 14. This switch circuit switches the electrical connection between the PLC transceiver units 14 in accordance with the control of the transfer processing unit 111.

  The power supply unit 16 is supplied with commercial power from, for example, the power main line L, generates a DC drive power from the commercial power, and supplies the drive power to the processing unit 11, the storage unit 12, and the PLC transceiver 14. The drive power supply may be configured to be generated from a battery or the like.

  The transfer processing unit 111 and the PLC transmission / reception unit selection unit 13 correspond to a bridge processing unit.

Next, the operation of this embodiment will be described.
(Operation of the first embodiment)
FIG. 6 is a flowchart illustrating the operation of the power line carrier communication bridge device according to the embodiment. When a PLC communication signal is received from the power line 3 via the power line connection unit 15 or the like, the PLC transmission / reception unit 14 of the PLC bridge device 1 separates the PLC communication signal from the power line 3 in FIG. The separated PLC communication signal is stored, and the PLC header is extracted from the separated PLC communication signal and notified to the transfer processing unit 111 of the processing unit 11 (S11).

  More specifically, the coupling circuit 141 of the PLC transmission / reception unit 14 separates the PLC communication signal from the power line 3 and outputs it to the analog front end unit 142. The modem circuit 1421 of the analog front end unit 142 demodulates the analog communication PLC communication signal input from the coupling circuit 141 into a digital signal and outputs the digital signal to the digital signal processing unit 143. The digital signal processing unit 143 stores the PLC communication signal of the digital signal input from the analog front end unit 142 in the buffer storage unit 144 and extracts the PLC header from the PLC communication signal of the digital signal. The data is output to the transfer processing unit 111 of the processing unit 11.

  When the transfer processing unit 111 receives the notification of the PLC header from the PLC transmission / reception unit 14, the transfer processing unit 111 receives the PLC header received by the PLC transmission / reception unit 14 based on the information received in the received PLC header. It is determined whether there is a communication signal relay destination (S12). More specifically, the transfer processing unit 111 first extracts the destination MAC address accommodated in the notified PLC header. Then, the transfer processing unit 111 refers to the transfer destination information stored in the transfer destination information storage unit 121 of the storage unit 12, in this embodiment, the transfer destination information table 51, and the destination MAC extracted from the PLC header. It is determined whether the address is registered in the MAC address field 512 of the transfer destination information table 51.

  If the result of this determination is that there is a relay destination (Yes), the transfer processing unit 111 executes step S13. On the other hand, if there is no relay destination (No), the transfer processing unit 111 performs processing described later. S21 is executed.

  In process S13, the transfer processing unit 111 obtains the port number from the port number field 511 of the record 513 corresponding to the record 514 that registers the destination MAC address extracted from the PLC header in the MAC address field 512 of the transfer destination information table 51. The port number in the PLC transmission / reception unit 14 of the transfer destination to which the PLC communication terminal 7 (PLC modem 5 and communication terminal 6) to which the PLC communication signal received by the PLC transmission / reception unit 14 is to be relayed is obtained is obtained. .

  Next, the transfer processing unit 111 controls the PLC transmission / reception unit selection unit 13 to electrically connect the PLC transmission / reception unit 14 having the acquired port number and the PLC transmission / reception unit 14 that has received the PLC communication signal. (S14). For example, when the PLC transmission / reception unit 14-A receives a PLC communication signal addressed to the PLC communication terminal 7-C1, the PLC transmission / reception unit selection unit 13 controls the PLC transmission / reception unit 14-A according to the control of the transfer processing unit 111. And PLC transmitting / receiving unit 14-C are electrically connected.

  Then, the transfer processing unit 111 receives the PLC communication signal of the digital signal stored in the buffer storage unit 144 of the PLC transmission / reception unit 14 that has received the PLC communication signal, and the PLC transmission / reception unit that has received the PLC communication signal. The data is transferred from the unit 14 to the PLC transmission / reception unit 14 as the transfer destination via the PLC transmission / reception unit selection unit 13 (S15).

  When the PLC communication signal of the digital signal is transferred, the PLC transmission / reception unit 14 inputs the PLC communication signal of the digital signal to the analog front end unit 142 via the digital signal processing unit 143. The modulation / demodulation circuit 1421 in the analog front end unit 142 generates a PLC communication signal of an analog signal by modulating the sine wave from the oscillation circuit 1422 according to the input digital signal, and outputs the communication signal to the coupling circuit 141. The coupling circuit 141 superimposes the PLC communication signal input from the modulation / demodulation circuit 1421 of the analog front end unit 142 on the power line 3. As a result, the PLC bridge device 1 electrically regenerates the received PLC communication signal and relays it only to the destination PLC communication terminal 7.

  For example, as shown in FIG. 1, the PLC communication terminal 7 -A sequentially sends PLC communication signals to the PLC communication terminal 7 -C 1, the PLC communication terminal 7 -F 1, the PLC communication terminal 7 -F 3, and the PLC communication terminal 7 -F 1. When (toC1, toF1, toF3, toF1) is transmitted, the PLC bridge device 1 executes processing S11, processing S12, processing S13, processing S14, and processing S15, thereby transmitting and receiving the PLC transmitting / receiving units 14-B, 14-. D and 14-E are PLC communication signals (toC1, toF1, toF3, toF1) to the PLC communication terminal 7-C1, the PLC communication terminal 7-F1, the PLC communication terminal 7-F3, and the PLC communication terminal 7-F1. The PLC transceiver 14-C transfers only the PLC communication signal (toC1) to the PLC communication terminal 7-C1, Only the PLC communication signal (toC1) to the C communication terminal 7-C1 is transmitted to the power line 3-C, and the PLC transceiver unit 14-F includes the PLC communication terminal 7-F1, the PLC communication terminal 7-F3, and the PLC communication. Only the PLC communication signals (toF1, toF3, toF1) to the terminal 7-F1 are transferred, and the PLC communication signals (toF1) to the PLC communication terminal 7-F1, the PLC communication terminal 7-F3, and the PLC communication terminal 7-F1. , ToF3, toF1) are transmitted to the power line 3-F.

  In this way, the PLC bridge device 1 refers to the PLC to which the PLC communication terminal 7 having the destination MAC address in the PLC header is connected by referring to the destination MAC address accommodated in the PLC header in the PLC. The communication signal is transferred only to the transmission / reception unit 14. In other words, the PLC bridge device 1 executes relay processing in the PLC hierarchy. For this reason, the PLC bridge device 1 can process the relay processing at a higher speed than the background art.

  On the other hand, in process S21, the transfer processing unit 111 converts the power line carrier communication MAC address assigned to the PLC transceiver 14 that has received the PLC communication signal into the source power line carrier communication MAC address in the PLC header. Used in the processing, a communication signal containing a destination MAC address extracted from the PLC header in step S12 and information requesting a response signal reply when this MAC address is used as the MAC address of the own device ( Hereinafter, this will be referred to as a “transfer destination search signal”. The response signal is a communication signal containing information indicating that the own device has the MAC address contained in the transfer destination search signal as the MAC address. Then, the transfer processing unit 111 sequentially switches the PLC transmission / reception unit selection unit 13 and transfers the generated transfer destination search signal to each of the PLC transmission / reception units 14-A to 14-F. The generated transfer destination search signal is broadcast. As is well known, broadcast communication includes, for example, broadcast and multicast.

  When each of the PLC modems 5-A to 5-F receives the broadcast destination search signal transmitted from the power line 3, the PLC modem 5-A to 5-F obtains its own MAC address and the MAC address accommodated in the destination search signal. If they match, a response signal is returned. For example, by configuring the PLC modem 5 so that the reception confirmation response signal of the transfer destination search signal is returned only when the MAC address of the own device and the MAC address accommodated in the transfer destination search signal match. The reception confirmation signal of the transfer destination search signal can be used as a response signal.

  When the transfer processing unit 111 receives a response signal from the PLC modem 5 having the destination MAC address extracted from the PLC header in step S12 as its own MAC address, the transfer processing unit 111 is assigned to the PLC transmission / reception unit 14, for example. The port number of the PLC transceiver 14 that has received this response signal is acquired by determining the PLC transceiver 14 that has notified the PLC header that contains the MAC address as the destination MAC address (S22).

  Next, the transfer processing unit 111 searches for a record 513 in which the acquired port number is registered in the port number field 511 of the transfer destination information table 51. Then, the transfer processing unit 111 newly creates a record 514 in the MAC address field 512 corresponding to the retrieved record 513, and the PLC transmission / reception unit 14 notifies the created record 514 of the MAC address field 512. The MAC address accommodated as the source MAC address is registered in the PLC header. Thereby, the transfer destination information table 51 is updated (S23). Next, the transfer processing unit 111 executes the processes S14 and S15 described above.

  For example, the transfer destination information table 51 shown in FIG. 5 in which the MAC address is not registered in the record 514-2 of the MAC address field 512 corresponding to the record 513-2 in which 1 is registered in the port number field 511 is transferred to the storage unit 12. The PLC communication terminal 7-A (the PLC modem 5-A and the communication terminal 6-A) is stored in the destination information storage unit 121, and the PLC communication terminal 7-B (the PLC modem 5-B and the communication terminal 6-A). When a PLC communication signal is transmitted to B), first, after executing step S11, it is determined in step S12 that there is no transfer destination. In step S21, the transfer processing unit 111 includes the MAC address of the PLC modem 5-B. The transfer destination search signal is broadcast to the PLC network N. When the transfer destination search signal is broadcast to the PLC network N, only the PLC communication terminal 7-B returns a response signal. Then, the transfer processing unit 111 acquires the port number 1 of the PLC transmission / reception unit 14 that has received the response signal in step S22. In step S23, the transfer processing unit 111 searches the record 513-2 for registering the acquired port number 1 in the port number field 511 of the transfer destination information table 51, and associates it with the searched record 513-2. Then, a new record 514-2 is created in the MAC address field 512, and the created MAC address field 512 contains the record 514-2 as the source MAC address in the PLC header notified from the PLC transceiver unit 14. Registered MAC address.

  By operating in this way, the PLC bridging device 1 is configured such that when the MAC address corresponding to the destination MAC address accommodated in the PLC header in the received PLC communication signal does not exist in the transfer destination information table 51, The correspondence between the destination MAC address and the port number in the transfer destination information table 51 can be automatically generated and registered in the transfer destination information table 51. As a result, even when there is no such correspondence, the PLC bridge device 1 can perform the relay process.

Next, another embodiment will be described.
(Second Embodiment)
FIG. 7 is a block diagram showing a configuration of a power line carrier communication bridge device according to the second embodiment. The PLC bridge device 1 ′ according to the second embodiment is different from the PLC bridge device 1 according to the first embodiment in the frequencies used for the PLC in the plurality of PLC transceiver units 14. For this reason, as shown in FIG. 7, the PLC bridge device 1 ′ is similar to the PLC bridge device 1, and the processing unit 11 functionally including the transfer processing unit 111 and the transfer destination information table 51 are stored therein. The storage unit 12 functionally includes the destination information storage unit 121, the PLC transmission / reception unit selection unit 13, and the PLC transmission / reception unit 14, and a power line connection unit instead of the power line connection unit 15 of the first embodiment. 17.

  Here, it should be noted that in the second embodiment, each of the PLC transmission / reception units 14-A to 14-F has different frequencies used for the PLC. That is, each of the PLC transceiver units 14-A to 14-F superimposes PLC communication signals on the power line 3 using frequencies A to F (frequency A to frequency F are different from each other). More specifically, as in the case of the first embodiment shown in FIG. 3, the PLC transceiver unit 14 includes a coupling circuit 141, an analog front end unit 142 including a modulation / demodulation circuit 1421 and an oscillation circuit 1422, and a digital signal. When the processing unit 143 and the buffer storage unit 144 are provided, the oscillation frequency of the oscillation circuit 1422 is different between the PLC transmission / reception units 14-A to 14-F.

  On the other hand, in the second embodiment, the PLC modems 5-A to 5-F are connected via the power lines 3-A to 3-F and the power line connection units 15-A to 15-F. Each of the PLC transceiver units 14-A to 14-F is configured to generate a PLC communication signal at a frequency used for the PLC. That is, each of the PLC modems 5-A to 5-F superimposes a PLC communication signal on the power line 3 using the frequencies A to F.

  The power line connection unit 17 is a device for connecting a plurality of PLC transmission / reception units 14 and a single power line 3, for example, a plurality of terminals 171 for connecting to the plurality of PLC transmission / reception units 14, respectively (see FIG. 7, six terminals 171 -A to 171 -F), a terminal 173 for connecting to the power line 3, and a conductive conduction path 172 for connecting the plurality of terminals 171 and the terminal 173. Prepare.

  In the second embodiment, one power line 3 is connected to the terminal 173 of the power line connecting portion 17, the outlet 4 is provided on the power line 3, and the PLC modems 5-A to 5-F are one. Connected to the power line 3. The terminal 173 may be an outlet (outlet socket), and the power line connection unit 17 may be configured to be connected to the power line 3 via the outlet 2 as in the first embodiment. .

  In the PLC bridge device 1 ′ having such a configuration, the PLC transceiver units 14 -A to 14 -F use the different frequencies A to F and the PLC communication terminals 7 -A to 7 -F, respectively. PLC communication signals are transmitted and received using one power line 3 as a transmission path.

  As described above, in the PLC bridge device 1 ′ according to the second embodiment, the frequencies A to F used for the PLCs in the PLC transceiver units 14-A to 14-F are different from each other. Communication signals can be transmitted through the power line 3. For this reason, one power line 3 can be used simultaneously as a plurality of transmission lines.

  In the second embodiment, the PLC bridge device 1 ′ can configure logical sub-networks with the PLC communication terminals 7 -A to 7 -F by frequency division multiplexing. On the other hand, the PLC bridge device 1 according to the first embodiment can configure a physical sub-network and a logical sub-network with each of the PLC communication terminals 7-A to 7-F.

  In the second embodiment, the company side sets in advance at the manufacturing stage, the shipping stage, etc. so that the frequencies A to F used for the PLCs in the PLC transmitting / receiving units 14-A to 14-F are different from each other. It may be configured so that it can be set on the user side.

  FIG. 8 is a block diagram showing a configuration of a power line carrier communication transceiver unit with a frequency setting function. In FIG. 8, a PLC transmission / reception unit 14 ′ with a frequency setting function includes a coupling circuit 141, a digital signal processing unit 143, and a buffer storage unit similar to the PLC transmission / reception unit 14 in the first and second embodiments. 144, an analog front end 142 ′ instead of the analog front end 142 in the first and second embodiments, and a frequency setting circuit 145.

  The analog front end unit 142 ′ includes a modulation / demodulation circuit 1421 similar to those in the first and second embodiments, and a frequency variable oscillation circuit 1423 that is an oscillation circuit that can change the oscillation frequency in accordance with the setting of the frequency setting circuit 145. With. The frequency setting circuit 145 is a circuit that sets the oscillation frequency of the variable frequency oscillation circuit 1423.

  The variable frequency oscillation circuit 1423 is composed of, for example, a Colpitts oscillation circuit or a Hartley oscillation circuit, and a plurality of circuit elements for determining the oscillation frequency such as a capacitor and a coil are prepared so that the oscillation frequency can be changed. By selecting one circuit element by a frequency setting circuit 145 having a plurality of contacts such as a switch, a plurality of dip switches, a rotary switch, and the like and capable of switching between these contacts, the oscillation frequency is reduced. Is set.

  Further, for example, the variable frequency oscillation circuit 1423 is configured by a frequency synthesizer using a PLL oscillation circuit, and is configured such that a plurality of magnifications of the PLL oscillation circuit can be set so that the oscillation frequency can be changed. An oscillation frequency is set by selecting one magnification by a frequency setting circuit 145 that includes a plurality of contacts and a switch that can switch between the contacts. The frequency synthesizer includes, for example, a reference oscillator, a phase comparator, a low-pass filter, a voltage controlled oscillator, and a frequency divider. In the frequency synthesizer having such a configuration, the output of the voltage controlled oscillator is frequency-divided or multiplied by a frequency divider and converted to a predetermined frequency and output to a phase comparator. The phase comparator compares the phase of the output from the frequency divider and the output from the reference oscillator, and outputs the error component to the low-pass filter. In the low-pass filter, a correction value voltage is generated based on the output from the phase comparator and output to the voltage controlled oscillator. The voltage-controlled oscillator changes the oscillation frequency according to the correction value voltage so that the frequency after the frequency division matches the frequency of the reference oscillator. In the frequency synthesizer, a desired frequency can be obtained by changing the magnification of the frequency divider or frequency divider.

  As described above, in the PLC bridge devices 1 and 1 ′ having the PLC transmission / reception unit 14 ′ instead of the PLC transmission / reception unit 14, the user side is configured so that the frequencies used for the PLCs in the PLC transmission / reception units 14 ′ are different from each other. Therefore, the frequency of each PLC transmitting / receiving unit 14 ′ can be set according to the transmission environment of the power line 3. In particular, in PLC, since the power line is used, firstly, the transmission environment changes relatively largely due to the noise generated by the equipment connected to the power line and the reduction of the impedance of the power line due to the connection of the equipment. Therefore, it is useful that the frequency of each PLC transmitting / receiving unit 14 ′ can be set on the user side.

  In the first and second embodiments described above, the transmission frequency used for the PLC in the PLC transmission / reception units 14 and 14 'is the PLC communication terminal 7 (for PLC) connected to the PLC transmission / reception units 14 and 14'. You may set so that it may differ from the transmission frequency used for PLC in the modem 5 and the communication terminal 6).

  By configuring the PLC bridge device 1, 1 ′ in this way, the frequency used for the downlink PLC going from the PLC bridge device 1, 1 ′ to the PLC communication terminal 7, and the PLC communication terminal 7 to the PLC bridge Since the frequencies used for the PLC in the upstream direction toward the devices 1 and 1 ′ are different from each other, it is possible to communicate in full duplex.

  Since the power line 3 is branched from the power trunk line L by the distribution board, the PLC bridge devices 1 and 1 'according to the first and second embodiments described above may be arranged on the distribution board. Good.

  FIG. 9 is a diagram showing a configuration of a distribution board with a bridge function for power line carrier communication. FIG. 9A shows a first configuration of a distribution board with a power line carrier communication bridge function, and FIG. 9B shows a second configuration of a distribution board with a power line carrier communication bridge function. Show.

  An example in which the PLC bridge device 1 according to the first embodiment is arranged on a distribution board will be described. In FIG. 9A, a distribution board 70 having a bridge function for power line carrier communication (hereinafter referred to as “PLC”). The abbreviation distribution board with a bridge function ”) is composed of a breaker 71 for connecting the power main line L, a plurality of breakers 72 for connecting the power line 3, and the breakers 71 and the plurality of breakers 72. A conductive conduction path 73 to be connected and the PLC bridge device 1 are provided, and the power line connection portion 15 of the PLC bridge device 1 is connected to the breaker 72. By connecting the power main line L to the breaker 71 and connecting the power line 3 to the breaker 72, the power main line L is branched into a plurality of power lines 3 by the distribution board 70 with a PLC bridge function, and the power line 3 is connected to the PLC bridge device. 1 power line connection unit 15. In the example shown in FIG. 9A, the breaker 72 is provided with six breakers 72-A to 72-F, and a power distribution line 3-having six power trunk lines L in the distribution board 70 with a PLC bridge function. The power lines 3-A to 3-F are branched to A to 3-F, and the power lines 3-A to 3-F are connected to the power line connection units 15-A to 15-F of the PLC bridge device 1, respectively. In FIG. 9A, the processing unit 11, the PLC transmission / reception unit selection unit 13, and the storage unit 12 in the PLC bridge device 1 are collectively described as a bridge processing unit / storage unit 10. Is omitted.

  By incorporating the PLC bridge device 1 into the distribution board in this way, the connection between the power line 3 and the PLC bridge device 1 is facilitated. Moreover, although the several power line 3 is mutually connected by the conduction path 73, by making mutually different the frequency used for PLC in the some PLC transmission / reception part 14 of the bridge device 1 for PLC as above-mentioned, Each power line 3 can communicate with the PLC at the same time.

  Similarly, the PLC bridge device 1 ′ according to the second embodiment can be disposed on the distribution board, and the distribution board 70 with the PLC bridge function can be configured.

  Further, as shown in FIG. 9B, a PLC including seven PLC transmission / reception units 14 and seven power line connection units 15 so that the power trunk line L can communicate with the PLC in addition to the six power lines 3. It is good also as the distribution board 70 'with the bridge function for PLC which incorporated the bridge apparatus 1 for distribution in the distribution board. Each PLC transmitting / receiving unit 14-A to 14-F is connected to each of the breakers 72-A to 72-F by the power line connecting units 15-A to 15-F in the same manner as in FIG. The unit 14-X is connected to the breaker 71 by the power line connection unit 15-X. By connecting the power trunk line L to the breaker 71, the power trunk line L is connected to the power line connection portion 15-X of the PLC bridge apparatus 1 by the distribution board 70 'with a PLC bridge function.

  By configuring the distribution board 70 ′ with the PLC bridge function in this way, it is possible to communicate with the PLC modem 5 -X outside the building using the power trunk line L.

  Furthermore, the PLC bridge device according to the present invention may be incorporated in a higher-level device such as a router device or a gateway device.

It is a figure which shows schematic structure of the power line carrier communication network which concerns on 1st Embodiment. It is a block diagram which shows the structure of the bridge apparatus for power line carrier communications which concerns on 1st Embodiment. It is a block diagram which shows the structure of the transmission / reception part for power line carrier communications which concerns on embodiment. It is a figure which shows the format of the communication signal of power line carrier communication. It is a figure which shows the structure of the transfer destination information table which concerns on embodiment. It is a flowchart which shows operation | movement of the bridge apparatus for power line carrier communications which concerns on embodiment. It is a block diagram which shows the structure of the bridge apparatus for power line carrier communications which concerns on 2nd Embodiment. It is a block diagram which shows the structure of the transmission / reception part for power line carrier communications with a frequency setting function. It is a figure which shows the structure of the electricity distribution panel with a bridge function for power line carrier communication.

Explanation of symbols

L power trunk line N power line carrier communication network 1, 1 ′ bridge device for power line carrier communication 3 power line 5 modem for power line carrier communication 6 communication terminal 7 PLC communication terminal 11 processing unit 12 storage unit 13 transmitter / receiver selection unit for power carrier communication, 14 'power carrier communication transmitter / receiver 15, 17 power line connection unit 51 transfer destination information table 70, 70' distribution board 111 with power line carrier communication bridge function transfer processing unit 121 transfer destination information storage unit 141 coupling circuit 511 port number Field 512 MAC address field 142, 142 'Analog front end unit 143 Digital signal processing unit 144 Buffer storage unit 145 Frequency setting circuit 1421 Modulation / demodulation circuit 1423 Variable frequency oscillation circuit 1422 Oscillation circuit

Claims (5)

Is taken out the header of the power line carrier communication by separating the communication signal of the power line communication by adding a header of a power line carrier communication to communication signals in an upper layer than the power line communication layer from the power line, the communication signal of the power line communication A plurality of power line carrier communication transceiver units that superimpose the power line on the power line;
Transfer destination information storage unit for storing a correspondence relationship between an identifier for identifying the power line carrier communication transceiver and a power line carrier MAC address in a power line carrier communication terminal connected to the power line transceiver When,
When a communication signal for power line carrier communication is received by the power line carrier communication transceiver, the correspondence is stored in the header for power line carrier communication in the received communication signal for power line carrier communication. A bridge processing unit that determines the identifier corresponding to the MAC address for the destination power line carrier communication and transfers the received communication signal of the power line carrier communication to the power line carrier communication transceiver unit of the determined identifier;
MAC address of the power line carrier communication, the power line carrier power line communication bridge and wherein the physical address der Rukoto that is used to send and receive communication signals in a communication layer. The power line carrier communication bridge device according to claim 1, wherein frequencies used for power line carrier communication in the plurality of power line carrier communication transceiver units are different from each other. The transmission frequency used for power line carrier communication in the power line carrier communication transceiver unit is different from the transmission frequency used for power line carrier communication in a power line carrier communication terminal connected to the power line carrier transceiver unit. The bridge device for power line carrier communication according to claim 1 or claim 2. When the MAC address corresponding to the destination MAC address for power line carrier communication accommodated in the header for power line carrier communication in the communication signal of the received power line carrier communication is not in the correspondence relationship, the bridge processing unit Searching for the power line carrier communication transceiver unit to which the communication terminal of the power line carrier communication having the MAC address for the destination power line carrier communication is connected, and the identifier of the searched power line carrier communication transceiver unit and the destination power line carrier The power line carrier communication bridge device according to any one of claims 1 to 3, wherein a MAC address for communication is associated and stored in the transfer destination information storage unit as the correspondence relationship. Is taken out the header of the power line carrier communication by separating the communication signal of the power line communication by adding a header of a power line carrier communication to communication signals in an upper layer than the power line communication from the power line, the power line communication signal of the power line communication A power line carrier communication MAC in a power line carrier communication terminal connected to the power line carrier communication transceiver unit, a plurality of power line carrier communication transceiver units superimposed on the power line carrier communication identifier, and an identifier for identifying the power line carrier communication transceiver unit A transfer destination information storage unit that stores a correspondence relationship with an address, and a bridge processing unit that transfers a communication signal of power line carrier communication between the plurality of power line carrier communication transceiver units, and the MAC address for power line carrier communication is , physical address der Ru power line communication bridge to be used to send and receive communication signals in the power line communication layer In the relay method of location,
When the power line carrier communication signal is received by the power line carrier communication transceiver unit, the power line carrier communication transceiver unit separates the power line carrier communication signal from the power line, and
Step of taking out the header for power line carrier communication from the communication signal of the separated power line carrier communication by the power line carrier communication transceiver unit;
Corresponding to the MAC address for power line carrier communication of the destination accommodated in the header for power line carrier communication taken out by referring to the correspondence relationship stored in the transfer information storage unit by the bridge processing unit Determining the identifier to be
Transferring the received communication signal of the power line carrier communication to the power line carrier communication transceiver unit of the determined identifier by the bridge processing unit;
The relay method for the power line carrier communication bridge device, comprising: superimposing the transferred communication signal of the power line carrier communication on the power line by the power line carrier communication transceiver unit having the determined identifier.

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