JP2021108435A - Superimposition device, and communication system - Google Patents

Abstract

To improve the reliability of communication.SOLUTION: A superimposition device 2 includes a power line connector 21 and a transmission line connector 22. The power line connector 21 is connected to a power line L20 for transmitting power in a facility. The transmission line connector 22 is connected to a double-wired transmission line L1 which is different from the power line L20. The superimposition device 2 transmits communication signals S1 in a frequency band different from the power frequency unidirectionally or bi-directionally between the power line connector 21 and the transmission line connector 22.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a superimposition device and a communication system, and more particularly to a superimposition device interposed between a power line and a transmission line, and a communication system including the superimposition device.

Patent Document 1 discloses a communication system.

This communication system is applied to buildings such as apartment houses and buildings that include a plurality of consumers. In this communication system, a slave unit and a controller are installed in each consumer. The slave unit has the function of a watt hour meter (measuring device). The slave unit measures the power consumption of each consumer and generates meter reading data according to the measurement result at regular time intervals. The slave unit transmits the generated meter reading data to the master unit and the controller by power line carrier communication (PLC) via the distribution system. One master unit is provided for each of the plurality of slave units, and meter reading data for each slave unit is acquired. The controller is housed in the distribution board into which the distribution system is drawn in for each customer. The controller acquires various data such as meter reading data from the slave unit of each customer, and uses this data to control the equipment in the customer and display the meter reading data on the monitor.

JP-A-2015-95878

Power lines are not necessarily intended to be used for the transmission of communication signals. Therefore, in a communication system using power line carrier communication, the signal may be attenuated during transmission of the signal via the power line. Therefore, in a communication system as described in Patent Document 1, there is room for improvement in communication reliability.

An object of the present disclosure is to provide a superimposition device and a communication system capable of improving the reliability of communication.

The superimposing device according to one aspect of the present disclosure includes a power line connector and a transmission line connector. The power line connector is connected to a power line that transmits power in the facility. The transmission line connector is connected to a two-wire transmission line different from the power line. The superimposing device transmits a communication signal in a frequency band different from the frequency of the power between the power line connector and the transmission line connector in one direction or in both directions.

The communication system according to one aspect of the present disclosure includes the superimposing device, a first terminal connected to the transmission line to transmit or receive the communication signal, and a second terminal connected to the power line to transmit or receive the communication signal. , Equipped with.

The present disclosure has an advantage that it is possible to improve the reliability of communication.

FIG. 1 is an explanatory diagram showing an outline of a facility in which the communication system of the embodiment is provided. FIG. 2 is a block diagram showing a configuration of a subsystem in the same communication system. FIG. 3 is a block diagram showing the configuration of the same communication system. FIG. 4 is a block diagram showing a configuration of a superimposing device in the same communication system. FIG. 5 is a schematic view showing an example of the above-mentioned superimposing device.

Hereinafter, the superimposing device and the communication system according to the embodiment of the present disclosure will be described with reference to the accompanying drawings. However, the following embodiments are only part of the various embodiments of the present disclosure. Each of the following embodiments can be changed in various ways depending on the design and the like as long as the object of the present disclosure can be achieved. Further, each figure described in each of the following embodiments is a schematic view, and the ratio of the size and the thickness of each component in the figure does not always reflect the actual dimensional ratio. do not have.

(1) Outline The communication system 100 of the present embodiment is provided in, for example, an apartment house 500 as a facility. The apartment house 500 includes a manager's room 510 and a plurality of dwelling units 520.

In the apartment house 500, for example, the switchboard 210 is provided in the manager's room 510. Further, each of the plurality of dwelling units 520 is provided with a distribution board 220. The distribution board 210 and the distribution board 220 of the plurality of dwelling units 520 are connected by a power line (outdoor wiring) L2 wired to the outside of the dwelling unit 520 in the housing complex 500. The distribution board 210 distributes electric power (AC power) from a power system 200 such as a commercial power source to a plurality of dwelling units 520 (distribution board 220) via a power line L2. The frequency of the AC power transmitted by the power line L2 is 50 Hz or 60 Hz.

As shown in FIG. 1, the communication system 100 includes a master unit (first terminal) 110, a plurality of subsystems 120, and a transmission line L1. In FIG. 1, for convenience, the transmission line L1 is shown by a dotted line and the power line L2 is shown by a solid line.

The master unit 110 is provided in, for example, the manager's room 510. The master unit 110 is connected to the switchboard 210 via the power line L2. Power is supplied to the master unit 110 from the power system 200 via the power line L2 and the switchboard 210.

Each of the plurality of subsystems 120 is provided in, for example, each dwelling unit 520 of the apartment house 500.

As shown in FIG. 2, each of the plurality of subsystems 120 includes one or more slave units (second terminals) 1, a superimposing device 2, and a power line (indoor wiring) L20. In FIG. 2, for convenience, the transmission line L1 and the signal line L10 are shown by dotted lines, and the power lines L2 and L20 are shown by solid lines.

The slave unit 1 is connected to the distribution board 220 via the power line L20. Power is supplied to the slave unit 1 from the power system 200 via the power line L20, the distribution board 220, the power line L2, and the distribution board 210. In the subsystem 120, one or more slave units 1 are connected via a power line L20.

Further, the slave unit 1 has a function of power line carrier communication for communicating via the power line L20. The slave unit 1 transmits and receives the communication signal S1 via the power line L20. The frequency band of the communication signal S1 is different (not overlapping) from the frequency (50 Hz or 60 Hz) of the power (AC power) transmitted by the power line L20. Here, the frequency band of the communication signal S1 is, for example, a frequency band used in high-speed power line communication (HD-PLC: High Definition Power Line Communication), and is 2 MHz to 30 MHz. That is, the frequency band of the communication signal S1 is in a higher frequency region than the frequency of electric power.

The communication signal S1 is transmitted in the subsystem 120 via the power line L20.

As shown in FIG. 4, the superimposing device 2 includes a power line connector 21 and a transmission line connector 22.

The power line connector 21 is connected to the power line L20. The power line connector 21 is connected to the slave unit 1 via the power line L20 (see FIG. 2).

The transmission line connector 22 is connected to the transmission line L1. The transmission line connector 22 is connected to the master unit 110 via the transmission line L1 (see FIG. 1).

The transmission line L1 is a two-wire communication line different from the power lines (L2 and L20). The transmission line L1 is connected to the master unit 110. The transmission line L1 is connected to a plurality of subsystems 120 (more specifically, a superimposition device 2 of each of the subsystems 120). That is, the plurality of subsystems 120 are connected to the master unit 110 via the transmission line L1.

The master unit 110 has a function of transmitting and receiving a communication signal S1 to and from a plurality of subsystems 120 via a transmission line L1.

The communication signal S1 is transmitted between the master unit 110 and the plurality of subsystems 120 via the transmission line L1.

The superimposing device 2 transmits the communication signal S1 received from the master unit 110 connected to the transmission line L1 via the transmission line connector 22 from the power line connector 21 to the power line L20. Further, the superimposing device 2 transmits the communication signal S1 received from the slave unit 1 connected to the power line L20 via the power line connector 21 from the transmission line connector 22 to the transmission line L1. In short, the superimposing device 2 unidirectionally or bidirectionally transmits a communication signal S1 in a frequency band different from the power frequency between the power line connector 21 and the transmission line connector 22, that is, between the power line L20 and the transmission line L1. (Here, bidirectional) is transmitted.

Since the communication system 100 of the present embodiment includes the superimposing device 2, it is possible to transmit the communication signal S1 via a path including the power line L20 and the transmission line L1. Therefore, as compared with the case where the communication signal S1 is transmitted only through the power lines L2 and L20, for example, the signal attenuation can be suppressed, and the reliability of communication can be improved.

(2) Details The superimposing device 2 and the communication system 100 of the present embodiment will be described in more detail with reference to FIGS. 1 to 5.

(2.1) Communication system The communication system 100 includes a superimposing device 2, a slave unit (first terminal) 1, and a master unit (second terminal) 110. As described above, the communication system 100 of the present embodiment can be used in the apartment house 500 as a facility. The facility in which the communication system 100 is used is not limited to the collective housing 500, and may be a detached house or a non-residential house such as a store, an office, or a factory.

As described above, the apartment house 500 includes a manager's room 510 and a plurality of dwelling units 520. A switchboard 210 and a master unit 110 are provided in the manager's room 510.

The switchboard 210 includes monitoring and control equipment (instruments, switches, relays, etc.) and main circuit equipment (circuit breakers, disconnectors, load switches, transformers, etc.). The switchboard 210 is connected to the power system 200. Further, the switchboard 210 is connected to the power line L2. The distribution board 210 transforms the power (AC power) from the power system 200 (power plant) and distributes the transformed power to the distribution board 220 of the dwelling unit 520 via the power line L2. The switchboard 210 may be arranged in a space other than the manager's room 510 in the facility (dwelling 500), or may be arranged outside the facility.

The master unit 110 operates by the electric power supplied from the switchboard 210.

The master unit 110 is connected to the communication network NT1. The communication network NT1 may include the Internet. The communication network NT1 may be composed of not only a network compliant with a single communication protocol but also a plurality of networks compliant with different communication protocols. The communication protocol can be selected from a variety of well-known wired and wireless communication standards. Although simplified in FIG. 1, the communication network NT1 may include data communication devices such as repeater hubs, switching hubs, bridges, gateways, routers and the like.

Further, the master unit 110 is connected to the transmission line L1. The transmission line L1 is a coaxial cable here. A coaxial cable is a cable that includes an inner conductor (center line) having a circular cross section and a cylindrical outer conductor that concentrically surrounds the inner conductor, and the inner conductor and the outer conductor are insulated by an insulator. Coaxial cable further includes a sheath covering the outer conductor.

As the transmission line L1, for example, a coaxial cable used for transmitting a signal of television broadcasting can also be used. The television broadcast signal includes, for example, a terrestrial digital television broadcast signal. The frequency band of the signal of terrestrial digital television broadcasting is, for example, 470 MHz to 770 MHz. That is, a second communication signal (television broadcast signal) S2 having a frequency band different from the frequency band of the communication signal (first communication signal) S1 is transmitted to the transmission line L1 (see FIG. 2). In the present embodiment, the frequency band of the second communication signal S2 does not overlap with the frequency band of the first communication signal S1. The transmission line L1 is connected to, for example, the television antenna 9, and the television broadcast signal (second communication signal S2) received by the television antenna 9 is transmitted.

By using the coaxial cable used for transmitting the signal of television broadcasting as the transmission line L1, it is possible to save the trouble of newly laying the transmission line L1. The signal of the television broadcast may include a signal of a cable television independent broadcast or the like in place of or in addition to the signal of the terrestrial digital television broadcast.

The master unit 110 transmits / receives data to / from the slave unit 1 using the communication signal S1. The master unit 110 transmits the data included in the communication signal S1 received from the slave unit 1 to an external server via the communication network NT1. Further, the master unit 110 receives data from an external server via the communication network NT1 and transmits the received data to the slave unit 1 using the communication signal S1.

As shown in FIG. 3, the master unit 110 includes a communication unit 111, a control unit 112, and a storage unit 113.

The communication unit 111 includes a communication module for communicating with the slave unit 1 using the communication signal S1. The communication unit 111 has a function of modulation and demodulation, and transmits the communication signal S1 in which the data is modulated from the transmission line L1 or demodulates the communication signal S1 received from the transmission line L1 to receive the data. do. Further, the communication unit 111 communicates with an external device via the communication network NT1. The communication unit 111 can transmit and receive various data to and from an external device connected to the communication network NT1.

The storage unit 113 has, for example, a non-volatile semiconductor memory such as a flash memory. The storage unit 113 stores parameters and the like used for communication using the communication signal S1.

The control unit 112 mainly includes a computer system having one or more processors and memories. The function as the control unit 112 is realized by executing the program recorded in the memory by one or more processors. The program may be pre-recorded in a memory, provided through a telecommunication line such as the Internet, or may be recorded and provided on a non-temporary recording medium such as a memory card.

The control unit 112 controls the communication unit 111 to transmit the communication signal S1 to the transmission line L1. Further, the control unit 112 controls the communication unit 111 to receive the communication signal S1 from the transmission line L1. Further, the control unit 112 controls the communication unit 111 to transmit and receive various data to and from an external device connected to the communication network NT1.

(2.2) Subsystem As shown in FIG. 2, each dwelling unit 520 in the facility 500 is provided with a subsystem 120. Further, each dwelling unit 520 is provided with a distribution board 220.

The distribution board 220 is attached to the wall or the like of the dwelling unit 520. The distribution board 220 includes a main breaker (leakage circuit breaker), a plurality of branch breakers, a power measuring device, and the like.

The distribution board 220 is connected to the power line L2. The distribution board 220 receives power from the distribution board 210 via the power line L2. Further, the distribution board 220 is connected to the power line L20. The distribution board 220 supplies electric power to the electric load arranged in the dwelling unit 520 via the power line L20. The power line L20 may include an outlet or the like provided on the wall of the dwelling unit 520.

The subsystem 120 includes one or more slave units (three in the example of FIG. 2) and a superimposing device 2. The distribution board 220 may or may not be included in the subsystem 120.

Each of the one or more slave units 1 is connected to the power line L20. The slave unit 1 receives power from the distribution board 220 via the power line L20. The slave unit 1 operates by the electric power supplied from the distribution board 220. Further, the slave unit 1 transmits and receives the communication signal S1 via the power line L20.

As shown in FIG. 3, the slave unit 1 includes a communication unit 11, a control unit 12, a storage unit 13, and a functional unit 14.

The communication unit 11 includes a communication module for communicating with the communication unit 111 of the master unit 110 by using the communication signal S1. The communication unit 11 has a function of modulation and demodulation, and transmits the communication signal S1 in which the data is modulated from the power line L20, or demodulates the communication signal S1 received from the power line L20 and receives the data.

The storage unit 13 has, for example, a non-volatile semiconductor memory such as a flash memory. The storage unit 13 stores parameters and the like used for communication using the communication signal S1.

The functional unit 14 is an element for realizing various functions assigned to the slave unit 1. The functions realized by the functional unit 14 may be common to each slave unit 1 or may be different from each other. The functional unit 14 includes, for example, a sensor. The sensor may include, for example, a temperature sensor, a motion sensor, a power sensor, and the like. Further, the functional unit 14 includes, for example, a wireless communication module that communicates using radio waves as a transmission medium. The wireless communication module may include, for example, a communication module of a communication method conforming to a standard such as Wi-fi (registered trademark).

The control unit 12 mainly comprises a computer system having one or more processors and memories. The function as the control unit 12 is realized by executing the program recorded in the memory by one or more processors. The program may be pre-recorded in a memory, provided through a telecommunication line such as the Internet, or may be recorded and provided on a non-temporary recording medium such as a memory card.

The control unit 12 controls the communication unit 11 to transmit the communication signal S1 to the power line L20. Further, the control unit 12 controls the communication unit 11 to receive the communication signal S1 from the power line L20. Further, the control unit 12 controls the function unit 14 to realize various functions. For example, when the functional unit 14 includes a sensor, the control unit 12 acquires the data detected by the sensor from the sensor. For example, when the functional unit 14 includes a wireless communication module, the control unit 12 causes wireless communication to be performed between the electric load arranged in the dwelling unit 520 and the wireless communication module.

The slave unit 1 receives power supply via the power line L20, and transmits / receives the communication signal S1 via the power line L20. Therefore, the slave unit 1 can be arranged and used at an arbitrary position in the dwelling unit 520. That is, in the communication system 100 of the present embodiment, the degree of freedom in the arrangement of the slave unit (second terminal) 1 is improved by performing the power line carrier communication using the power line L20 in the subsystem 120. Further, since the communication signal S1 can be transmitted and received only by connecting the slave unit 1 to the power line L20 (connecting to the outlet), it is easy to change the number of slave units 1 in the subsystem 120.

(2.3) Superimposition device Hereinafter, the superimposition device 2 of the present embodiment will be described in more detail with reference to FIGS. 4 and 5.

The superimposing device 2 can be attached to the wall of the dwelling unit 520, for example, by using a device for attaching a wiring device. That is, in the present embodiment, the superimposing device 2 is a wiring device provided on the wall of the facility.

As described above, the superimposing device 2 includes a power line connector 21 and a transmission line connector 22. The superimposing device 2 transmits the communication signal S1 in both directions between the power line connector 21 and the transmission line connector 22. In other words, the superimposing device 2 bridges the communication signal S1 between the power line L20 and the transmission line L1. The superimposing device 2 superimposes the first communication signal S1 from the power line L20 on the second communication signal S2 transmitted on the transmission line L1. Further, the superimposition device 2 superimposes the first communication signal S1 from the transmission line L1 on the power (AC power) transmitted by the power line L20.

Further, as shown in FIG. 4, the superimposing device 2 further includes a signal line connector 23. The superimposing device 2 transmits the second communication signal S2 from the transmission line connector 22 to the signal line connector 23.

Further, as shown in FIG. 4, the superimposing device 2 further includes an impedance matching unit 24, a first filter 25, and a second filter 26.

The transmission line L1 is connected to the transmission line connector 22. The transmission line connector 22 includes, for example, an F-type connector. An F-type connector provided at one end of the transmission line L1 is connected to the F-type connector.

The power line connector 21 is connected to the transmission line connector 22. Here, the power line connector 21 is connected to the transmission line connector 22 via the impedance matching unit 24 and the second filter 26. The power line L20 is connected to the power line connector 21. The power line connector 21 includes a pair of terminals to which a pair of electric wires of the power line L20 are connected. The terminal includes, for example, a quick connection terminal.

The signal line connector 23 is connected to the transmission line connector 22. Here, the signal line connector 23 is connected to the transmission line connector 22 via the first filter 25. A signal line L10 for transmitting the second communication signal S2 is connected to the signal line connector 23. The second communication signal S2 input to the transmission line connector 22 is output from the signal line connector 23. The signal line L10 is a communication line different from the transmission line L1 and is wired in the dwelling unit 520. The signal line L10 is a coaxial cable here. The signal line connector 23 includes, for example, an F-type connector. An F-type connector provided at one end of the signal line L10 is connected to the F-type connector.

As shown in FIG. 2, the signal line L10 is connected to the processing device 3 provided in the dwelling unit 520. The processing device 3 receives the second communication signal S2 from the superimposing device 2 via the signal line L10. The processing device 3 is a television device here. The television device receives a signal of terrestrial digital television broadcasting as a second communication signal S2 via a transmission line L1, a superimposing device 2, and a signal line L10, and displays an image based on the received signal.

The impedance matching unit 24 is interposed between the power line connector 21 and the transmission line connector 22. The impedance matching unit 24 has the characteristic impedance of the circuit on the power line L20 side connected to the power line connector 21 and the transmission connected to the transmission line connector 22 at least in the frequency band (2 MHz to 30 MHz) of the first communication signal S1. Match with the characteristic impedance of the circuit on the line L1 side. The impedance matching unit 24 can be realized by a well-known configuration such as a transformer (transformer) or a matching circuit including a coil and a capacitor.

The first filter 25 is interposed between the transmission line connector 22 and the signal line connector 23. The first filter 25 attenuates at least a signal having a component in the frequency band (2 MHz to 30 MHz) of the first communication signal S1 among the signals input to the first filter 25. Further, the first filter 25 transmits a signal of a component in the frequency band (470 MHz to 770 MHz) of the second communication signal S2. The first filter 25 may include, for example, a high-pass filter or a band-pass filter. The high-pass filter and the band-pass filter can be realized by an appropriate combination of circuit elements such as a coil, a capacitor, and a resistor.

The first communication signal S1 input from the transmission line L1 to the transmission line connector 22 is attenuated by the first filter 25 to the extent that it hardly reaches the signal line connector 23. On the other hand, the second communication signal S2 input from the transmission line L1 to the transmission line connector 22 passes through the first filter 25 and is output from the signal line connector 23 to the signal line L10. That is, of the first communication signal S1 and the second communication signal S2 input from the transmission line L1 to the transmission line connector 22, substantially only the second communication signal S2 is output from the signal line connector 23 to the signal line L10. Will be done.

The superimposition device 2 of the present embodiment does not include an amplifier that amplifies a signal, a modulator that modulates a signal, or the like. Therefore, the second communication signal S2 input to the transmission line connector 22 is output from the signal line connector 23 as it is or slightly attenuated in the superimposing device 2. In other words, the superimposing device 2 transmits the second communication signal S2 from the transmission line L1 to the signal line L10 without amplifying it.

The second filter 26 is interposed between the transmission line connector 22 and the power line connector 21. The second filter 26 attenuates at least the signal of the frequency band (470 MHz to 770 MHz) of the second communication signal S2 among the signals input to the second filter 26. Further, the second filter 26 transmits a signal of a component in the frequency band (2 MHz to 30 MHz) of the first communication signal S1. The second filter 26 may include, for example, a low-pass filter or a band-pass filter. A low-pass filter and a band-pass filter can be realized by an appropriate combination of circuit elements such as coils, capacitors, and resistors.

The first communication signal S1 input from the transmission line L1 to the transmission line connector 22 passes through the second filter 26 and is output from the power line connector 21 to the power line L20. On the other hand, the second communication signal S2 input from the transmission line L1 to the transmission line connector 22 is attenuated by the second filter 26 to the extent that it hardly reaches the power line connector 21. That is, of the first communication signal S1 and the second communication signal S2 input from the transmission line L1 to the transmission line connector 22, substantially only the first communication signal S1 is output from the power line connector 21 to the power line L20. ..

Further, the first communication signal S1 input from the power line L20 to the power line connector 21 passes through the second filter 26 and is output from the transmission line connector 22 to the transmission line L1. That is, the first communication signal S1 input from the power line L20 to the power line connector 21 is output from the transmission line connector 22 to the transmission line L1.

The superimposition device 2 of the present embodiment does not include an amplifier that amplifies a signal, a modulator that modulates a signal, or the like. Therefore, the first communication signal S1 input to the transmission line connector 22 is output from the power line connector 21 as it is or slightly attenuated in the superimposing device 2. Further, the first communication signal S1 input to the power line connector 21 is output from the transmission line connector 22 as it is or slightly attenuated in the superimposing device 2. In other words, the superimposing device 2 transmits the first communication signal S1 from the transmission line L1 to the power line L20 without amplifying it. Further, the superimposing device 2 transmits the first communication signal S1 from the power line L20 to the transmission line L1 without amplifying it.

In one specific example, the impedance matching unit 24, the first filter 25, and the second filter 26 are realized by using the transformer 20.

As shown in FIG. 5, the transformer 20 includes a first winding L101, a second winding L102, and a third winding L103 that are magnetically coupled. For example, the first winding L101, the second winding L102, and the third winding L103 are wound around the same core. The first winding L101 is connected between a pair of electric wires of the power line connector 21. The second winding L102 is connected between a pair of electric wires of the transmission line connector 22. The third winding L103 is connected between a pair of electric wires of the signal line connector 23.

The turns ratio between the first winding L101 and the second winding L102 is the characteristic impedance of the circuit on the power line L20 side connected to the power line connector 21 and the circuit on the transmission line L1 side connected to the transmission line connector 22. Is set to match the characteristic impedance of. In short, the first winding L101 and the second winding L102 of the transformer 20 function as an impedance matching unit 24. Similarly, the turn ratio between the first winding L101 and the third winding L103 is also the characteristic impedance of the circuit on the transmission line L1 side connected to the transmission line connector 22 and the signal connected to the signal line connector 23. The characteristic impedance of the circuit on the line L10 side is set to match.

Between the first winding L101 and the power line connector 21, an appropriate circuit element that constitutes the second filter 26 together with the first winding L101 (for example, a capacitor that constitutes a bandpass filter together with the first winding L101). Can be connected. The number of turns (inductance) of the first winding L101 and the characteristics of the circuit element (capacitor capacity, etc.) are such that the second filter 26 that transmits the first communication signal S1 and blocks the second communication signal S2 is realized. Is set to.

Between the third winding L103 and the signal line connector 23, an appropriate circuit element (for example, a capacitor forming a bandpass filter together with the third winding L103) forming the first filter 25 together with the third winding L103, etc. ) Can be connected. The number of turns (inductance) of the third winding L103 and the characteristics of the circuit element (capacitor capacity, etc.) are such that the first filter 25 that blocks the first communication signal S1 and transmits the second communication signal S2 is realized. Is set to.

The circuit element connected to the first winding L101 is not indispensable. Only the first winding L101 may be connected to the power line connector 21. The inductor component of the first winding L101 makes it possible to reduce noise at a higher frequency than the frequency bands of the first communication signal S1 and the second communication signal S2. The first winding L101 can function as a noise filter. The circuit element connected to the third winding L103 is also not essential. Only the third winding L103 may be connected to the signal line connector 23.

In short, the superimposing device 2 of one specific example is interposed between the power line L20 and the transmission line L1, and the transformer 20 for matching the characteristic impedance of the circuit including the power line L20 with the characteristic impedance of the circuit including the transmission line L1. It has. The transformer 20 constitutes a part of the first filter 25 or the second filter 26.

As described above, the communication system 100 of the present embodiment includes the superimposing device 2. Therefore, the communication signal S1 can be transmitted between the master unit 110 and the subsystem 120 via the transmission line L1, and the communication signal S1 can be transmitted via the power line L20 in the subsystem 120. That is, in the communication system 100, the communication signal S1 can be transmitted via the path including the power line L20 and the transmission line L1. Therefore, as compared with the case where the communication signal S1 is transmitted only through the power lines L2 and L20, for example, the attenuation of the communication signal S1 can be suppressed, and the reliability of communication can be improved.

(3) Modifications Each of the above embodiments is only one of the various embodiments of the present disclosure. The above-described embodiment can be changed in various ways depending on the design and the like as long as the object of the present disclosure can be achieved. Hereinafter, modifications of the above-described embodiment will be listed. The modifications described below can be applied in combination as appropriate.

In one modification, the transmission line L1 is not limited to the coaxial cable used for transmitting a television broadcast signal, and may be a two-wire transmission line used for transmitting other signals. Further, the transmission line L1 may be a dedicated transmission line for the first communication signal S1, that is, a transmission line to which only the first communication signal S1 is transmitted.

In one modification, the superimposing device 2 may be integrated with the slave unit 1. For example, in one housing, an element as a slave unit 1 (communication unit 11, a control unit 12, a storage unit 13, and a function unit 14) and an element as a superimposing device 2 (power line connector 21, transmission line connector 22, The signal line connector 23, the impedance matching unit 24, the first filter 25, and the second filter 26) may be mounted. The functional unit 14 of the slave unit 1 integrated with the superimposing device 2 may be a wireless communication module.

In one modification, the superimposing device 2 is between the first amplifier that amplifies the first communication signal S1 transmitted between the transmission line L1 and the power line L20 and / or between the transmission line L1 and the signal line L10. A second amplifier that amplifies the second communication signal S2 to be transmitted may be provided.

In one modification, the superimposing device 2 may further include one or more outlets (outlets) connected to the power line connector 21. An electrical device plug is connected to the outlet. In this case, the superimposing device 2 does not output the communication signal S1 to the power line L20 connected to the distribution board 220 by an appropriate filter, and outputs the communication signal S1 to the power line L20 connected to the outlet. It may be configured as such.

In one modification, the superimposing device 2 may be arranged in the space inside the dwelling unit 520. That is, the superimposing device 2 may be arranged inside the facility. For example, the superimposing device 2 has a structure in which a power line connector 21 and a transmission line connector 22 are connected to an outlet and a television outlet (F-type tangent of a coaxial cable) provided side by side on the wall of the dwelling unit 520. You may be.

In one modification, the superimposing device 2 may include a plurality of signal line connectors 23. In this case, the superimposing device 2 can also function as a so-called distributor.

(3) Summary The following aspects are disclosed from the embodiments and modifications described above.

The superimposing device (2) of the first aspect includes a power line connector (21) and a transmission line connector (22). The power line connector (21) is connected to a power line (L20) that transmits power in the facility (dwelling 500). The transmission line connector (22) is connected to a two-wire transmission line (L1) different from the power line (L20). The superimposing device (2) transmits a communication signal (S1) in a frequency band different from the power frequency between the power line connector (21) and the transmission line connector (22) in one direction or in both directions.

According to this aspect, by using the superimposing device (2), it is possible to transmit the communication signal (S1) via the path including the power line (L20) and the transmission line (L1). Therefore, it is possible to improve the reliability of communication as compared with the case where the communication signal (S1) is transmitted only through the power line, for example.

In the superimposing device (2) of the second aspect, in the first aspect, the transmission line (L1) is a coaxial cable.

According to this aspect, the transmission efficiency of the communication signal (S1) can be improved, particularly when the communication signal (S1) is a high-frequency signal.

In the superimposing device (2) of the third aspect, in the first or second aspect, the transmission line (L1) has a frequency different from the frequency band of the first communication signal (S1) as the communication signal (S1). The second communication signal (S2) of the band is transmitted. The superimposing device (2) superimposes the first communication signal (S1) from the power line (L20) on the second communication signal (S2).

According to this aspect, for example, the first communication signal (S1) can be transmitted by using the transmission line (L1) laid for the transmission of the second communication signal (S2), and the transmission line (S1) can be transmitted. The trouble of newly laying L1) can be saved.

In the superimposing device (2) of the fourth aspect, in the third aspect, the first filter (25) for attenuating the first communication signal (S1) and the second filter (26) for attenuating the second communication signal (S2). ) And at least one of them are further provided.

According to this aspect, it is possible to block the transmission of an unnecessary signal among the first communication signal (S1) and the second communication signal (S2). The first filter (25) preferably transmits the first communication signal (S1). Further, it is preferable that the second filter (26) transmits the second communication signal (S2).

The superimposing device (2) of the fifth aspect includes a transformer (20) in the fourth aspect. The transformer (20) is interposed between the power line (L20) and the transmission line (L1). The transformer (20) matches the characteristic impedance of the circuit including the power line (L20) with the characteristic impedance of the circuit including the transmission line (L1). The transformer (20) constitutes a part of the first filter (25) or the second filter (26).

According to this aspect, impedance matching and unwanted signal attenuation can be achieved using the transformer (20).

The superimposing device (2) of the sixth aspect further includes a signal line connector (23) in any one of the third to fifth aspects. The signal line connector (23) is connected to the signal line (L10) that transmits the second communication signal (S2). The signal line (L10) is different from the transmission line (L1).

According to this aspect, the signal line (L10) can be detachably connected to the superimposing device (2).

The superimposing device (2) of the seventh aspect further includes an outlet electrically connected to the power line connector (21) in any one of the first to sixth aspects. An electrical device plug is connected to the outlet.

According to this aspect, it is possible to supply electric power to the electric device via the superimposing device (2).

In the superimposing device (2) of the eighth aspect, in any one of the first to seventh aspects, the superimposing device (2) is a wiring device provided on the wall of the facility.

According to this aspect, the space of the facility can be effectively used.

In the superimposing device (2) of the ninth aspect, in any one of the first to eighth aspects, the superimposing device (2) is arranged inside the facility.

According to this aspect, the degree of freedom of arrangement of the superimposing device (2) is improved.

In the superimposing device (2) of the tenth aspect, in any one of the first to ninth aspects, the superimposing device (2) moves from one of the power line (L20) and the transmission line (L1) to the other. , The communication signal (S1) is transmitted without being amplified.

According to this aspect, it is possible to simplify the configuration of the superimposing device (2).

The communication system (100) of the eleventh aspect is connected to the superimposing device (2) of any one of the first to tenth aspects and the transmission line (L1) to transmit or receive the communication signal (S1). It includes a terminal (master unit 110) and a second terminal (slave unit 1) that is connected to a power line (L20) and transmits or receives a communication signal (S1).

According to this aspect, by using the superimposing device (2), it is possible to transmit the communication signal (S1) via the path including the power line (L20) and the transmission line (L1). Therefore, it is possible to improve the reliability of communication as compared with the case where the communication signal (S1) is transmitted only through the power line, for example.

The communication system (100) of the twelfth aspect includes a plurality of subsystems (120) in the eleventh aspect. Each of the subsystems (120) includes one or more second terminals (slave units 1). In each of the subsystems (120), one or more second terminals are connected via a power line (L20). The plurality of subsystems (120) are connected to the first terminal (master unit 110) via a transmission line (L1).

According to this aspect, the communication signal (S1) can be transmitted and received between the first slave unit (master unit 110) and the subsystem (120) by the transmission line (L1), so that the transmission efficiency of the communication signal (S1) is high. Can be improved. Further, since the communication signal (S1) can be transmitted and received by the power line (L20) in the subsystem (120), the degree of freedom in arranging the second terminal in the area (dwelling unit 520) in which the subsystem (120) is provided. Will increase.

1 Slave unit (second terminal)
2 Superimposition device 20 Transformer 21 Power line connector 22 Transmission line connector 23 Signal line connector 25 1st filter 26 2nd filter 100 Communication system 110 Master unit (1st terminal)
120 Subsystem L1 Transmission line L10 Signal line L20 Power line S1 Communication signal (1st communication signal)
S2 2nd communication signal

Claims (12)

A power line connector connected to a power line that transmits power in the facility,
A transmission line connector connected to a two-wire transmission line different from the power line,
With
A communication signal in a frequency band different from the frequency of the power is transmitted between the power line connector and the transmission line connector in one direction or in both directions.
Superimposition device. The transmission line is a coaxial cable.
The superimposing device according to claim 1. A second communication signal having a frequency band different from the frequency band of the first communication signal as the communication signal is transmitted to the transmission line.
The superimposing device superimposes the first communication signal from the power line on the second communication signal.
The superimposing device according to claim 1 or 2. At least one of a first filter that attenuates the first communication signal and a second filter that attenuates the second communication signal is further provided.
The superimposing device according to claim 3. A transformer is provided between the power line and the transmission line to match the characteristic impedance of the circuit including the power line with the characteristic impedance of the circuit including the transmission line.
The transformer constitutes a part of the first filter or the second filter.
The superimposing device according to claim 4. A signal line connector different from the transmission line and connected to the signal line for transmitting the second communication signal is further provided.
The superimposing device according to any one of claims 3 to 5. An outlet that is electrically connected to the power line connector and to which a plug of an electric device is connected is further provided.
The superimposing device according to any one of claims 1 to 6. The superimposing device is a wiring device provided on the wall of the facility.
The superimposing device according to any one of claims 1 to 7. The superimposing device is arranged inside the facility.
The superimposing device according to any one of claims 1 to 8. The superimposing device transmits the communication signal from one of the power line and the transmission line to the other without amplifying the communication signal.
The superimposing device according to any one of claims 1 to 9. The superimposing device according to any one of claims 1 to 10,
A first terminal connected to the transmission line and transmitting or receiving the communication signal,
A second terminal connected to the power line and transmitting or receiving the communication signal,
To prepare
Communications system. Each of which has a plurality of subsystems each having one or more of the second terminals.
In each of the plurality of subsystems, the one or more second terminals are connected via the power line.
The plurality of subsystems are connected to the first terminal via the transmission line.
The communication system according to claim 11.

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