JP2013201543A - Communication system, subscriber-side device, and external power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication system capable of reducing power consumption when including a communication device constituted by a plurality of devices.SOLUTION: A communication system comprises: a subscriber-side device 4 that relays communication between a host network 1 and a terminal; and a USB device 6 that is connected with the subscriber-side device 4. The subscriber-side device 4 includes: an ONU unit 100 that receives power supply from either a commercial power supply 5 or the USB device 6 and supplies power to an HGW unit 200 in the subscriber-side device 4; and the HGW unit 200 that receives power supply from the ONU unit 100. The USB device 6 includes a battery that can supply power to the subscriber-side device 4. The ONU unit 100 sets its own operation mode to a power-saving mode when receiving power supply from the USB device 6. The HGW unit 200 sets its own operation mode to a power-saving mode when the ONU unit 100 receives power supply from the USB device 6.

Description

  The present invention relates to a communication system.

  Conventionally, in communication systems, devices such as HGW (Home Gate Way) and ONU (Optical Network Unit) are always energized, but it is not always necessary to operate all functions to the maximum, When the user goes to bed or goes out, the operation with the minimum necessary functions and performance is sufficient. In addition, it has been studied to save power by changing the power saving mode in which the HGW or ONU is in a sleep mode when the HGW or ONU is not used for communication, or by changing the transfer method when the communication traffic is low. Such a technique is disclosed in Patent Document 1 below.

  With the widespread use of optical lines and IP telephones, communication systems that use telephones via HGWs and ONUs, such as those described above, are increasing. Here, power is supplied to HGW and ONU in order to use the telephone because there is a demand for telephone and network communications (Web, e-mail, etc.) even in a situation where commercial power is not supplied to facilities such as homes due to a power failure. It is necessary to operate.

JP 2010-035209 A

  However, according to the above-described conventional technique, in the communication device in which the ONU-HGW operates integrally when receiving power supply from the external battery, the device on the side that is not directly connected to the external battery is connected from the commercial power source. It is not possible to determine whether the power is supplied from an external battery or from an external battery. For this reason, the communication device in which the ONU-HGW operates integrally has a problem in that it cannot be switched to the power saving mode as a whole when the external battery is driven, and the power consumption cannot be reduced.

  The present invention has been made in view of the above, and an object of the present invention is to obtain a communication system capable of reducing power consumption when including a communication device including a plurality of devices.

  In order to solve the above-described problems and achieve the object, the present invention includes a subscriber-side device that relays communication between a host network and a terminal, an external power supply device that is connected to the subscriber-side device, The subscriber-side device receives power from either a commercial power supply or the external power supply device, and supplies power to the other communication devices in the subscriber-side device. A supply-side communication device that receives power from the supply-side communication device, and the external power supply device includes a battery that can supply power to the subscriber-side device. When the side communication device is supplied with power from the external power supply device, its own operation mode is set to a power saving mode capable of operating with lower power consumption than the normal mode, and the power receiving side communication device If the communication device is supplied with power from the external power supply device, the operation mode of its own power-saving mode, characterized in that.

  Advantageous Effects of Invention According to the present invention, there is an effect that power consumption can be reduced when a communication device including a plurality of devices is included.

FIG. 1 is a diagram illustrating a configuration example of a network according to the first embodiment. FIG. 2 is a diagram illustrating a configuration example of a subscriber-side device. FIG. 3 is a diagram illustrating a configuration example of the power feeding determination unit. FIG. 4 is a flowchart illustrating a process for detecting a change in the power supply method in the power supply determination unit. FIG. 5 is a flowchart illustrating a change detection process of the power supply voltage in the power supply determination unit. FIG. 6 is a diagram illustrating a configuration example of a USB device. FIG. 7 is a diagram illustrating a configuration example of a network in the first embodiment. FIG. 8 is a sequence diagram showing transition of operation modes in the subscriber side device and the USB device. FIG. 9 is a diagram illustrating a configuration example of a subscriber-side device. FIG. 10 is a diagram illustrating a configuration example of a network according to the second embodiment. FIG. 11 is a sequence diagram showing transition of operation modes in the subscriber side device and the USB device. FIG. 12 is a sequence diagram showing transition of operation modes in the USB device. FIG. 13 is a diagram showing information in the Ethernet (registered trademark) frame. FIG. 14 is a sequence diagram illustrating transition of operation modes in the HGW unit. FIG. 15 is a sequence diagram illustrating transition of operation modes in the HGW unit.

  Embodiments of a communication system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a configuration example of a network in the present embodiment. In this network, a plurality of subscriber-side devices 4 are connected via a distributor 3 to a station-side device 2 connected to a host network 1 such as a global network. The subscriber-side device 4 is a communication device that is supplied with power from the commercial power supply 5 and can be connected to the USB device 6 or the like by USB (Universal Serial Bus) connection. The subscriber side device 4 has a function of receiving power supply from the USB device 6 which is an external power supply device. The subscriber side device 4 can be connected to various terminals such as an IP (Internet Protocol) telephone 7, an analog telephone 8, a PC (Personal Computer) 9, a home appliance 10, and an STB (Set Top Box) 11. . The subscriber side device 4 is a communication device that relays between the host network 1 and these terminals.

  FIG. 2 is a diagram illustrating a configuration example of the subscriber side device 4. The subscriber side device 4 is composed of a device obtained by combining a plurality of communication devices. The subscriber side device 4 functions as an optical line termination device and functions as a home gateway and an ONU unit 100 that is a supply side communication device that receives power supply from either the commercial power supply 5 or the USB device 6. HGW unit 200 that is a power-receiving-side communication device that receives power supply from.

  The ONU unit 100 is an interface with a TRX unit 101, a PON (Passive Optical Network) LSI (Large Scale Integration) unit 102, a PHY unit 103, and the HGW unit 200 side, which are general configurations that perform optical signal transmission / reception processing. A LAN (Local Area Network) unit 104, a power unit 105 that receives power from the commercial power source 5, a USB unit 106 connected to the USB device 6, a control unit 107 that controls the operation of the ONU unit 100, and a power unit The power supply determination unit 108 that determines whether the power is supplied from the USB unit 106 or the USB unit 106, and the USB connection determination unit 109 that determines the device type connected to the USB unit 106.

  The HGW unit 200 includes a WAN (Wide Area Network) unit 201 that is an interface with the ONU unit 100 side, a PHY unit 202 that is a general configuration that performs optical signal transmission / reception processing, a MAC chip unit 203, and an IP telephone 7. A LAN unit 204 that is an interface with an analog telephone 8, an analog unit 205 that is an interface with an analog telephone 8, and the like, a power source unit 206 that receives power from the ONU 100 side, and a wireless LAN unit that can communicate with other devices via a wireless LAN 208 and a control unit 209 that controls the operation of the HGW unit 200.

  The ONU unit 100 and the HGW unit 200 are connected by a power supply line and a communication line. The power supply unit 105 receives power supply by being connected to the commercial power supply 5 and supplies power to the ONU unit 100 and the HGW unit 200. The USB unit 106 can receive power supply from the connected USB device 6. When receiving power supply from the USB device 6, the USB unit 106 can supply power to the ONU unit 100 and the HGW unit 200 in the same manner as the power supply unit 105. In the ONU unit 100, the power supply determination unit 108 determines which of the power supply unit 105 or the USB unit 106 is supplying power. In the HGW unit 200, the analog unit 205 can supply power to the analog telephone 8 when connected to the analog telephone 8 or the like.

  In FIG. 2, the HGW unit 200 includes one LAN unit 204 and one analog unit 205, but is an example, and includes a plurality of each and connects to a plurality of terminals (IP phone 7, analog phone 8, etc.). Is possible.

  Next, processing for determining which of the power supply unit 105 or the USB unit 106 is supplying power in the power supply determination unit 108 will be described. FIG. 3 is a diagram illustrating a configuration example of the power supply determination unit 108 of the ONU unit 100. The power supply determination unit 108 can determine the high / low voltage of each of the power supply unit 105 and the USB unit 106, and can determine the switching of power supply between the power supply unit 105 and the USB unit 106.

  FIG. 4 is a flowchart showing processing for detecting a change in the power supply method in the power supply determination unit 108. The power supply determination unit 108 detects a change in the power supply voltage, and determines whether the voltage is the voltage of the USB unit 106 or the voltage of the power supply unit 105 at the time of the change. First, the power feeding determination unit 108 detects a change in power supply voltage supplied to the ONU unit 100 and the HGW unit 200 (step S101).

  FIG. 5 is a flowchart showing a power supply voltage change detection process in the power supply determination unit 108. The power supply determination unit 108 stores the voltage detected last time (step S201), and further stores the current voltage (step S202). And the electric power feeding determination part 108 sets a flag, when a change is detected in the last time and the present voltage (step S203: Yes) (step S204). On the other hand, if no change is detected in the previous and current voltages (step S203: No), the detection process is terminated.

  Returning to FIG. 4, when the flag is not set (step S102: No), the power feeding determination unit 108 returns to step S101 and detects a change in the power supply voltage (step S101). When the flag is set (step S102: Yes), the power supply determination unit 108 supplies power to the commercial power supply mode from the power supply unit 105 if the current voltage is from the power supply unit 105 (step S103: Yes). (Step S104). If the current voltage is not from the power supply unit 105 (step S103: No) and the current voltage is from the USB unit 106 (step S105: Yes), the power supply determination unit 108 supplies power from the USB unit 106. USB mode is set (step S106). Thereby, the power feeding determination unit 108 can preferentially use the power supply unit 105 side. In the ONU unit 100, it is possible to provide a battery. In this case, the power supply determination unit 108 determines that the current voltage is not from the USB unit 106 (step S105: No), and cannot detect the current voltage (step S107). Thereafter, the power supply determination unit 108 returns to step S101 to detect a change in the power supply voltage supplied to the ONU unit 100 and the HGW unit 200.

  Here, the configuration of the USB device 6 that is connected to the subscriber apparatus 4 and can supply power to the subscriber apparatus 4 will be described. FIG. 6 is a diagram illustrating a configuration example of the USB device 6. The USB device 6 supplies power to the USB I / F unit 501, which is an interface for connecting to the subscriber side device 4 via USB, and the own device, and can also supply power to the subscriber side device 4. A battery 502, a USB connection determination unit 503 for determining a type connected to the USB destination, a USB supply determination unit 504 for determining whether or not USB connection is being performed to the connection destination device, and a USB A USB connection database (DB) 505 for storing information on the type of the device connected by the power supply, a power supply unit 506 that receives power supply from the commercial power supply 5 when the commercial power supply 5 is available, and its operating state, etc. Wireless LAN unit 507 and LAN unit 508 for notifying from other than the USB I / F unit 501, and a control unit 509 for controlling the operation of the USB device 6. Since the USB device 6 needs to supply power to the subscriber side device 4 at the time of a power failure or the like, it is essential to include the battery 502.

  Next, a description will be given of a process in which each device reduces power consumption at the time of a power failure in which the commercial power supply 5 cannot be used in the subscriber device 4 and the USB device 6. FIG. 7 is a diagram illustrating a configuration example of a network in the present embodiment. The state where the commercial power source 5 and the USB device 6 are connected to the ONU unit 100 is shown. FIG. 8 is a sequence diagram showing transition of operation modes in the subscriber side device 4 and the USB device 6.

  First, the USB device 6 that can be on the power supply side and the subscriber apparatus 4 are connected by USB (step S301). In the USB device 6, the USB connection determination unit 503 performs mapping between the connected USB port and the connection partner (subscriber side device 4), and determines the device type (step S302). The USB connection determination unit 503 stores the mapped information in the USB connection DB 505 and determines whether or not the other party should be supplied with power via USB.

  When the power supply from the commercial power supply 5 is lost (step S303), the subscriber side device 4 switches to the power supply via USB (step S304). Then, the USB device 6 starts supplying power to the subscriber side device 4 (step S305).

  In the USB device 6, when the USB supply determination unit 504 determines that power supply via USB has started (step S 306), the USB connection determination unit 503 determines that the power supply target via USB is determined from the mapping information, and performs control. Under the control of the unit 509, the operation mode of the USB device 6 is set to a power saving mode capable of operating with lower power consumption than the normal mode (step S307). As the power saving mode at this time, it suffices to operate only the power supply via the USB, and the other processes may be in a stopped (sleep) state.

  In the subscriber side device 4, the power supply determination unit 108 detects that power supply from the USB has started, and the ONU unit 100 can operate with lower power consumption than in the normal mode under the control of the control unit 107. The mode is changed (step S308). Further, in the subscriber side device 4, the HGW unit 200 detects that the ONU unit 100 is supplied with power from the USB device 6 or has shifted to the power saving mode, and is controlled by the control unit 209. The device itself shifts to the power saving mode (step S309).

  By supplying power from the USB device 6 via USB, the subscriber apparatus 4 can continue operation even if the power supply from the commercial power supply 5 is interrupted. The analog telephone 8 connected to the analog unit 105 can also be used by receiving power supply via the analog unit 205. In addition, when a device driven by a battery such as a notebook PC is connected to the LAN unit 204 side, such a device can also communicate using the subscriber side device 4.

  In the HGW unit 200, as a method for detecting that the ONU unit 100 is supplied with power from the USB device 6 or the transition to the power saving mode, for example, a method in which the HGW unit 200 monitors the operation mode of the ONU unit 100, When the method of notifying the HGW unit 200 that the ONU unit 100 has been powered by USB, or when the USB device 6 and the HGW unit 200 can directly communicate via a LAN, a wireless LAN, or the like, the USB device 6 directly communicates with the HGW unit 200. There is a method for notifying that the power supply method has changed, but the method is not limited thereto.

  In the USB device 6, when any processing occurs during the power saving mode, the control unit 509 returns the necessary function (configuration) from the sleep state to the normal mode (step S310), and after the generated processing ends (step S310). S311) The operation mode is again set to the power saving mode (step S312).

  Then, when the power supply from the commercial power supply 5 is restored in the subscriber side device 4 (step S313), the USB device 6 ends the power supply to the subscriber side device 4 (step S314).

  Thereafter, in the USB device 6, the USB supply determination unit 504 detects the end of power supply by USB, and the operation mode is returned to the normal mode under the control of the control unit 509 (step S315).

  In the subscriber unit 4, in the ONU unit 100, the power supply determination unit 108 confirms the power supply from the power supply unit 105, and shifts the operation mode to the normal mode under the control of the control unit 107. Further, in the subscriber side device 4, the HGW unit 200 detects that the ONU unit 100 is supplied with power from the commercial power source 5 or that the ONU unit 100 has shifted to the normal mode, and the control unit 209 Under the control, the device itself shifts to the normal mode (step S316).

  As described above, the USB device 6 (specifically, a notebook PC or the like) is used as an external battery supply source which is an external power supply device, and the USB device 6 and the subscriber side device 4 are connected, and the battery of the USB device 6 is connected. The subscriber side device 4 (ONU unit 100, HGW unit 200) can be operated using electric power as a power source.

  When using only an external battery with limited capacity, it is necessary to extend the usage time as much as possible rather than the processing capacity. Therefore, the ONU unit 100 and the HGW unit 200 operate in the same manner as when the commercial power source 5 is used. If it is, use time becomes short. In a communication system that is powered from an external battery with limited capacity, it is necessary to extend the usage time as much as possible. As a method for giving the usage time of the communication system, it is necessary to save power in the subscriber side device 4 and the USB device 6 as described above.

  A case where power is saved in the subscriber side device 4 (ONU unit 100, HGW unit 200) on the demand side will be described. The subscriber side device 4 is an ONU-HGW-integrated casing and is operated by combining a plurality of devices. One device (ONU unit 100) is equipped with a power outlet and USB, and the other device. The (HGW unit 200) is configured to be supplied via a power line or the like. The device (ONU unit 100) that is directly powered by the commercial power supply 5 or USB or the like determines the power supply source device connected by USB, and the power supply device is a battery system device with a capacity limit. In this case, the mode is shifted to a power saving mode in which performance is degraded regardless of the presence or absence of communication. The ONU unit 100 that can be directly fed from the commercial power supply 5 and the USB interface transmits a notification message to the HGW unit 200 to which power is indirectly supplied, and shifts the HGW unit 200 to the power saving mode.

  For this reason, first, the ONU unit 100 determines the type of the power supply source device, and switches to the power saving mode when the supply source is a device with a capacity restriction based on the device type. At this time, when power is supplied from the USB device 6, it is possible to send and receive information to and from the power supply source device. At this time, the device itself is a specific connection destination such as the ONU unit 100. To the USB device 6 side. If the HGW unit 200 that is not directly connected cannot detect a change in the situation, the HGW unit 200 receives a message notification from the ONU unit 100 or the like that is directly supplied, and indirectly shifts to the power saving mode.

  As the power saving mode, only the minimum necessary functions are operated. When the use of the telephone is regarded as the most important, only the functions of the analog unit 205 and the WAN unit 201 of the HGW unit 200 are operated, and other functions are set to sleep or stopped. In the ONU unit 100, the link speed of the Ether port is slowed down (for example, from 1 Gbps to 100/10 Mbps, etc.) to save power so that the voice data of the telephone can be communicated. The HGW unit 200 not directly supplied is in a power saving mode in which only a function for specifying is performed by a connected neighboring device, or the ONU unit 100 is supplied with power from the USB device 6 , And the device itself enters the power saving mode.

  Next, a case where the USB device 6 having a battery such as a notebook PC on the supply side is provided with power saving will be described. When the USB device 6 is connected to a specific USB of the subscriber side device 4, power is supplied from the USB device 6 to the subscriber side device 4. When the USB device 6 itself does not require processing, other functions are stopped except for the supply function via USB. As a result, the USB device 6 uses no power other than power supply, so the usable time of the USB device 6 itself is extended.

  When the USB device 6 is USB and the connection partner cannot be specified, the determination may be made based on the power supply amount from the USB device 6 as described later. That is, since the subscriber side device 4 needs an amount of power for operating the ONU unit 100 and the HGW unit 200, the consumed power consumption is lower than that of a low power consumption such as a USB memory. Becomes higher. That is, the battery consumption of the USB device 6 increases. This amount may be determined by the USB device 6, and when the remaining amount of the battery is largely reduced, that is, when the amount of power required by the other party is large, the state other than the supply function may be stopped.

  In addition to the notebook PC, the USB device 6 that is a power supply source includes a battery such as a mobile phone, a portable music device, a USB hard disk, a tablet terminal, a smartphone, and an external battery device, and supplies power via the USB. Any device can be used. If it has processing capability by itself, the processing capability is suppressed, and a sleep mode or the like other than the supply capability is set. When the device itself as the power supply source requires processing (e.g., mail reception or Web browsing), the sleep mode may be temporarily canceled to enter a power consumption mode that allows processing.

  As described above, according to the present embodiment, the subscriber side device 4 composed of a plurality of communication devices (ONU unit 100, HGW unit 200) is connected to a USB device 6 equipped with a battery. In this case, when the power supply from the commercial power supply 5 is lost, the power supply is switched to the power supply from the USB device 6. At this time, in the subscriber side device 4, the ONU unit 100 connected to the commercial power supply 5 and the USB device 6 is in the power saving mode, and further, in the HGW unit 200, the ONU unit 100 is supplied with power from the USB device 6. Alternatively, the power saving mode of the ONU unit 100 is detected and the power saving mode itself is set. As a result, the subscriber-side device 4 can operate while receiving power from the USB device 6 and reducing power consumption when power from the commercial power source 5 is lost.

  In addition, when the USB device 6 constituting the communication system with the subscriber side device 4 starts to supply power to the subscriber side device 4, the USB device 6 itself also enters the power saving mode. When power is not supplied, it is possible to reduce its own power consumption, extend the time during which power can be supplied to the subscriber side device 4, and extend the operation time (use time) of the subscriber side device 4. It becomes.

Embodiment 2. FIG.
In the present embodiment, in the subscriber side device, the HGW unit is connected to the USB device and the commercial power source. A different part from Embodiment 1 is demonstrated.

  The network configuration in the present embodiment is the same as that in the first embodiment (see FIG. 1), but the subscriber side device 4a is used instead of the subscriber side device 4. FIG. 9 is a diagram illustrating a configuration example of the subscriber side device 4a. The subscriber side device 4a is composed of a device in which a plurality of communication devices are combined. The subscriber side device 4a functions as a home gateway, functions as a supply side communication device HGW unit 400 that receives power supply from either the commercial power source 5 or the USB device 6, and functions as an optical line termination device. A power receiving side communication device ONU unit 300 that receives power supply.

  The ONU unit 300 includes a TRX unit 301, a PON LSI unit 302, a PHY unit 303, a LAN unit 304 that is an interface with the HGW unit 400, and an HGW unit 400. A power supply unit 305 that receives power supply and a control unit 307 that controls the operation of the ONU unit 300 are provided.

  The HGW unit 400 is an interface with a WAN unit 401 that is an interface with the ONU unit 300 side, a PHY unit 402 that is a general configuration for performing optical signal transmission / reception processing, a MAC chip unit 403, an IP phone 7, and the like. A LAN unit 404, an analog unit 405 that is an interface with the analog telephone 8 or the like, a power supply unit 406 that receives power supply from the commercial power supply 5, a USB unit 407 that is connected to the USB device 6, and other devices by wireless LAN A wireless LAN unit 408 capable of communication; a control unit 409 that controls the operation of the HGW unit 400; a power supply determination unit 410 that determines whether power is supplied from the power supply unit 406 or the USB unit 407; and a USB unit A USB connection determination unit 411 that determines the type of device connected to 407.

  The ONU unit 300 and the HGW unit 400 are connected by a power supply line and a communication line. The power supply unit 406 receives power supply by being connected to the commercial power supply 5 and supplies power to the HGW unit 400 and the ONU unit 300. The USB unit 407 can receive power supply from the connected USB device 6. When receiving power supply from the USB device 6, the USB unit 407 can supply power to the HGW unit 400 and the ONU unit 300 in the same manner as the power supply unit 406. In the HGW unit 400, the power supply determination unit 410 determines which of the power supply unit 406 and the USB unit 407 is supplying power. In the HGW unit 400, the analog unit 405 can supply power to the analog phone 8 when connected to the analog phone 8 or the like.

  Like the HGW unit 200 of the first embodiment, the HGW unit 400 includes one LAN unit 404 and one analog unit 405. However, the HGW unit 400 is an example, and includes a plurality of terminals (IP phone 7 and analog phone 8). Etc.). In addition, the configuration and operation of power feeding determination section 410 are the same as those of power feeding determination section 108 (see FIGS. 3 to 5) of the first embodiment.

  Next, a description will be given of a process in which each device reduces power consumption at the time of a power failure in which the commercial power supply 5 cannot be used in the subscriber device 4a and the USB device 6. FIG. 10 is a diagram illustrating a configuration example of a network in the present embodiment. The state where the commercial power supply 5 and the USB device 6 are connected to the HGW unit 400 is shown. FIG. 11 is a sequence diagram showing transition of operation modes in the subscriber apparatus 4a and the USB device 6.

  First, the USB device 6 that can be on the power supply side and the subscriber apparatus 4a are connected by USB (step S401). In the USB device 6, the USB connection determination unit 503 performs mapping between the connected USB port and the connection partner (subscriber side device 4a), and determines the device type (step S402). The USB connection determination unit 503 stores the mapped information in the USB connection DB 505 and determines whether or not the other party should be supplied with power via USB.

  When the power supply from the commercial power supply 5 is lost (step S403), the subscriber side device 4a switches to the power supply via USB (step S404). Then, the USB device 6 starts supplying power to the subscriber side device 4a (step S405).

  In the USB device 6, when the USB supply determination unit 504 determines that the USB power supply has started (step S 406), the USB connection determination unit 503 determines that the power supply target via the USB is based on the mapping information, and performs control. The operation mode of the USB device 6 is set to the power saving mode under the control of the unit 509 (step S407). As the power saving mode at this time, it suffices to operate only the power supply via the USB, and the other processes may be in a stopped (sleep) state.

  In the subscriber side device 4a, the power supply determination unit 410 detects that power supply from the USB has started, and the HGW unit 400 shifts to the power saving mode under the control of the control unit 409 (step S408). Further, in the subscriber side device 4a, the HGW unit 400 notifies the ONU unit 300 that power is supplied from the USB device 6 or has shifted to the power saving mode, and the ONU unit 300 Under the control of 307, the device itself shifts to the power saving mode (step S409).

  In the USB device 6, when any processing occurs during the power saving mode, the control unit 509 returns the necessary function (configuration) from the sleep state to the normal mode (step S410), and after the generated processing ends (step S411). Again, the operation mode is set to the power saving mode (step S412).

  When the power supply from the commercial power supply 5 is restored in the subscriber side device 4a (step S413), the USB device 6 ends the power supply to the subscriber side device 4a (step S414).

  Thereafter, in the USB device 6, the USB supply determination unit 504 detects the end of power supply by USB, and the operation mode is returned to the normal mode under the control of the control unit 509 (step S415).

  In the subscriber unit 4 a, in the HGW unit 400, the power supply determination unit 410 confirms the power supply from the power supply unit 406 and shifts the operation mode to the normal mode under the control of the control unit 409. Further, in the subscriber side device 4a, the ONU unit 300 receives notification from the HGW unit 400 that it has shifted to the normal mode, and shifts itself to the normal mode under the control of the control unit 307 (step S416).

  In the subscriber unit 4a, the operation mode is notified from the HGW unit 400 to the ONU unit 300, but the present invention is not limited to this. Although the ONU unit 300 does not include a wireless LAN, the ONU unit 300 may receive a power supply state directly from the USB device 6 when information can be directly exchanged with the USB device 6. Further, the ONU unit 300 may monitor the operation mode of the HGW unit 400.

  As described above, according to the present embodiment, the subscriber-side device 4a composed of a plurality of communication devices (ONU unit 300, HGW unit 400) is connected to the USB device 6 equipped with a battery. In this case, when the power supply from the commercial power supply 5 is lost, the power supply is switched to the power supply from the USB device 6. At this time, in the subscriber side apparatus 4a, the HGW unit 400 connected to the commercial power supply 5 and the USB device 6 is in the power saving mode, and the HGW unit 400 notifies the ONU unit 300 of its own operation mode. The power saving mode was set. Thereby, in the subscriber side apparatus 4a, when the power supply from the commercial power supply 5 is lost, it is possible to receive power supply from the USB device 6 and operate with reduced power consumption.

  Further, when the USB device 6 constituting the communication system with the subscriber side device 4a starts to supply power to the subscriber side device 4a, the USB device 6 itself also enters the power saving mode. When power is not supplied, it is possible to reduce its own power consumption, extend the time during which power can be supplied to the subscriber side device 4a, and extend the operation time (use time) of the subscriber side device 4a. It becomes.

Embodiment 3 FIG.
As described in the first and second embodiments, in the subscriber apparatuses 4 and 4a and the USB device 6, various combinations of power supply are assumed. In this embodiment, a combination of power supply for each configuration and an operation mode at that time will be described.

  First, the case of Embodiment 1 will be described. In the configuration of the first embodiment (see FIG. 7), devices that can be used by directly connecting to the commercial power source 5 are the ONU unit 100 and the USB device 6 of the subscriber side device 4. A device that can operate as a battery is the USB device 6. The ONU unit 100 and the USB device 6 of the subscriber side device 4 can switch the operation mode to the power saving mode based on their own judgment. In the configuration shown in FIG. 7, the following four patterns can be considered as combinations of power supply to each configuration.

(1) When USB device 6 is supplied from commercial power source 5, ONU unit 100 is supplied from commercial power source 5, and HGW unit 200 is supplied from ONU unit 100. Each device is supplied with power from normal commercial power source 5. Therefore, it can operate in the normal mode. In addition, in the subscriber side apparatus 4 (ONU part 100, HGW part 200), when there is no communication, it is also possible to shift to a power saving mode.

(2) When the USB device 6 is supplied from the battery 502, the ONU unit 100 is supplied from the commercial power source 5, and the HGW unit 200 is supplied from the ONU unit 100. For example, the USB device 6 is unplugged from the commercial power source 5 and carried. It is in a state where it is connected to the person side device 4. Since the subscriber-side device 4 receives power from the commercial power supply 5, the subscriber-side device 4 (ONU unit 100, HGW unit 200) can operate in the normal mode. Further, although the USB device 6 is battery-driven, it does not supply power to the subscriber side device 4, and therefore may be in a normal power saving mode.

(3) When USB device 6 is supplied from commercial power source 5, ONU unit 100 is supplied from USB device 6, HGW unit 200 is supplied from ONU unit 100 In subscriber side device 4, power supply from commercial power source 5 is interrupted Therefore, power is supplied from the USB device 6. In this case, the subscriber side device 4 determines that the ONU unit 100 is supplied from the USB device 6 and shifts to the power saving mode. Similarly, in the subscriber side device 4, the HGW unit 200 also shifts to the power saving mode. Since the USB device 6 is supplied with power from the commercial power source 5, it can operate in the normal mode.

(4) When the USB device 6 is supplied from the battery 502, the ONU unit 100 is supplied from the USB device 6, and the HGW unit 200 is supplied from the ONU unit 100. The power supply from the commercial power supply 5 is interrupted in each device during a power failure, etc. Is the situation. In this case, since the power supply from the commercial power supply 5 is interrupted in the subscriber side device 4, power is supplied from the USB device 6, but the USB device 6 is also battery-driven. Therefore, the subscriber side device 4 (ONU unit 100, HGW unit 200) is in the power saving mode, and the USB device 6 is also in the power saving mode. In (4), each device is in a power saving mode, but may be in a mode in which power consumption can be further reduced as compared with the cases (1) to (3). Thereby, it becomes possible to extend the operation time (utilization time) of the entire system.

  Next, the case of the second embodiment will be described. In the configuration of the second embodiment (see FIG. 10), the devices that can be directly connected to the commercial power supply 5 are the HGW unit 400 and the USB device 6 of the subscriber side device 4a. A device that can operate as a battery is the USB device 6. The HGW unit 400 and the USB device 6 of the subscriber side device 4a can switch the operation mode to the power saving mode based on their own judgment. In the configuration shown in FIG. 10, the following four patterns can be considered as combinations of power supply to each configuration.

(5) When the USB device 6 is supplied from the commercial power source 5, the HGW unit 400 is supplied from the commercial power source 5, and the ONU unit 300 is supplied from the HGW unit 400. Each device is supplied with power from the normal commercial power source 5. Therefore, it can operate in the normal mode. In addition, in the subscriber side apparatus 4a (HGW part 400, ONU part 300), when there is no communication, it is also possible to shift to a power saving mode.

(6) USB device 6: Supply from battery 502, HGW unit 400: Supply from commercial power supply 5, ONU unit 300: Supply from HGW unit 400 For example, USB device 6 is unplugged from commercial power supply 5 and carried and joined It is in a state where it is connected to the person side device 4a. Since the subscriber side device 4a receives power from the commercial power source 5, the subscriber side device 4a (HGW unit 400, ONU unit 300) can operate in the normal mode. Further, although the USB device 6 is battery-driven, it does not supply power to the subscriber side device 4a, and therefore may be in a normal power saving mode.

(7) USB device 6: Supply from commercial power supply 5, HGW unit 400: Supply from USB device 6, ONU unit 300: Supply from HGW unit 400 In subscriber apparatus 4a, power supply from commercial power supply 5 is interrupted Therefore, power is supplied from the USB device 6. In this case, the subscriber side device 4a determines that the HGW unit 400 is supplied from the USB device 6, and shifts to the power saving mode. Similarly, in the subscriber side device 4a, the ONU unit 300 also shifts to the power saving mode. Since the USB device 6 is supplied with power from the commercial power source 5, it can operate in the normal mode.

(8) When the USB device 6 is supplied from the battery 502, the HGW unit 400 is supplied from the USB device 6, and the ONU unit 300 is supplied from the HGW unit 400. The power supply from the commercial power supply 5 is interrupted in each device, such as during a power failure. Is the situation. In this case, in the subscriber side apparatus 4a, since the power supply from the commercial power source 5 is interrupted, power is supplied from the USB device 6, but the USB device 6 is also battery-driven. Therefore, the subscriber side device 4a (HGW unit 400, ONU unit 300) is in the power saving mode, and the USB device 6 is also in the power saving mode. In (8), each device is in the power saving mode, but it may be in a mode in which power consumption can be further reduced as compared with the cases of (5) to (7). Thereby, it becomes possible to extend the operation time (utilization time) of the entire system.

  As described above, when the subscriber-side devices 4 and 4a and the USB device 6 change the operation mode, in the communication system constituted by these devices, the operation time (usage time) of the entire system can be extended. It becomes possible.

Embodiment 4 FIG.
In the first to third embodiments, the USB device 6 recognizes the other party (subscriber side devices 4 and 4a) to be connected to the USB, and shifts to the power saving mode as necessary. In the present embodiment, a case will be described in which the USB device 6 cannot determine a partner device to which a USB connection is made. A different part from Embodiments 1-3 is demonstrated.

  In the subscriber side device 4 and the USB device 6, a process in which the USB device 6 reduces power consumption at the time of a power failure in which the commercial power supply 5 cannot be used will be described. FIG. 12 is a sequence diagram showing transition of operation modes in the USB device 6. As an example, the USB-connected device is the subscriber side device 4, but the same applies to the subscriber side device 4a.

  First, the USB device 6 that can be on the power supply side and the subscriber side device 4 are connected by USB (step S501). In the USB device 6, the USB connection determination unit 503 cannot determine the connected partner (subscriber side device 4), so the device type cannot be determined, and the mapping information cannot be stored in the USB connection DB 505 (step S502).

  When the power supply from the commercial power supply 5 is lost (step S503), the subscriber side device 4 switches to the power supply via USB (step S504). Then, the USB device 6 starts supplying power to the subscriber side device 4 (step S505).

  In the USB device 6, the supply destination device is unknown, but the USB supply determination unit 504 determines that there is a certain amount of power supply via USB (step S 506), and the USB device 6 is controlled by the control unit 509. Is set to the power saving mode (step S507). As the power saving mode at this time, it suffices to operate only the power supply via the USB, and the other processes may be in a stopped (sleep) state.

  In the USB device 6, when any processing occurs during the power saving mode, the control unit 509 returns the necessary function (configuration) from the sleep state to the normal mode (step S508), and after the generated processing ends (step S509). Again, the operation mode is set to the power saving mode (step S510).

  When the power supply from the commercial power source 5 is restored in the subscriber side device 4 (step S511), the USB device 6 ends the power supply to the subscriber side device 4 (step S512).

  Thereafter, in the USB device 6, the USB supply determination unit 504 detects the end of power supply by USB, and the operation mode is returned to the normal mode under the control of the control unit 509 (step S513).

  As described above, according to the present embodiment, the USB device 6 can shift itself to the power saving mode when the connection partner cannot be determined and there is a certain amount of power supply via the USB. . Even in this case, in the communication system constituted by the USB device 6 and the subscriber side device 4 or the subscriber side device 4a, the system is in a situation where the power supply from the commercial power source 5 is interrupted in each device such as a power failure. It is possible to extend the operation time (use time) as a whole.

Embodiment 5 FIG.
In the first to fourth embodiments, when notifying the change of the power supply mode from the ONU unit 100 to the HGW unit 200, or when notifying the change of the power supply mode from the HGW unit 400 to the ONU unit 300, for example, It is also possible to use a method of notifying with an Ether I / F or a method of notifying with a dedicated line. In the case of notifying with the Ether I / F, information may be embedded in the option code of the OAM frame, and determination may be made between both devices. Moreover, you may notify between both apparatuses using the line which is not utilized among what is connected with an Ether cable.

  Further, when communication via a wireless LAN is possible, the USB device 6 can notify the HGW unit 200 or the ONU unit 300 of the power supply mode directly. In addition, notification by an IP packet or USB, or notification by a dedicated line can be used when there is a dedicated line.

In addition, when each device is connected by Ethernet, an information area included in the Ethernet frame may be used. FIG. 13 is a diagram illustrating information in the Ethernet frame. The table above shows the information in the Ethernet frame, the lower frame shows the information of "Config_Reg ^a" in the "Encording" in the table above. As described above, it is also possible to use the reserved area (“rsvd” in the frame) of the control code in the order set column of 8B / 10B and 64B / 66B encoding.

Embodiment 6 FIG.
In the present embodiment, a method in which a notebook PC is assumed as the USB device 6 and the HGW unit 200 that is not directly connected to the USB device 6 in the subscriber apparatus 4 changes the operation mode will be described. A different part from Embodiment 1-5 is demonstrated.

  FIG. 14 is a sequence diagram showing transition of operation modes in the HGW unit 200 of the subscriber side device 4. As an example, the device connected to the USB is the subscriber side device 4, but the same applies to the subscriber side device 4a (in this case, the ONU unit 300 is not directly connected to the USB).

  First, as a USB device 6 that can be on the power supply side, the notebook PC and the ONU unit 100 of the subscriber apparatus 4 are connected by USB (step S601).

  The ONU unit 100 switches to operation by power supply via USB (step S602). Then, the notebook PC starts supplying power to the ONU unit 100 (step S603).

  In the notebook PC, the operation mode is set to the power saving mode (step S604), and the USB power supply to the ONU unit 100 is directly notified to the HGW unit 200 using a wireless LAN or the like (step S605).

  In response to the notification from the notebook PC, the HGW unit 200 shifts the operation mode to the power saving mode (step S606).

  When the power supply from the commercial power supply 5 is restored (step S607), the ONU unit 100 switches the power supply source from the notebook PC to the commercial power supply 5 (step S608). Then, the notebook PC ends the power supply to the ONU unit 100 (step S609).

  Thereafter, the notebook PC returns the operation mode to the normal mode (step S610), and directly notifies the HGW unit 200 that the USB power supply has been completed to the ONU unit 100 using a wireless LAN or the like (step S611).

  The HGW unit 200 receives the notification from the notebook PC and shifts the operation mode to the normal mode (step S612).

  As described above, when the USB device 6 can communicate by wireless LAN or the like like a notebook PC, it is also possible to directly notify the communication apparatus not connected by USB from the notebook PC. Specifically, when the notebook PC recognizes the neighboring HGW unit 200 by DHCP (Dynamic Host Configuration Protocol) or the like, the notebook PC may notify by unicast or broadcast by within the communication system. May be performed.

  Next, when direct notification by a wireless LAN or the like is not possible between the notebook PC and the HGW unit 200, a method via the ONU unit 100 may be used. FIG. 15 is a sequence diagram showing transition of operation modes in the HGW unit 200 of the subscriber side device 4. Similarly to FIG. 14, the subscriber side device 4a (in this case, it is the ONU unit 300 that is not directly connected to the USB).

  First, as a USB device 6 that can be on the power supply side, the notebook PC and the ONU unit 100 of the subscriber side device 4 are connected by USB (step S701). The ONU unit 100 switches to operation by power supply via USB (step S702).

  The notebook PC notifies the ONU unit 100 via the USB of information on the state of charge of the battery mounted on the notebook PC along with the information on the start of USB power supply (step S703). The ONU unit 100 notifies the information acquired from the notebook PC to the HGW unit 200 (step S704).

  Based on the acquired information, the HGW unit 200 sets the operation mode to the normal mode when there is a margin in the state of charge of the notebook PC, for example, when it is determined that the estimated available time is 3 hours or longer (step S705). .

  Further, the notebook PC notifies the ONU unit 100 of information on the state of charge of the battery mounted on the notebook PC via the USB (step S706). The ONU unit 100 notifies the information acquired from the notebook PC to the HGW unit 200 (step S707).

  The HGW unit 200 sets the operation mode to the power saving mode when there is a margin in the state of charge of the notebook PC based on the acquired information, for example, when the estimated available time is less than 1 hour (step S708). ).

  Specifically, the notebook PC notifies the ONU unit 100 using at least one of Ethernet OAM frame, IP packet, USB notification, or dedicated line notification. Can be transferred to the HGW unit 200. In addition to information on the state of charge of the battery mounted on the notebook PC, the content notified by the notebook PC may include supplying power to the ONU unit 100 as in FIG.

  Note that the HGW unit 200 may always be in the power saving mode in the case of USB power feeding regardless of the state of charge of the notebook PC in order to have a use time.

  As described above, when the USB device 6 is a notebook PC, power supply information can be notified directly or indirectly to the HGW unit 200.

  As described above, the communication system according to the present invention is useful for a PON system, and is particularly suitable for a system including a device that can shift to a power saving mode.

DESCRIPTION OF SYMBOLS 1 Host network 2 Station side device 3 Distributor 4, 4a Subscriber side device 5 Commercial power supply 6 USB device 7 IP phone 8 Analog phone 100, 300 ONU part 200, 400 HGW part

Claims (26)

A communication system comprising a subscriber-side device that relays communication between a host network and a terminal, and an external power supply device connected to the subscriber-side device,
The subscriber side device is:
A supply-side communication device that receives power supply from either a commercial power supply or the external power supply device and supplies power to the other communication devices in the subscriber-side device;
A power receiving communication device that receives power supply from the supply communication device;
With
The external power supply device is
A battery capable of supplying power to the subscriber side device;
With
When the supply side communication device receives power supply from the external power supply device, the operation mode of the supply side is set to a power saving mode capable of operating with lower power consumption than the normal mode,
The power-receiving-side communication device sets its own operation mode to a power-saving mode when the supply-side communication device receives power supply from the external power supply device.
A communication system characterized by the above. The external power supply device is
When power is supplied to the subscriber side device, its own operation mode is a power saving mode.
The communication system according to claim 1. The external power supply device is
When it is connectable with the commercial power supply and receives power supply from the commercial power supply and supplies power to the subscriber side device, it sets its own operation mode to a power saving mode and receives power supply from the commercial power supply. However, if power is supplied to the subscriber side device, its own operation mode is set to a power saving mode.
The communication system according to claim 1. The external power supply device is
If the device to be connected cannot be determined, the operation mode is set to the power saving mode based on the power supply amount.
The communication system according to claim 1, 2, or 3. The supply-side communication device notifies the power-receiving-side communication device that power is being supplied from the external power supply device;
The communication system according to any one of claims 1 to 4. The supply-side communication device performs notification to the power-receiving-side communication device using at least one of an Ethernet (registered trademark) OAM frame, an IP packet, a USB notification, or a dedicated line notification.
The communication system according to claim 5. The power-receiving-side communication device monitors the supply-side communication device and detects that the supply-side communication device is receiving power from the external power supply device;
The communication system according to any one of claims 1 to 4. The power-receiving-side communication device has received power from the external power supply device when the link speed with the supply-side communication device is slower than in the normal mode. To detect,
The communication system according to claim 7. The external power supply device notifies the power receiving communication device that power is being supplied to the supply communication device.
The communication system according to claim 1, 2, or 3. The external power supply apparatus supplies power to the supply-side communication apparatus using at least one of Ethernet OAM frame, IP packet, USB notification, or dedicated line notification. Notify the supply side communication device,
The supply side communication device transfers the notification received from the external power supply device to the power reception side communication device;
The communication system according to claim 1, 2, or 3. The external power supply device notifies the power receiving communication device in a communicable range that power is being supplied to the supply communication device by unicast or broadcast.
The communication system according to claim 3. The external power supply device includes information on a charging state of a battery included in the information to be notified,
The communication system according to claim 9, 10 or 11. The external power supply device is at least one of a notebook PC, a mobile phone, a portable music device, a USB hard disk, a tablet terminal, a smartphone, and an external battery device.
The communication system according to any one of claims 1 to 12. The subscriber-side device in a communication system comprising: a subscriber-side device that relays communication between a host network and a terminal; and an external power supply device connected to the subscriber-side device, the external device When the power supply device includes a battery capable of supplying power to the subscriber side device,
A supply-side communication device that receives power supply from either a commercial power supply or the external power supply device and supplies power to the other communication devices in the subscriber-side device;
A power receiving communication device that receives power supply from the supply communication device;
With
When the supply side communication device receives power supply from the external power supply device, the operation mode of the supply side is set to a power saving mode capable of operating with lower power consumption than the normal mode,
The power-receiving-side communication device sets its own operation mode to a power-saving mode when the supply-side communication device receives power supply from the external power supply device.
A subscriber-side device. The supply-side communication device notifies the power-receiving-side communication device that power is being supplied from the external power supply device;
The subscriber-side device according to claim 14, wherein: The supply side communication device performs notification to the power receiving side communication device using at least one of Ethernet OAM frame, IP packet, USB notification, or dedicated line notification.
The subscriber-side device according to claim 15, wherein The power-receiving-side communication device monitors the supply-side communication device and detects that the supply-side communication device is receiving power from the external power supply device;
The subscriber-side device according to claim 14, wherein: The power-receiving-side communication device has received power from the external power supply device when the link speed with the supply-side communication device is slower than in the normal mode. To detect,
The subscriber side device according to claim 17, wherein The external power supply device in a communication system comprising a subscriber side device that relays communication between a host network and a terminal, and an external power supply device connected to the subscriber side device,
A battery capable of supplying power to the subscriber side device;
With
When power is supplied to the subscriber side device, its own operation mode is a power saving mode.
An external power supply device. The external power supply device in a communication system comprising a subscriber side device that relays communication between a host network and a terminal, and an external power supply device connected to the subscriber side device,
A battery capable of supplying power to the subscriber side device;
With
When it is connectable with the commercial power supply and receives power supply from the commercial power supply and supplies power to the subscriber side device, it sets its own operation mode to a power saving mode and receives power supply from the commercial power supply. However, if power is supplied to the subscriber side device, its own operation mode is set to a power saving mode.
An external power supply device. If the device to be connected cannot be determined, the operation mode is set to the power saving mode based on the power supply amount.
The external power supply device according to claim 19 or 20, wherein The subscriber side device receives power from either a commercial power source or the external power supply device, and supplies power to other communication devices in the subscriber side device; and the supply side A power receiving side communication device that receives power supply from the communication device,
Notifying the power receiving side communication device that power is being supplied to the supply side communication device.
The external power supply device according to claim 19 or 20, wherein The subscriber side device receives power from either a commercial power source or the external power supply device, and supplies power to other communication devices in the subscriber side device; and the supply side A power receiving side communication device that receives power supply from the communication device,
Using at least one of Ethernet OAM frame, IP packet, USB notification, or dedicated line notification, the supply side communication device is notified to the supply side communication device. ,
The external power supply device according to claim 19 or 20, wherein The subscriber side device receives power from either a commercial power source or the external power supply device, and supplies power to other communication devices in the subscriber side device; and the supply side A power receiving side communication device that receives power supply from the communication device,
Notifying the power receiving side communication device in a communicable range that power is being supplied to the supply side communication device by unicast or broadcast,
The external power supply device according to claim 20. Include information on the state of charge of the battery provided in the information to be notified,
The external power supply device according to claim 22, 23, or 24. The external power supply device is at least one of a notebook PC, a mobile phone, a portable music device, a USB hard disk, a tablet terminal, a smartphone, and an external battery device.
The external power supply device according to any one of claims 19 to 25, wherein

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