JP2016100755A - Power line communication device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption at the time of master search operation.SOLUTION: A power line communication device functions as part or all of a terminal that mutually communicates with a master terminal via a power line. When the power line communication device cannot receive a beacon (BCN) from the master terminal, it maintains a reception standby state (STBY) over a first prescribed time T1, and then becomes to be in an intermittent search mode while repeating a sleep state (SLP) over a second prescribed time T2 and a reception standby state (STBY) over a third prescribed time T3.SELECTED DRAWING: Figure 12

Description

  The present invention relates to a power line communication device (PLC [power line communication] baseband LSI, PLC adapter, etc.).

  In recent years, power line communication devices that perform mutual communication between a master and a terminal via a power line have been put into practical use.

  In addition, Patent Document 1 and Patent Document 2 can be cited as examples of the related art (utilization example of a beacon) related to the above.

JP2012-150285A (paragraph 0038, etc.) JP2013-146048A (paragraph 0093 etc.)

  However, the conventional power line communication apparatus has a problem that it takes time for the pairing operation and a problem that power consumption during the master search operation increases.

  In view of the above-mentioned problems found by the inventors of the present application, the invention disclosed in the present specification provides a power line communication device capable of realizing an automatic pairing operation with a master terminal. Objective.

  In addition, the invention disclosed in the present specification provides a power line communication device capable of reducing power consumption during a master search operation in view of the above-described problems found by the inventors of the present application. With the goal.

  The power line communication device disclosed in the present specification functions as part or all of a terminal terminal that performs mutual communication with a master terminal via a power line, and receives a beacon via the power line. In some cases, the connection sequence for establishing pairing with the master terminal is started (first configuration).

  Note that the power line communication device having the first configuration has a configuration (second configuration) for starting the connection sequence when receiving a beacon from a different master terminal even when paired with a certain master terminal. Good.

  The power line communication device having the first or second configuration may be configured to cancel the current pairing state (third configuration) when a reset command is received.

  The power line communication apparatus having the third configuration may be configured to receive the reset command via the power line (fourth configuration).

  In addition, when the power line communication device having any one of the first to fourth configurations has been paired with a certain master terminal, the current pairing state is maintained regardless of whether or not a beacon is received (fifth configuration). ).

  The power line communication device disclosed in the present specification functions as part or all of a terminal terminal that performs mutual communication with the master terminal via the power line, and is received via the power line. When the reception state of the beacon changes, the connection sequence for establishing pairing with the master terminal is started (sixth configuration).

  Note that the power line communication device having the sixth configuration may be configured to monitor the number of received beacons and determine whether or not the beacon reception state has changed (seventh configuration).

  The power line communication apparatus having the sixth configuration may be configured to monitor the beacon transmission source and determine whether the beacon reception state has changed (eighth configuration).

  In addition, the power line communication device having any one of the sixth to eighth configurations may perform the connection sequence when the connection sequence is being executed even after a predetermined time has elapsed since the last change of the beacon reception state. It is good to make it the structure (9th structure) to stop.

  In addition, the power line communication device disclosed in the present specification functions as a part or all of the terminal terminal that performs mutual communication with the master terminal via the power line, and when the power is turned on. , Start a connection sequence for establishing pairing with the master terminal, and stop the connection sequence when pairing is not established after the first predetermined time has elapsed since the start of the connection sequence. The connection sequence is restarted (tenth configuration) when a second predetermined time has elapsed since the connection sequence was stopped.

  Note that the power line communication device having any one of the first to tenth configurations may have a configuration (eleventh configuration) integrated as a baseband LSI compliant with the power line communication standard.

  The power line communication system disclosed in the present specification includes a master terminal and a terminal terminal that performs mutual communication with the master terminal via a power line, and a part of the terminal terminal or As a whole, the power line communication device having any one of the first to eleventh configurations is used (a twelfth configuration).

  The power line communication device disclosed in this specification functions as part or all of the terminal terminal that performs mutual communication with the master terminal via the power line, and receives a beacon from the master terminal. When no longer being received, the reception search state is maintained for the first predetermined time, and then the intermittent search mode in which the sleep state for the second predetermined time and the reception standby state for the third predetermined time are repeated. (13th configuration).

  In the power line communication device having the thirteenth configuration, at least one of the first predetermined time, the second predetermined time, and the third predetermined time can be arbitrarily adjusted. A configuration that is a variable value (fourteenth configuration) may be used.

  Further, in the power line communication device having the fourteenth configuration, the first predetermined time and the third predetermined time are both set longer than the beacon transmission cycle (fifteenth configuration). Good.

  In the power line communication device having the fourteenth or fifteenth configuration, the first predetermined time may be set longer than the third predetermined time (sixteenth configuration).

  The power line communication device having any one of the thirteenth to sixteenth configurations may sleep for a fourth predetermined time in accordance with the beacon transmission cycle when the beacon from the master terminal is periodically received. It is preferable to adopt a configuration (a seventeenth configuration) in an intermittent reception mode in which the state and the reception standby state for at least the fifth predetermined time are repeated.

  In the power line communication device having the seventeenth configuration, the second predetermined time may be set longer than the fourth predetermined time (eighteenth configuration).

  In the power line communication device having the seventeenth or eighteenth configuration, the first predetermined time and the third predetermined time are both set longer than the fifth predetermined time (19th). (Configuration).

  The power line communication device having any one of the thirteenth to nineteenth configurations includes a first oscillation circuit that generates a main clock and a second oscillation circuit that generates a sub-clock having a frequency lower than that of the main clock. In the sleep state in the intermittent search mode, the first oscillation circuit is stopped and the second predetermined time is counted using the sub clock (twentieth configuration).

  Also. The power line communication device having any one of the thirteenth to twentieth configurations may be configured as a baseband LSI (21st configuration) that is compliant with the power line communication standard.

  A power line communication system disclosed in the present specification includes a master terminal and a terminal terminal that performs mutual communication with the master terminal via a power line. The power line communication device having any one of the twenty-first configurations is used (a twenty-second configuration).

  According to the invention disclosed in the present specification, it is possible to provide a power line communication device that can realize an automatic pairing operation with a master terminal.

  Further, according to the invention disclosed in the present specification, it is possible to provide a power line communication device that can reduce power consumption during a master search operation.

Block diagram showing a configuration example of a power line communication system Block diagram showing a configuration example of a power line communication device Sequence diagram showing an example of manual pairing operation Sequence diagram showing an example of automatic pairing operation Sequence diagram showing an example of pairing cancellation / repairing operation Flow chart showing a first example of automatic pairing operation Flow chart showing an example of a connection sequence Flow chart showing a second example of automatic pairing operation Flow chart showing a third example of automatic pairing operation Flow chart showing a fourth example of automatic pairing operation Timing chart showing first example of master search operation Timing chart showing second example of master search operation

<Power line communication system>
FIG. 1 is a block diagram illustrating a configuration example of a power line communication system. The power line communication system 100 of this configuration example includes a power line 110, PLC adapters 120 and 130, a router 140, a personal computer 150, a home appliance 160, and a lighting device 170.

  The power line 110 is a commercial AC power line (AC100V / AC200V) drawn into a house or facility. The power line 110 is laid from the distribution board in the house to each room.

  The PLC adapter 120 is a master terminal (parent device) that performs mutual communication with various terminal terminals (such as the PLC adapter 130, the home appliance 160, and the lighting device 170) via the power line 110. A router 140 is connected to the PLC adapter 120 serving as a master terminal. However, when the PLC adapter 120 has a router function, the router 140 can be omitted.

  The PLC adapter 130 is one of terminal terminals (slave devices) that perform mutual communication with the PLC adapter 120 via the power line 110. In the example of this figure, only one personal computer 150 is connected to one PLC adapter 130. However, the number of connection ports of the PLC adapter 130 is not limited to this. For example, when a multi-port PLC adapter 130 is used, a plurality of wired network compatible devices (personal computers) are connected to one PLC adapter 130. Network printers, televisions, video recorders, etc.) can also be connected.

  The router 140 is a communication device for relaying data between a LAN [local area network] and a WAN [wide area network]. A PLC adapter 120 is connected to the LAN port of the router 140, and a wide area communication network 180 (such as the Internet) is connected to the WAN port of the router 140.

  The personal computer 150 is one piece of hardware that performs power line communication via the PLC adapter 130. If the personal computer 150 is used, it is possible to control the operation of the home appliance 160 and the lighting device 170 as well as browse websites and send and receive e-mails.

  The home appliance 160 is one of terminal terminals (slave devices) that perform mutual communication with the PLC adapter 120 via the power line 110, and includes a PLC baseband LSI 161, a user interface 162, and a host CPU (central processing unit). 163. As household appliance 160, what is called white goods, such as an air conditioner, a washing machine, a refrigerator, a rice cooker, and a microwave oven, can be mentioned.

  The PLC baseband LSI 161 is a power line communication device that functions as part of the home appliance 160, and is integrated as a semiconductor device that conforms to a predetermined power line communication standard. The home appliance 160 on which the PLC baseband LSI 161 is mounted acquires a power line communication function in addition to the original function of the device.

  The user interface 162 is a front end for accepting a user operation and notifying the user of the operating state of the home appliance 160. The user interface 162 includes input units such as buttons, switches, touch panels, and remote controllers, and output units such as indicator lamps, liquid crystal display panels, speakers, and buzzers.

  The host CPU 163 controls the operation of the home appliance 160 according to a user operation received through the user interface 162 or a remote control command transmitted from the personal computer 150 or the wide area communication network 180 via the power line 110. For example, when the home appliance 160 is an air conditioner, the host CPU 163 controls on / off of operation, switching of an operation mode (cooling / heating), setting of a target temperature, adjustment of air volume and direction, and the like. The

  The lighting device 170 is one of terminal terminals (slave devices) that perform mutual communication with the PLC adapter 120 via the power line 110, and includes a PLC baseband LSI 171, an LED (light emitting diode) driver LSI 172, and an LED light source 173. And including. Examples of the illumination device 170 include an LED ceiling light, an LED downlight, and an LED spotlight.

  The PLC baseband LSI 171 is a power line communication device that functions as a part of the lighting device 170, and is integrated as a semiconductor device that conforms to a predetermined power line communication standard. The lighting device 170 equipped with the PLC baseband LSI 171 acquires a power line communication function in addition to the original lighting function of the device.

  The LED driver LSI 172 performs light emission drive control of the LED 173 by generating a drive current for the LED 173. In particular, the LED driver LSI 172 controls the turning on / off of the LED 173, dimming control (luminance control), or toning control according to a remote control command transmitted from the personal computer 150 or the wide area network 180 via the power line 110. The function to perform.

  The LED light source 173 is supplied with a drive current from the LED driver LSI 172, and for example, daylight color (color temperature 6700K), daylight white (color temperature 5000K), white (color temperature 4200K), warm white (color temperature 3500K), or , Emit light of light bulb color (color temperature 3000K). The LED light source 173 includes a single LED element or a plurality of LED elements connected in series or in parallel as a light emitting element. However, the light emitting element is not limited to the LED element, and an organic EL element or the like may be used.

  By constructing the power line communication system 100 described above, the LAN cable is not routed unnecessarily between a plurality of terminals installed in different living rooms (for example, between the personal computer 150 and the home appliance 160 or the lighting device 170). Bidirectional wired communication (power line communication) can be performed.

<Power line communication device>
FIG. 2 is a block diagram illustrating a configuration example of the power line communication device. The power line communication apparatus 200 of this configuration example corresponds to the PLC baseband LSI 161 or 171 or the PLC adapter 130 of FIG. 1, and includes a microcomputer 201, a ROM [read only memory] 202, and a RAM [random access memory]. 203, interrupt control circuit 204, PLC control circuit 205, transmission DAC [digital-to-analogue converter] circuit 206, reception ADC [analogue-to-digital converter] circuit 207, and general-purpose input / output circuit 208 A PWM [pulse width modulation] output circuit 209, a power-on reset circuit 210, a first oscillation circuit 211, a second oscillation circuit 212, a timer circuit 213, and a bus 214.

  The microcomputer 201 operates in response to the input of the main clock MCLK, and comprehensively controls the operation of the power line communication device 200.

  The ROM 202 stores a program executed by the microcomputer 201 in a nonvolatile manner. As a program storage means, an EEPROM (electrically erasable programmable ROM) capable of rewriting data, a flash memory, or the like may be used.

  The RAM 203 is volatile storage means used as a work area for the microcomputer 201.

  The interrupt control circuit 204 generates an interrupt signal for restarting the first oscillation circuit 211, for example, when returning from sleep in the intermittent search mode (details will be described later).

  The PLC control circuit 205 includes a PLC_PHY layer and a PLC_MAC layer that comply with the power line communication standard, and performs a modulation process of a digital transmission signal, a demodulation process of a digital reception signal, and the like.

  The transmission DAC circuit 206 converts the digital transmission signal input from the PLC control circuit 205 into an analog transmission signal and outputs the analog transmission signal to the power line.

  The reception ADC circuit 207 converts an analog reception signal input from the power line into a digital reception signal and outputs the digital reception signal to the PLC control circuit 205.

  The general-purpose input / output circuit 208 is an external interface for performing bidirectional communication with the outside of the apparatus. For example, when the power line communication device 200 is used as the PLC baseband LSI 171 in FIG. 1, the general input / output circuit 208 can output an ON / OFF signal of the LED light source 173 to the LED driver LSI 172.

  The PWM output circuit 209 is an external interface for outputting a PWM signal to the outside of the apparatus. For example, when the power line communication device 200 is used as the PLC baseband LSI 171 in FIG. 1, a PWM dimming signal (luminance control signal) of the LED light source 173 can be output from the PWM output circuit 209 to the LED driver LSI 172. .

  The power-on reset circuit 210 generates a reset signal for initializing each part of the apparatus when the power to the power line communication apparatus 200 is turned on.

  The first oscillation circuit 211 generates a main clock MCLK having a first frequency f1 (for example, f1 = 1 to 20 MHz). The first oscillation circuit 211 temporarily stops the oscillation operation every time the power line communication device 200 shifts to the intermittent search mode (details will be described later) and switches from the reception standby state to the sleep state.

  The second oscillation circuit 212 generates a sub clock SCLK having a second frequency f2 (f2 <f1, for example, f2 = 32 kHz). Note that the second oscillation circuit 211 always continues its oscillation operation regardless of the operation state of the power line communication device 200.

  The timer circuit 213 counts the number of pulses of the subclock SCLK and interrupts the sleep return timing each time the power line communication device 200 shifts to the intermittent search mode (details will be described later) and switches from the reception standby state to the sleep state. Notify the control circuit 204.

  The bus 214 is a common signal path for performing bidirectional communication between the circuit elements of the power line communication apparatus 200.

<Manual pairing operation>
FIG. 3 is a sequence diagram illustrating an example of a manual pairing operation between the master terminal 300 and the terminal terminal 400. The master terminal 300 corresponds to the PLC adapter 120 of FIG. On the other hand, the terminal 400 corresponds to the home appliance 160, the PLC adapter 130, or the like (device provided with a user interface) in FIG.

The terminal terminal 400 starts a connection sequence for establishing pairing with the master terminal 300 in response to pressing of its own pairing execution button. More specifically, the terminal device 400 as a trigger depression pairing start button to start the transmission of the request signal (register _{_} REQ). Transmitting operation of the request signal (register _{_} REQ) is continued over a maximum of 5 minutes from the master terminal 300 until it receives a reply response signal (register _{_} RES).

The master terminal 300 in response to the fact that their pairing execution button during receiving the request signal (register _{_} REQ) from a terminal device 400 is pressed, a response signal to the terminal device 400 (register _{_} RES) Send.

Terminal device 400 receives that response signal from the master terminal 300 (register _{_} RES) has been returned, to generate a PSK [pre-shared key] a predetermined algorithm, then, acknowledge signal (register to the master terminal 300 to send _{_} RES _{_} ACK) a.

The master terminal 300 receives the acknowledge signal from the terminal device 400 (register _{_} RES _{_} ACK) is sent back, to generate a PSK a predetermined algorithm.

  Through a series of connection sequences described above, a pair of PSKs are generated at both the master terminal 300 and the terminal terminal 400, whereby mutual authentication between the two is completed and pairing between the master terminal 300 and the terminal terminal 400 is established. The

  Note that once the pairing is established between the master terminal 300 and the terminal terminal 400, the pairing between the two will not be canceled unless the pairing is intentionally canceled thereafter. Therefore, for example, even if the main power of the terminal terminal 400 is turned off, the mutual authentication with the master terminal 300 is completed promptly without going through the above connection sequence when the main power of the terminal terminal 400 is turned on next time. To do.

  However, in order to realize the above-described manual pairing operation, it is necessary to provide a user interface such as a pairing execution button on both the master terminal 300 and the terminal terminal 400. In the case where the host CPU is provided in the terminal terminal 400, the pairing operation with the master device 300 can be started without the user interface by controlling the PLC baseband LSI from the host CPU. Is possible.

  However, for example, when it is desired that the terminal terminal 400 be a device that does not have a user interface or a host CPU, such as the lighting device 170 of FIG. 1, the above-described pairing execution button is pressed or a control command from the host CPU is used. Instead, it is necessary to prepare a new pairing start trigger separately.

  Hereinafter, an automatic pairing operation that can be applied to a device that does not include a user interface or a host CPU will be described in detail.

<Automatic pairing operation>
FIG. 4 is a sequence diagram showing an example of automatic pairing operation between the master terminal 300 and the terminal terminal 500. The master terminal 300 corresponds to the PLC adapter 120 of FIG. On the other hand, the terminal terminal 500 corresponds to the lighting device 170 in FIG. The terminal terminal 500 is equipped with the power line communication device 200 (PLC baseband LSI) of FIG.

  Master terminal 300 periodically transmits a beacon (BCN) to the power line. This beacon (BCN) can be received by all terminal terminals connected to the power line regardless of whether or not pairing with the master terminal 300 is established.

Therefore, (by extension, the power line communication apparatus 200 that is mounted to) the terminal device 500, upon receiving a beacon (BCN) via a power line, transmission of the foregoing connection sequence (request signal (register _{_} REQ) ). That is, in the automatic pairing operation of this figure, reception of a beacon (BCN) is used as a pairing start trigger. Since the connection sequence itself is the same as in FIG. 3 except that the pairing start trigger is different, a duplicate description is omitted.

  By adopting such an automatic pairing operation, even a device that does not have a user interface or host CPU can be paired with the master device 300 simply by connecting it to the power line and turning on the power. The operation can be automatically started.

<Pairing cancellation / re-pairing>
FIG. 5 is a sequence diagram illustrating an example of the pairing cancellation operation between the master terminal 300 a and the terminal terminal 500 and the re-pairing operation between the master terminal 300 b and the terminal terminal 500. In this figure, the master terminal 300a is a master terminal that has already been paired with the terminal terminal 500. On the other hand, the master terminal 300b is another master terminal trying to establish a new pairing with the terminal terminal 500.

  As described above, the terminal terminal 500 is not provided with any user interface (such as a pairing cancel button). Therefore, in order to cancel the pairing between the master terminal 300a and the terminal terminal 500, it is necessary to prepare a new pairing cancellation trigger instead of pressing the pairing cancellation button.

  Therefore, the terminal terminal 500 (and thus the power line communication device 200 mounted on the terminal terminal 500) cancels the current pairing state established with the master terminal 300a when receiving a reset command via the power line. . The above reset command is a command conforming to, for example, HTTP [hypertext transfer protocol], and is transmitted from the personal computer 600 existing in the LAN to the terminal terminal 500. However, the reset command may be received via a serial interface or the like. Moreover, if a pairing cancellation | release button can be provided, what is necessary is just to let that pressing down be a pairing cancellation | release trigger.

  When the terminal terminal 500 returns to the initial state (the state in which none of the master terminals 300a and 300b is paired) by such a pairing cancellation operation, in order to perform the automatic pairing operation described in FIG. The terminal 500 enters a beacon (BCN) reception standby state.

Then, the terminal device 500 starts the aforementioned connection sequence (transmission of the request signal (register _{_} REQ)) when it receives a beacon (BCN) via the power line. Note that the beacon (BCN) received by the terminal 500 is merely a trigger for starting the automatic pairing operation, and the transmission source is not questioned. That is, the beacon (BCN) may be transmitted from the master terminal 300b that is newly trying to establish pairing, or transmitted from the master terminal 300b whose pairing has been canceled in response to the reset command. It may be a thing.

Thereafter, the pairing execution button of the master terminal 300b during the period in which the request signal from the terminal device 500 (register _{_} REQ) is transmitted is depressed, is underway series connection sequence described above, the master terminal The re-pairing between 300b and the terminal terminal 500 is completed.

<Flowchart>
FIG. 6 is a flowchart showing a first example of the automatic pairing operation. The operating subject of this flow is basically a power line communication device (PLC broadband LSI) provided in a terminal terminal. The same applies to FIGS. 7 to 10 described later.

  When this flow is started, the pairing state of the terminal terminal is checked in step S10, and then the flow proceeds to step S11. If it is determined in step S11 that the terminal terminal has been paired, the flow returns to step S10.

  As described above, once the terminal terminal is paired, step S10 and step S11 are repeated until the terminal terminal pairing is canceled. That is, when the terminal terminal has already been paired with the master terminal, the terminal terminal maintains the current pairing state regardless of whether or not a beacon is received (without checking the beacon).

  On the other hand, if it is determined in step S11 that the terminal terminal has not been paired, the flow proceeds to step S12. In step S12, whether or not a beacon is received is checked, and then the flow proceeds to step S13.

  If it is determined in step S13 that a beacon has not been received, the flow returns to step S10. On the other hand, if it is determined in step S13 that a beacon has been received, the flow proceeds to step S14.

In step S14, the series of connection sequences described in FIG. 4 is executed. Mutual authentication completion of the master terminal and the terminal device, or by transmitting the time-up of the request signal (register _{_} REQ), this connection sequence is ended, the flow is returned to step S10. Thereafter, the above series of flows is repeated.

  Note that steps S10 and S11 may be moved between step S13 and step S14, and the flow may be modified to prohibit the transition to step S14 when the determination in step S11 is YES. When such a modification is performed, the terminal terminal sequentially checks whether or not a beacon has been received, but when it is already paired with a certain master terminal, it maintains the current pairing state regardless of the check result. become.

  FIG. 7 is a flowchart showing an example of a connection sequence in step S14. In the sequence diagram of FIG. 4, steps executed by the terminal terminal are rewritten as a flowchart.

When the connection sequence of this figure is started, in step S14-1, after the request signal (register _{_} REQ) is transmitted, the flow proceeds to step S 14 - 2. In step S 14 - 2, it is determined whether or not it has received a response signal (register _{_} RES) is performed. Here, if a yes determination is made, the flow proceeds to step S14-3, and if a no determination is made, the flow proceeds to step S14-5.

If yes determination is made at step S 14 - 2, the generation of PSK at Step S14-3 is executed, after the transmission of the acknowledge signal (register _{_} RES _{_} ACK) it is performed in the following step S14-4, a series of The connection sequence ends.

On the other hand, when a negative determination is made in step S14-2, in step S14-4, it is determined whether or not a predetermined time Tx (for example, 5 minutes) has elapsed since the connection sequence was started. Here, if YES determination has been made is the transmission timeout of the request signal (register _{_} REQ), a series of connection sequence is ended. On the other hand, if a negative determination is made, the flow returns to step S14-1.

  FIG. 8 is a flowchart showing a second example of the automatic pairing operation. This flowchart is based on the first example (FIG. 6) described above, and is characterized in that steps S15 and S16 are added. Therefore, the same steps as those in the first example described above are denoted by the same reference numerals as those in FIG. 6, and redundant description is omitted. In the following, the characteristic parts of the second example will be mainly described.

  If it is determined in step S11 that the terminal has been paired, the flow is not immediately returned to step S10, but is advanced to step S15. In step S15, the transmission source of the received beacon is checked, and then the flow proceeds to step S16. The transmission source is checked by confirming the ID information of the master terminal included in the beacon.

  In step S <b> 16, it is determined whether or not the beacon transmission source is a different master terminal from the currently paired master terminal. If the determination is yes, the flow proceeds to step S14, and the above-described connection sequence is started. On the other hand, if a negative determination is made, the flow returns to step S10.

  That is, even if a terminal terminal has already been paired with a certain master terminal (referred to as an old master terminal), when it receives a beacon from a different master terminal (referred to as a new master terminal), it is paired with the new master terminal. In view of the high possibility that the user is expecting, the above-described connection sequence is started.

According to such an automatic pairing operation, within the time the terminal device is transmitting the request signal (register _{_} REQ), by pressing the pairing execution button of the new master terminal, the old master terminal and the terminal device Pairing with the new master terminal and the terminal terminal can be re-paired. On the other hand, if the pairing execution button of the new master terminal is not pressed, the pairing between the old master terminal and the terminal terminal is maintained. Therefore, when changing the pairing destination of the terminal terminal, the reset operation (pairing canceling operation) described in FIG. 5 is unnecessary.

  When this flow is adopted, as long as a plurality of master terminals are connected to the power line, the above-described connection sequence is periodically (or continuously) performed. However, as explained above, unless the pairing execution button is pressed on the new master terminal during the connection sequence, pairing between the old master terminal and the terminal terminal will not be canceled, so no particular trouble will occur. it is conceivable that.

  If the connection sequence is started but the pairing with the new master terminal is not established as a result of proceeding from step S16 to step S14, the history is stored, and thereafter, this corresponds to the history. When the master terminal is a beacon transmission source, a no determination may be made in step S16. With such a configuration, the connection sequence is not unnecessarily started.

  FIG. 9 is a flowchart showing a third example of the automatic pairing operation. When this flow is started, in step S20, the beacon reception state (for example, the number of received beacons with different transmission sources) is checked, and then the flow proceeds to step S21. In step S21, it is determined whether the beacon reception state has changed. Here, when a yes determination is made, the flow proceeds to step S22, and when a no determination is made, the flow proceeds to step S23.

If in step S21 is YES determination is made, after the connection sequence (transmission of the request signal (register _{_} REQ)) is started in step S22, the flow is returned to step S20. That is, the terminal terminal starts a connection sequence for establishing pairing with the master terminal when the reception state of the beacon received via the power line changes.

  On the other hand, when a negative determination is made in step S21, in step S23, it is determined whether or not a predetermined time Tx (for example, 5 minutes) has elapsed since the beacon reception state last changed. Here, if a yes determination is made, the flow proceeds to step S24, and if a no determination is made, the flow returns to step S20.

  When a yes determination is made in step S23, in step S24, it is determined whether or not the connection sequence started in step S22 is being executed (whether or not mutual authentication with the master terminal is incomplete). Done. Here, when a yes determination is made, the flow proceeds to step S25, and when a no determination is made, the flow returns to step S20.

  If a YES determination is made in step S24, a connection sequence stop process is performed in step S25, and then the flow returns to step S20. In this way, the terminal terminal stops the connection sequence when the connection sequence is being executed even after the elapse of the predetermined time Tx since the last change of the beacon reception state.

  Hereinafter, the operation of this flowchart will be described with specific examples. For example, when receiving a beacon from the master terminal for the first time during the first pairing of the terminal terminal, the number of received beacons changes from 0 (initial value) to 1. Accordingly, since a yes determination is made in step S21, a connection sequence is started in step S22. As a result, the pairing between the master terminal and the terminal terminal is established by pressing the pairing execution button of the master terminal.

  Thereafter, unless a new master terminal is connected to the power line, the number of received beacons remains one. Therefore, until the predetermined time Tx elapses after the number of received beacons changes to 1, the flow loops through the no determination in step S20, step S21, and the no determination in step S23. In addition, after a predetermined time Tx has elapsed since the number of received beacons has changed to one, the flow loops through Step S20, No determination in Step S21, Yes determination in Step S23, and No determination in Step S24. To do.

  On the other hand, when a new master terminal is connected to the power line after pairing with the old master terminal is established, the number of received beacons changes from one to two. Accordingly, a yes determination is made in step S21, and a connection sequence is started in step S22.

  At this time, until the predetermined time Tx elapses after the number of received beacons changes to 2, the flow loops through the no determination in step S20, step S21, and the no determination in step S23. If the connection sequence is completed when a predetermined time Tx has elapsed since the number of received beacons has changed to two (when pairing with the new master terminal has been established), step S20 is performed. The flow loops through a no determination in step S21, a yes determination in step S23, and a no determination in step S24.

  However, if the connection sequence has not ended when the predetermined time Tx has elapsed since the number of received beacons has changed to two (if pairing with the new master terminal has not been established), step S24 is performed. In step S25, the connection sequence is stopped.

  That is, when the connection sequence is started in response to the change in the beacon reception state, but the predetermined time Tx has passed without the pairing execution button of the new master terminal being pressed, the connection sequence is stopped.

  Thus, in consideration of the fact that the terminal terminal is likely to expect pairing with the new master terminal because the beacon reception state changes, the network environment changes. The connection sequence described above is started not only during ringing.

  In this flow, the number of beacons received is monitored and the configuration for determining whether the beacon reception state has changed is taken as an example, but the monitoring target is not limited to this, for example, Even if the number of received beacons does not change, it is also possible to monitor the beacon source data and determine whether or not the beacon reception state has changed.

FIG. 10 is a flowchart showing a fourth example of the automatic pairing operation. Start When this flow is started by the power supply to the terminal device, at step S30, after a power-on reset, the connection sequence for establishing a pairing with the master terminal (transmission of the request signal (register _{_} REQ)) To do.

  Thereafter, in step S31, the pairing state of the terminal terminal is checked, and the flow proceeds to step S32. If it is determined in step S32 that the terminal terminal has been paired, the flow ends. As described above, once the terminal terminal is paired, the current pairing state is maintained without starting the connection sequence until the terminal terminal pairing is canceled.

  If it is determined in step S32 that the terminal terminal has not been paired, the flow proceeds to step S33 to determine whether or not a predetermined time Tx (for example, 5 minutes) has elapsed since the start of the connection sequence. Done. Here, if a yes determination is made, the flow proceeds to step S34, and if a no determination is made, the flow returns to step S31.

  If a YES determination is made in step S33, connection sequence stop processing is performed in step S34. As described above, when the pairing is not established even after the predetermined time Tx has elapsed since the start of the connection sequence, the terminal terminal temporarily stops the connection sequence being executed.

  Thereafter, in step S35, it is determined whether or not a predetermined time Ty (for example, 1 hour) has elapsed since the connection sequence was stopped. If the determination is yes, the flow is returned to step S30, and the above-described connection sequence is resumed. On the other hand, if a negative determination is made, the flow returns to step S35, and the counting operation for a predetermined time Ty is continued.

  According to such an automatic pairing operation, as long as the terminal terminal is in an unpaired state, it is possible to periodically attempt pairing with the master terminal without requiring beacon monitoring.

<Master search operation>
FIG. 11 is a timing chart showing a first example of the master search operation, in which the reception state of the beacon BCN and the operation state of the terminal terminal are depicted in order from the top.

  The terminal terminal that has been paired with the master terminal receives a beacon BCN (for example, several hundred μs wide) periodically transmitted from the master terminal, and performs timing control of power line communication. In particular, when the beacon BCN is periodically received from the master terminal, the terminal terminal matches the transmission period Ta of the beacon BCN (for example, 50 ms, 100 ms, 120 ms) at a predetermined time Tb (= Ta−Tc). The intermittent reception mode is such that the sleep state (SLP) over and the reception standby state (STBY) over at least the predetermined time Tc (for example, 5 ms at the shortest) are repeated.

  For example, at time t11 to t12 or t13 to t14 in the figure, the terminal terminal returns from the sleep state (SLP) to the reception standby state (STBY) immediately before the master terminal transmits the beacon BCN, When it is recognized that a data packet does not continue to the received beacon BCN, the state immediately shifts from the reception standby state (STBY) to the sleep state (SLP).

  On the other hand, at time t12 to t13 in the figure, the terminal terminal returns to the reception standby state (STBY) immediately before the master terminal transmits the beacon BCN, and confirms that the data packet continues to the received beacon BCN. As a result of the recognition, the data communication state (COMM) is continued without shifting to the sleep state (SLP). Further, at time t12 to t13, the terminal terminal promptly shifts to the sleep state (SLP) when it recognizes that the data packet does not continue to the beacon BCN received thereafter.

  In the sleep state (SLP), the operation of almost all circuit elements included in the terminal terminal (except for some circuit elements necessary for the sleep return operation) is stopped. Therefore, by installing the intermittent reception mode, it is possible to significantly reduce the power consumption of the terminal terminal.

  However, if the master terminal stops transmitting the beacon BCN because the master terminal is pulled out of the power line or the power supply to the master terminal is stopped, the terminal terminal returns to the reception standby state (STBY). Even so, the state where the beacon BCN cannot be received continues.

  As a result, as shown after time t14, the terminal terminal continues to search for the master terminal (maintained in the reception standby state (STBY) until the beacon BCN is received). The merit (power saving) is impaired.

  FIG. 12 is a timing chart showing a second example of the master search operation. Similarly to FIG. 11, the reception state of the beacon BCN and the operation state of the terminal terminal are depicted in order from the top. Note that the intermittent reception mode at times t11 to t14 is as described above, and thus a redundant description is omitted. In the following, an improvement point of the master search operation after time t14 will be mainly described.

  As shown after time t14, when the terminal terminal (and thus the power line communication device provided in the terminal terminal) no longer receives the beacon (BCN) from the master terminal, the terminal terminal continues for a predetermined time T1 (for example, 3 seconds). An intermittent search mode that repeats a sleep state (SLP) for a predetermined time T2 (for example, 1 second) and a reception standby state (STBY) for a predetermined time T3 (for example, 300 ms) after maintaining the reception standby state (STBY) Become.

  That is, the fact that the terminal terminal cannot receive the beacon BCN for a predetermined time T1 that is sufficiently longer than the beacon transmission cycle Ta means that the master terminal is not transmitting the beacon BCN (or the master terminal itself is Then, the process shifts to an intermittent search mode for minimizing power consumption.

  As described above, by performing intermittent operation not only in a situation in which beacon BCN can be received periodically (time t11 to t14) but also in a situation in which beacon BCN cannot be received (after time t14), the terminal at the time of the master search operation It becomes possible to greatly reduce the power consumption of the terminal.

  Note that at least one of the predetermined times T1 to T3 may be a variable value that can be arbitrarily adjusted from a personal computer or the like via a power line. For example, the predetermined time T1 until the transition to the intermittent search mode may be arbitrarily adjusted between 1 second and 1 minute. With such a configuration, it is possible to arbitrarily adjust the ease of transition to the intermittent search mode and the behavior in the intermittent search mode.

  Also, it is desirable that both the predetermined times T1 and T3 for entering the reception standby state (STBY) are set longer than the transmission period Ta of the beacon BCN. For example, if Ta = 100 ms, it is desirable to set T1 = 1 s and T3 = 300 ms. If such setting is performed, as long as the beacon BCN is periodically transmitted from the master terminal, the beacon BCN can be received without omission in the reception standby state (STBY) of the terminal terminal.

  Further, as exemplified above, it is desirable to set the predetermined time T1 longer than the predetermined time T3. By making such a setting, it is possible to prioritize the power saving of the terminal terminal by shortening the reception standby state (STBY) after shifting to the intermittent search mode.

  In addition, the sleep time (predetermined time T2) in the intermittent search mode is desirably set longer than the sleep time (predetermined time Tb) in the intermittent reception mode. By performing such setting, it is possible to prioritize the power saving of the terminal terminal by lengthening the sleep state (SLP) after shifting to the intermittent search mode.

  In addition, it is desirable to set the reception standby time (predetermined times T1 and T3) in the intermittent search mode longer than the shortest reception standby time (predetermined time Tc) in the intermittent reception mode. By performing such setting, it is possible to receive the beacon BCN without omission while intermittently waiting for the reception of the beacon BCN to save power.

  When the power line communication apparatus 200 of FIG. 2 is mounted on a terminal terminal, the power line communication apparatus 200 stops the first oscillation circuit 211 and the sub clock SCLK in the sleep state (SLP) in the intermittent search mode. The predetermined time T2 may be counted using

  This will be specifically described with reference to the example of FIG. The power line communication device 200 is generated by the first oscillation circuit 211 until the terminal terminal shifts to the intermittent search mode, that is, until the predetermined time T1 elapses while maintaining the reception standby state (STBY). It operates using the main clock MCLK.

  When the predetermined time T1 has elapsed, the power line communication device 200 stops the first oscillation circuit 211. As a result, the power line communication apparatus 200 enters a sleep state (SLP) in which circuit elements such as the microcomputer 201 using the main clock MCLK have stopped operating.

  However, the second oscillation circuit 212 continues the generation operation of the sub clock SCLK even in the sleep state (SLP). Further, the timer circuit 203 notifies the interrupt control circuit 204 of the sleep return timing by counting the number of pulses of the sub clock SCLK and elapses a predetermined time T2 (for example, 1 second).

  In response to the notification from the timer circuit 203, the interrupt control circuit 204 restarts the first oscillation circuit 211. As a result, the generation operation of the main clock MCLK is resumed, so that the power line communication device 200 returns to the reception standby state (STBY). Thereafter, when the beacon BCN is not received within the predetermined time T3, the power line communication device 200 stops the first oscillation circuit 211 again and enters the sleep state (SLP) described above. Thereafter, the same operation is repeated.

  As described above, the sub clock SCLK has a lower frequency than the main clock MCLK. Therefore, the current consumption of the second oscillation circuit 212 can be suppressed smaller than that of the first oscillation circuit 211. For this reason, if the sleep recovery timing is determined using the subclock SCLK, the current consumption in the sleep state (SLP) in the intermittent search mode can be significantly reduced compared to that in the reception standby state (STBY). It becomes.

  Of course, it is possible to determine the sleep return timing using the main clock MCLK without preparing the second oscillation circuit 212. However, when such a configuration is adopted, the current consumption of the first oscillation circuit 211 cannot be reduced because the first oscillation circuit 211 must be continuously driven even in the sleep state (SLP).

<Other variations>
The various technical features disclosed in the present specification can be variously modified within the scope of the technical creation in addition to the above-described embodiment. That is, the above-described embodiment is to be considered in all respects as illustrative and not restrictive, and the technical scope of the present invention is indicated not by the description of the above-described embodiment but by the scope of the claims. It should be understood that all modifications that fall within the meaning and range equivalent to the terms of the claims are included.

  Various inventions disclosed in the present specification can be applied to, for example, a PLC baseband LSI and a PLC adapter.

100 Power Line Communication System 110 Power Line 120 PLC Adapter (Master Terminal)
130 PLC adapter (terminal terminal)
140 router 150 personal computer 160 home appliance (terminal terminal)
161 PLC baseband LSI
162 User interface 163 Host CPU
170 Lighting equipment (terminal terminal)
171 PLC baseband LSI
172 LED driver LSI
173 LED
180 Wide-area communication network 200 Power line communication device 201 Microcomputer 202 ROM
203 RAM
204 Interrupt control circuit 205 PLC control circuit 206 Transmission DAC circuit 207 Reception ADC circuit 208 General-purpose input / output circuit 209 PWM output circuit 210 Power-on reset circuit 211 First oscillation circuit 212 Second oscillation circuit 213 Timer circuit 214 Bus 300, 300a, 300b Master terminal 400 Terminal terminal (home appliances, etc.)
500 Terminal terminal (lighting equipment, etc.)
600 Personal computer

Claims (10)

  A power line communication device that functions as part or all of a terminal terminal that performs mutual communication with a master terminal via a power line, and receives a first predetermined time when a beacon from the master terminal is not received. A power line communication apparatus, which is in an intermittent search mode that repeats a sleep state for a second predetermined time and a reception standby state for a third predetermined time after maintaining the standby state.   The at least one of the first predetermined time, the second predetermined time, and the third predetermined time is a variable value that can be arbitrarily adjusted. The power line communication device described.   The power line communication apparatus according to claim 2, wherein both the first predetermined time and the third predetermined time are set longer than a transmission period of the beacon.   4. The power line communication apparatus according to claim 2, wherein the first predetermined time is set longer than the third predetermined time. 5.   When a beacon from the master terminal is periodically received, intermittent reception that repeats a sleep state for a fourth predetermined time and a reception standby state for at least a fifth predetermined time in accordance with the transmission period of the beacon It becomes a mode, The power line communication apparatus as described in any one of Claims 1-4 characterized by the above-mentioned.   The power line communication apparatus according to claim 5, wherein the second predetermined time is set longer than the fourth predetermined time.   The power line communication apparatus according to claim 5 or 6, wherein both the first predetermined time and the third predetermined time are set longer than the fifth predetermined time. A first oscillation circuit for generating a main clock;
A second oscillation circuit for generating a sub-clock having a lower frequency than the main clock;
Have
8. In the sleep state in the intermittent search mode, the first oscillation circuit is stopped and the second predetermined time is counted using the sub clock. The power line communication device according to the item.   The power line communication apparatus according to any one of claims 1 to 8, wherein the power line communication apparatus is integrated as a baseband LSI that conforms to a power line communication standard. A master terminal,
A terminal terminal that communicates with the master terminal via a power line;
A power line communication system comprising:
A power line communication system using the power line communication device according to any one of claims 1 to 9 as the terminal terminal.

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