JP2013197789A - Electronic apparatus and power control method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To save electric power of a communication processing function with a simple structure, while maintaining the communication quality of a data signal received in an electronic apparatus.SOLUTION: The electronic apparatus (2, printer devices 40, 140) includes a communication processing unit (21), a connection supervision unit (30), power supply units (26, 28) and a power supply controller (32). The communication processing unit performs data processing transmitted and received through a network (4). The connection supervision unit supervises the transition of a connection state between the communication processing unit and the network, from potential variation of a communication noise produced by the data transmission and reception. The power supply unit supplies power to the communication processing unit. The power supply controller controls power supply to the communication processing unit according to a connection state between the communication processing unit and the network.

Description

The present invention relates to an electronic device connected to a network, and relates to a power saving technique for performing power control according to a connection state of an interface.

  In an electronic device that is connected to a master computer via a network and transmits and receives data, various devices have been devised to reduce power consumption.

With regard to the power saving function of this electronic device, it is known to perform power supply control for an interface and a terminal device based on the presence or absence of detection of a link pulse transmitted from a connection destination device (for example, Patent Document 1).

Japanese Patent Laid-Open No. 11-88352

  By the way, in power saving of an electronic device, it is important to reduce standby power consumed while the functional unit is stopped. In particular, an electronic device connected to a LAN (Local Area Network) must always wait for a signal such as instruction information transmitted via the network. Regarding communication processing via a network, for example, in the IEEE (American Institute of Electrical and Electronics Engineers) 802.3 standard, a link pulse that is periodically output from an electronic device on the master side is output. When the slave-side electronic device receives the link pulse, it must send a response to the master-side electronic device. For this reason, in the electronic device on the slave side, for example, with respect to PHY (Physical Layer Device) which is a functional component of the network interface, it is difficult to determine the power supply stop compared to other functional components.

  As a means for determining the connection state between the electronic device and the LAN, for example, there is one that checks a connection state by branching a part of a signal line of a network interface. In this case, the connection state is confirmed by detecting a link pulse passing through the signal line. In the monitoring means that branches the circuit on the interface side, for example, in the transmission path composed of a plurality of signal lines, the impedance of some branched signal lines is mismatched, thereby affecting the electrical characteristics of the data signal. There is a possibility to give.

  Further, when the monitoring means is installed by branching a part of the signal lines in this way, it is necessary to match the electrical characteristics among the plurality of signal lines, for example, by separately providing an adjustment circuit.

Therefore, in view of the above problems, an object of the electronic device and the power supply control method of the present disclosure is to reduce the power consumption of the communication processing function with a simple configuration while maintaining the communication quality of the data signal received by the electronic device. It is in.

In order to achieve the above object, the configuration of the present disclosure includes a communication processing unit, a connection monitoring unit, a power supply unit, and a power supply control unit. The communication processing unit processes data to be transmitted / received via the network. The connection monitoring unit monitors the transition of the connection state between the communication processing unit and the network from the potential fluctuation of communication noise generated by data transmission / reception. The power supply unit supplies power to the communication processing unit. The power supply control unit controls power supply to the communication processing unit according to a connection state between the communication processing unit and the network.

  According to the electronic device of the present disclosure or the power supply control method thereof, any one of the following effects can be obtained.

  (1) By controlling the power supply to the function of the communication processing unit based on the potential fluctuation of the communication noise generated by the transmission / reception of data, the power saving process can be performed efficiently.

  (2) The connection state of the network interface can be monitored without affecting the data itself by monitoring the potential fluctuation of the communication noise caused by the communication without capturing the transmitted / received data itself.

  (3) It is possible to simplify the connection monitoring means of the network interface by taking in and monitoring the potential fluctuation of communication noise generated by the pulse transformer that performs data signal conversion.

Other objects, features, and advantages of the present invention will become clearer with reference to the accompanying drawings and each embodiment.

It is a figure which shows the structural example of the electronic apparatus which concerns on 1st Embodiment. It is a flowchart which shows an example of a power supply control process. It is a figure which shows the structural example of the power saving state of an electronic device. It is a figure which shows the structural example of the printer apparatus which concerns on 2nd Embodiment. It is a figure which shows the structural example of a pulse transformer. FIG. 4 is a diagram illustrating an example of a power saving state of a control unit of the printer apparatus. It is a flowchart which shows an example of a network connection determination process. 6 is a flowchart illustrating an example of operation control of the printer apparatus. It is a timing chart which shows an example of a power saving mode transition determination process. It is a flowchart which shows an example of the process of the return determination from a power saving mode. It is a figure which shows an example of the detection waveform at the time of LAN connection. It is a figure which shows an example of the detection waveform at the time of LAN disconnection. It is a figure which shows the structural example of the printer apparatus which concerns on other embodiment. It is a flowchart which shows an example of a power supply control process.

  [First Embodiment]

  FIG. 1 shows a configuration example of an electronic device according to the first embodiment. The configuration shown in FIG. 1 is an example, and the present invention is not limited to such a configuration.

  An electronic device 2 illustrated in FIG. 1 is an example of the electronic device of the present disclosure, and is connected to an external device 6 via a communication cable 8 connected to the network 4. As the communication cable 8, for example, a LAN cable standardized by IEEE802.3 can be used. The electronic device 2 executes processing based on operation instructions and data information received from the external device 6 via, for example, the communication cable 8.

  The external device 6 is an output source of operation control information for the electronic device 2 and constitutes a master relationship with the slave-side electronic device 2 that receives the control information. The external device 6 is composed of, for example, a PC (Personal Computer) connected to the network 4, a switching hub, a router, and the like. For example, the external device 6 periodically transmits a link pulse signal to the electronic device 2 in order to check the connection state, and monitors the response signal output from the electronic device 2. The external device 6 has a power saving control function for turning off the power supply to the transmission / reception function with respect to the network 4 side and other functions based on the use state and the standby time regardless of the connection state with the electronic device 2, for example. ing.

  The electronic device 2 is an information processing device such as a printer according to the external device 6. The electronic device 2 includes, for example, a control unit 10 that configures a communication processing function and a power supply control function, and a function control unit 12 that controls an operation mechanism and the like.

  The control unit 10 is configured by a single circuit board including, for example, a processor core, and receives operation instruction signals and data signals from the external device 6, outputs control information to the function control unit 12, power supply control, and the like. Do. The control unit 10 also monitors the connection state between the electronic device 2 and the network 4. As a monitoring process, it is monitored whether a control signal or the like is received with the external device 6 via the network 4. Thereby, the control unit 10 determines, for example, whether the external device 6 is in a power saving state or whether the communication cable 8 is physically connected. For example, the interface connector 15 of the communication cable 8 is connected to the interface connector 14 of the control unit 10. Further, the function control unit 12 is connected to the control unit 10 via an interface connector 16, for example.

  The function control unit 12 is a function module that processes the control information generated by the control unit 10 and constitutes a function unit such as a printer engine, for example. The function control unit 12 includes, for example, software and hardware.

  With such a configuration, the electronic device 2 monitors the connection state with the network 4, and performs power supply control on the communication processing unit 21 that processes data transmitted / received via the network 4 according to the connection state. That is, when the external device 6 is in an operating state and connected via the network 4, the electronic device 2 supplies power to the communication processing unit 21. Further, when the connection state between the network 4 and the electronic device 2 changes due to the external device 6 being suspended or the communication cable 8 being cut off, the electronic device 2 stops the power supply to the communication processing unit 21. . The electronic device 2 resumes power supply to the communication processing unit 21 when the connection state with the network 4 changes due to communication resumption from the external device 6 side or the like.

  The control unit 10 is configured by a computer, and includes a pulse tunnel 20 and a communication processing unit 21 on a transmission path connected to the interface connector 14, for example. The control unit 10 includes a first power supply unit 26, a second power supply unit 28, a connection monitoring unit 30, a power supply control unit 32, a memory controller 34, a memory 36, and an interface control circuit 38.

  The pulse transformer 20 is means for transmitting an AC signal having a pulse waveform to the communication processing unit 21 through the communication cable 8. The pulse transformer 20 receives a data signal or control signal from the external device 6 received via the communication cable 8, and outputs a signal subjected to, for example, signal level conversion or communication noise insulation to the communication processing unit 21 side. .

  Communication data is superimposed on the data signal received via the communication cable 8 and transmitted. This communication noise includes, for example, common mode noise generated between a transmission path configured in the electronic device 2 and a ground (GND) (not shown). This common mode noise is generated when a data signal from the external device 6 is received, and a potential fluctuation of, for example, 50 to 200 [mV] occurs. Therefore, the pulse transformer 20 extracts the potential of common mode noise generated in the transmission path, and outputs it to the connection monitoring unit 30 via the power supply control unit 32. For example, the pulse transformer 20 extracts the connection state information between the network 4 and the communication processing unit 21 without electrically contacting a data signal received from the external device 6 with a detection circuit or the like. In other words, in this connection monitoring, for example, the potential fluctuation generated at the center tap installed in the pulse transformer 20 is used, and the data signal passing through the transmission path is not captured.

  For example, the pulse transformer 20 may be integrated with the interface connector 14 to form a connector unit.

  The communication processing unit 21 is configured to perform processing of data to be transmitted / received, and includes, for example, a PHY 22 and a LAN controller 24. The PHY (Physical Layer Device) 22 is an example of a device that executes, for example, conversion of a received signal, processing based on a protocol, division, analysis of a header portion included in data, and the like. The PHY 22 is an example of a network interface. The LAN controller 24 is an example of a unit that controls signal processing transmitted / received to / from the external device 6 via the network 4.

  As described above, the communication processing unit 21 needs to maintain the reception standby state when the master-side external device 6 connected via the network 4 is activated. Therefore, for example, even when the power saving mode is executed when the electronic device 2 does not operate for a certain period of time, the communication processing unit 21 is maintained in the energized state unless it can be determined that the external device 6 has stopped.

  The first power supply unit 26 constitutes a constant power supply unit. For example, the first power supply unit 26 is connected to the pulse transformer 20, the power supply control unit 32, the connection monitoring unit 30, the memory controller 34, the memory 36, the interface control circuit 38, and the like through the power supply line 27. Has been feeding.

  The second power supply unit 28 is a control power supply controlled by the power supply control unit 32. For example, the PHY 22 and the LAN controller 24 are connected to the second power supply unit 28 via a power supply line 29 to supply power. Then, the second power supply unit 28 stops power supply to the communication processing unit 21 when the connection between the communication processing unit 21 and the network 4 is released based on a control instruction from the power supply control unit 32. Further, when the connection between the communication processing unit 21 and the network 4 is resumed, the power supply to the communication processing unit 21 is resumed. The feed lines 27 and 29 do not indicate a single physical feed cable.

  The connection monitoring unit 30 is a means for monitoring the connection state between the communication processing unit 21 and the network 4 and includes, for example, a processor core that executes a connection monitoring program. For example, a detection voltage value is input to the connection monitoring unit 30 as potential information of communication noise generated in the pulse transformer 20 via the power supply control unit 32. The connection monitoring unit 30 monitors the transition of the network 4 and the communication processing unit 21 from the connected state to the disconnected state, or the transition from the disconnected state to the connected state, for example, based on a change in voltage value detected from communication noise. Then, the connection monitoring unit 30 outputs an instruction for maintaining, stopping, or restarting the power supply to the power supply control unit 32 based on the monitoring result.

  The power supply control unit 32 performs power management on the second power supply unit 28. This power management stops the power supply of the second power supply unit 28 when the connection between the communication processing unit 21 and the network 4 is released by the power supply instruction based on the monitoring result from the connection monitoring unit 30. When the connection between the communication processing unit 21 and the network 4 is resumed, the power supply from the second power supply unit 28 is resumed.

  The power supply control unit 32 includes, for example, a comparison circuit that extracts signal information that can be determined by a computer from detection waveform information of a voltage value of communication noise captured from the pulse transformer 20, a switch circuit, and a wakeup event circuit that starts and stops the power supply Etc.

  The memory controller 34 is means for controlling writing or reading of programs and data to and from the memory 36 in accordance with instructions from the processor core that functions as the connection monitoring unit 30.

  The memory 36 constitutes, for example, a storage area of the control unit 10 or an execution area of a program that is processed by the processor core. In the storage area, for example, an OS (Operating System) for operating the electronic device 2, a connection monitoring process, a communication process, or a program for generating an operation instruction for the function control unit 12 is stored. The interface control circuit 38 is a configuration example that exchanges data communication and power supply control information between the control unit 10 and the function control unit 12.

  In the electronic device 2, the program for performing power supply control is not limited to the program stored in the memory 36, and for example, a program stored in a CD, a DVD, or an external storage device may be read. In addition, the control unit 10 may fetch and execute such a program from the external device 6 or other storage device connected on the network 4.

  Next, FIG. 2 shows an example of power control processing by the electronic device. The processing content and processing procedure shown in FIG. 2 are examples, and the present invention is not limited to such a configuration.

  In the power supply control process shown in FIG. 2, monitoring is performed using a voltage value in which a potential fluctuation caused by communication noise taken in from the pulse transformer 20 by the connection monitoring unit 30 is detected (S11). In this potential monitoring, it is determined whether or not the communication function unit 21 of the electronic device 2 is disconnected from the network 4 (S12).

  If it is a non-connection state (YES of S12), a control instruction will be output from the connection monitoring part 30 to the electric power feeding control part 32, and the electric power feeding by the 2nd power supply part 28 will be controlled to OFF (S13). When the power supply by the second power supply unit 28 is stopped, the communication function unit 21 is stopped and a sleep state is entered. Moreover, if it is a connection state (NO of S12), the electric power feeding by the 2nd power supply part 28 will be maintained. In this case, the connection monitoring unit 30 detects a potential fluctuation caused by communication noise.

  After the power supply is stopped, the connection monitoring unit 30 monitors the potential fluctuation of communication noise in the pulse transformer 20 (S14). Then, the connection monitoring unit 30 determines whether or not the network 4 and the communication function unit 21 are connected (S15). If a potential fluctuation of communication noise in the pulse transformer is detected by this monitoring process, it is determined that the connection state between the network 4 and the communication processing unit 21 has been resumed (YES in S15). When the connection with the network 4 is resumed, the power supply control unit 32 outputs a power supply start instruction to the second power supply unit 28 based on the power supply restart instruction from the connection monitoring unit 30 (S16). If the connection with the network 4 is suspended (NO in S15), the monitoring process is continued (S14).

  With this power control, if the electronic device 2 is disconnected from the network 4 and the communication processing unit 21 due to the transition of the external device 6 to the sleep state (power saving mode) or the release of the interface connectors 14 and 15, Power supply to the communication processing unit 21 is stopped. Thereby, the communication function part 21 of the electronic device 2 can achieve power saving of the LAN connection function in conjunction with the power saving state of the external device 6, for example.

  According to such a configuration, the power saving process can be efficiently performed by controlling the power supply to the function of the communication processing unit based on the potential fluctuation of the communication noise generated by the transmission / reception of the data signal. In addition, by monitoring the potential fluctuation of communication noise caused by communication without taking in the data to be transmitted / received, the connection state of the network interface can be monitored without affecting the data itself. By capturing and monitoring potential fluctuations of communication noise generated in a pulse transformer that performs data signal conversion, it is possible to simplify the connection monitoring means of the network interface. When the connection to the network is resumed in a state where the power supply of the communication processing unit is stopped, the communication processing unit can be quickly restored based on the potential fluctuation detected by the pulse transformer.

  [Second Embodiment]

  FIG. 4 shows a configuration example of a printer apparatus according to the second embodiment. The configuration shown in FIG. 4 is an example, and the present invention is not limited to such a configuration. In FIG. 4, the same components as those in FIG.

  A printer device 40 shown in FIG. 4 is an example of the electronic device of the present disclosure. As described above, the pulse transformer 20 monitors the connection with the network 4 from the potential fluctuation of the communication noise caused by the reception or transmission of the data signal. doing. Then, based on the monitoring result, the printer device 40 performs power supply control for stopping power supply to the communication processing unit configured by, for example, the PHY 22.

  The printer device 40 includes, for example, a printer control unit 42 and a printer engine 44 having a connection monitoring function with the network 4 and a power supply control function. The power control of the printer device 40 includes, for example, power saving modes 1, 2, and 3. In the power saving mode 1, for example, the clock operation is stopped as a part of the control function. In the power saving mode 2, the printer engine 44, which is one of the functional modules of the printer device 40, is turned off and the printing operation is stopped. The power saving mode 3 is a power control method according to the present disclosure, and stops power supply to the communication processing unit side in conjunction with the power saving state of the external device 6 or the disconnection from the network 4 due to the removal of the communication cable 8. To do.

  The printer control unit 42 is an example of the control unit 10 and is configured by a computer, and includes, for example, an MCU (Micro Controller Unit) 50, a comparator 52, an FET (field effect transistor) 54, and a video controller 56. The printer control unit 42 includes a power generation unit 60, a constant power supply unit (VDDC) 62, and a power supply unit (VDD) 64. The printer engine 44 constitutes the function control unit 12 described above, and is a functional module that executes control of a mechanism unit that performs printing, processing of image information to be printed, and the like.

  The MCU 50 is a microprocessor in which a computer system is configured by a single integrated circuit, for example. The MCU 50 controls the print instruction and print data from the external device 6 received through the interface connectors 14 and 15 and outputs them to the printer engine 44 side. The MCU 50 also performs monitoring control of the connection state between the printer device 40 and the network 4, power supply control linked to the connection state, and the like. The MCU 50 includes, for example, a processor core 58, a LAN controller 24, a power supply control unit 32, a memory controller 34, and the like.

  The processor core 58 functions as the connection monitoring unit 30 described above by executing a network connection monitoring program. For example, the processor core 58 determines whether or not the LAN is in an ON state from a communication noise potential signal taken from the pulse transformer 20, and outputs a power supply ON / OFF instruction to the power supply control unit 32. After the VDD 64 is turned OFF, the detection signal from the comparator 52 is monitored, and when connection with the network 4 is confirmed, a power supply return instruction is output to the power supply control unit 32.

  The switch circuit 59 of the power supply control unit 32 is switched between conduction and non-conduction in accordance with a control instruction output from the processor core 58. The switch circuit 59 is a trigger input circuit that switches ON / OFF of the FET 54 and stops the VDD 64, and constitutes a wake-up event circuit that starts the VDD 64.

  The comparator 52 is means for detecting potential fluctuations caused by communication noise. This comparator 52 is connected to either the center tap 74 of the primary winding 70 or the center tap 76 of the secondary winding 72 in a part of the transmission path of the pulse transformer 20 shown in FIG. The voltage value is taken in. The center taps 74 and 76 of the pulse transformer 20 are configured to maintain a voltage balance at the midpoint between the primary winding 70 and the secondary winding 72. For example, a pull-up for maintaining the ground or a constant voltage. The circuit is connected.

  In the printer device 40, voltage values at the existing center taps 74 and 76 are detected. Then, the processor core 58 monitors the connection state with the network 4 from the increase or fluctuation of the voltage value due to the common mode noise generated by the data signal received from the external device 6 via the network 4. That is, the printer device 40 does not directly detect the data signal itself taken in by a transmission path branch or the like. As a result, the printer 40 can monitor the connection state to the network 4 without electrically contacting the received data.

  The comparator 52 detects the connection with the network 4 from the voltage level fluctuation caused by the propagation of the common mode noise for the voltage value acquired from the center tap 74 or 76. Specifically, for example, the comparator 52 compares the acquired voltage value with a reference voltage value, and outputs a “LAN_on” signal indicating the comparison result. As a result of this comparison, when a voltage value higher than the reference voltage value is detected, for example, “Hi” (high level) is output as the “LAN_on” signal to the power supply control unit 32 side. When the connection with the network 4 is released, the voltage value becomes smaller than the reference voltage, and “Low” (low level) is output.

  The video controller 56 is an example of an interface control circuit with the printer engine 44 side, and functions in accordance with a control instruction from the processor core 58. The video controller 56 controls, for example, a printer execution instruction, a video output signal transmission, or a response signal reception process from the printer engine 44 side to the printer engine 44 side.

  The power generation unit 60 generates a power output by feeding from a commercial AC power source. The VDDC 62 corresponds to the first power supply unit 26 described above, and always receives a power supply output from the power generation unit 60. The VDDC 62 supplies power to the connection monitoring function with the network 4 configured by the MCU 50 and the like through the power supply line 63. The VDD 64 corresponds to the second power supply unit 28 described above. The VDD 64 receives power supply output from the power generation unit 60 via the FET 54 and supplies power. The VDD 64 supplies power to, for example, the PHY 22 and the LAN controller 24 that configure the communication processing unit through the power supply line 65. The FET 54 is an example of a switch circuit that switches between conduction and non-conduction in accordance with a power supply control instruction from the power supply control unit 32. The VDD 64 generates a power supply output only when the FET 54 is conductive.

  In such a configuration, when the network 4 transitions from the connected state to the disconnected state, the power supply control unit 32 outputs a Low signal in the power supply control signal pow_ctl in accordance with an instruction from the processor core 58. In response to this output, the FET 54 is turned off. As a result, the VDD 64 shown in FIG. 6 is stopped, and for example, power supply to the PHY 22 and the LAN controller 24 configuring the communication processing unit is stopped, and the power saving mode is set.

  When the network 4 transitions from the disconnected state to the connected state, the voltage value of the center tap signal of the pulse transformer 20 increases, and the LAN_on signal from the comparator 52 becomes Hi. Then, the processor core 58 outputs an instruction to resume power supply to the power supply control unit 32 based on the Hi signal from the comparator 52. The power supply control unit 32 switches the switch circuit 59 and outputs a Hi signal with a pow_ctl signal to the FET. As a result, the FET 54 is switched to the connected state, and power supply from the VDD 64 is resumed.

  FIG. 7 shows an example of a network connection determination process of the printer apparatus. The processing procedure and processing contents shown in FIG. 7 are examples, and the present invention is not limited to such a configuration.

  In the processing shown in FIG. 7, for example, when the printer device 40 is powered on, initial operations such as reading of a program from the memory 36 by the processor core 58 and execution of other initializations are performed (S21). When the printer device 40 starts up, the processor core 58 monitors the LAN connection state (S22). The processor core 58 takes in the voltage comparison signal from the comparator 52 and determines whether or not the LAN is connected (S23).

  When it is determined that the processor core 58 is connected to the LAN (YES in S23), the processor core 58 maintains power supply to the communication processing unit and maintains the online state for the network 4 (S24). Further, when the processor core 58 determines that it is not connected to the LAN based on the comparison result from the comparator 52 (NO in S23), the processor core 58 outputs an instruction to the power supply control unit 32 and sends it to the communication processing unit such as the PHY 22 or the like. The power supply is stopped, and the transmission data processing function is shifted to the OFF state (S25).

  The LAN connection state monitoring process in S22 is continuously executed while the printer device 40 is in an energized state, for example. If the power supply to the communication processing unit including the PHY is in the OFF state, for example, when the connection with the LAN is resumed (YES in S23), the power supply to the communication processing unit is resumed and the online state is changed ( S24).

  Next, FIG. 8 shows an example of operation control processing of the printer apparatus.

  The processing procedure illustrated in FIG. 8 is an example of the power control method according to the present disclosure, and includes, for example, preparation processing for shifting to the power saving mode 3 for the printer device 40 in the state of the power saving mode 2. This operation control is executed in the processor core 58 configured in the MCU 50, and transitions to, for example, a state A indicating standby, a state B indicating a disconnected state, and a state C indicating a power saving mode 3.

  In this processing procedure, for example, due to the continuation of the standby state of the printer device 40, the power saving mode 1 is shifted to the power saving mode 2 in which a part of the functional units are set to the standby state (S31). The sleep monitoring process monitors, for example, whether the external device 6 has shifted to the power saving state or whether the interface connectors 14 and 15 are connected (S32). Then, the voltage value of the center tap signal of the pulse transformer 20 is detected, and it is determined from the connection state of the network interface whether the printer control unit 42 is connected to the network 4 (LAN) (S33).

  If the network interface is in a connected state (YES in S33), the process returns to S32 because it is necessary to wait for communication from the external device 6.

  When the network interface is not connected (NO in S33), preparation for shifting to the power saving mode 3 is performed (S34). In this transition preparation process, for example, in response to an instruction from the processor core 58, a wake-up event is set for the power supply control unit 32, and a power-off instruction is issued to the PHY 22, which is a network interface control circuit (S34). Thereby, the printer apparatus 40 shifts to the power saving mode 3 (S35).

  With this process, when it is confirmed that the connection state with the network 4 is monitored in the sleep monitoring process and the response operation to the operation instruction from the external device 6 and the response process to the link pulse are not required, the power saving mode 3 Can be migrated to. In addition, power saving of the printer device 40 can be achieved in conjunction with the connection state of the network interface.

  FIG. 9 and FIG. 10 show an example of determination processing for transition to the power saving mode or determination processing for returning from the power saving mode.

  In the transition determination process to the power saving mode 3 shown in FIG. 9, the LAN_on signal indicating the comparison result of the voltage value captured from the pulse transformer 20 by the comparator 52 is monitored (S1). When the detected voltage value shown in FIG. 11 has a constant amplitude value, the comparator 52 outputs the LAN_on signal as Hi, indicating the connection state with the network 4. At this time, the power supply control unit 32 maintains the control signal pow_ctl for the FET 54 at the Hi output, and power is supplied by VDD64.

  When the connection with the network 4 is canceled due to the external device 6 shifting to the power saving mode or the like, the processor core 58 confirms that the LAN_on signal from the comparator 52 is in the Low state. That is, as shown in FIG. 12, whether or not the amplitude of the detected voltage value taken in by the comparator 52 from the pulse transformer 20 is minute or 0, the LAN connection state changes, and whether or not the preparation for shifting to the power saving mode 3 is started. Is determined (S2). In the LAN connection monitoring (state B), the signal pow_ctl signal from the power supply control unit 32 is maintained in the Hi state, so that power supply to the communication processing unit by the VDD 64 is maintained. For the determination in S2, for example, a determination period of a predetermined time is set, and the standby state is maintained until the determination period elapses, for example, by a timer (not shown).

  When preparation for shifting to the power saving mode 3 is set, the processor core 58 outputs a power supply stop instruction to the power supply control unit 32 based on the Low signal of LAN_on (S3). In response to an instruction from the processor core 58, the power supply control unit 32 sets pow_ctl to Low, and shifts the FET 54 to the unconnected state. When the FET 54 is in a non-connected state, power is not supplied from the power generation unit 60 to the VDD 64, and the mode shifts to the power saving mode 3 in which the communication processing unit connected to the VDD 64 is suspended.

  (1) Masking the cause of an event from the external interface

  Even if a data request or a processing request arrives from an external interface such as a LAN or an operation button, in order to avoid a recovery request from being generated during the process of shifting to the power saving mode 3, For this processing, mask processing is performed. Specifically, a gate (mask) instruction is issued to the external interrupt input block in the processor core 58 to complete the mask process.

  (2) Recovery point recovery processing when returning

  For example, the recovery point and the restart data when the power saving mode 3 is recovered are saved in the memory 36, for example. As a result, the processor core 58 executes the process from the saved point at the time of recovery, so that the process before the transition to the power saving mode 3 can be resumed.

  The processor core 58 saves (copies) the value of the program counter configured in the processor core 58, for example, in a pointer that the processor core 58 first refers to at the time of recovery. Further, the processor core 58 purges (discharges) the contents stored in the volatile memory such as the internal cache to the external memory and completes the processing.

  (3) Wake-up event condition setting processing

  A return condition by the power supply control unit 32 is set. In this embodiment, for example, a command is issued so that the return condition is based on the Hi level of the input signal LAN_on from the comparator 52, and the process is completed. After this process, in the power supply control unit 32, when the input signal LAN_on becomes Hi, the power supply control signal pow_ctl becomes active (Hi).

  (4) Transition to power saving mode 3

  A command is issued to the power supply control unit 32, and the process of executing the power saving mode 3 is completed. With this process, the power supply control unit 32 cancels (negates) the power supply control signal pow_ctl (state S3). When the power control signal pow_ctl is canceled, the power control FET 54 receiving the power control signal pow_ctl at the gate shifts to the OFF state, the power supply of VDD 64 is canceled, and the shift to the power saving mode 3 is completed. .

  According to such processing, the power supply on the communication processing unit side such as the PHY 22 and the LAN controller 24 of the printer device 40 can be cut in conjunction with the release of the connection state of the network 4.

  In the restart determination process from the power saving mode shown in FIG. 10, the state C monitors the restart of the connection from the power saving mode 3 to the network 4.

  (1) Power saving mode 3 (State C)

  In the power saving mode 3, the power supply to the communication processing unit by the VDD 64 is stopped when the LAN is in an inactive state because the network 4 and the printer device 40 are not connected or the external device 6 is powered off. At this time, the input signal LAN_on from the comparator 52 to the power supply control unit 32 is in the Low state.

  (2) Wake-up state

  The processor core 58 detects that LAN_on has changed from Low to Hi (S4). That is, when energization of the external device 6 is resumed or the LAN is activated when the communication cable 8 is connected, the voltage value of the center tap signal detected from the pulse transformer 20 increases due to common mode noise and oscillates. As a result, the comparator 52 switches the LAN_on signal to Hi by receiving an input equal to or higher than the reference voltage as shown in FIG. At this time, the pow_ctl signal of the power supply control unit 32 is in the Low state and the FET 54 is in the non-connected state, so that the VDD 64 stops supplying power.

  (3) Connection detection

  Upon receiving the Hi signal from the comparator 52, the power supply control unit 32 starts a wakeup event (S5). Then, based on an instruction from the processor core 58, the pow_ctl signal for the FET 54 is switched to Hi.

  (4) Power on

  When the output signal pow_ctl becomes Hi (active), the gate of the FET 54 is turned ON, and the VDD 64 receives power supply from the power generation unit 60 and resumes power supply to the PHY 22 and the LAN controller 24.

  According to such a configuration, the potential fluctuation caused by the common mode noise generated by the data transmission / reception is utilized, and the power supply to the function of the communication processing unit is controlled in conjunction with the connection state with the network, thereby efficiently saving. The electrification process can be performed. Further, since the circuit is not branched in order to capture the data itself to be transmitted and received in the network interface, the impedance on the transmission path is not affected. Therefore, for example, even when a part of a plurality of transmission paths is used for network connection detection, it is not necessary to install a circuit configuration for matching impedance characteristics and the like with other transmission paths. Further, since the network connection can be monitored without electrically contacting the received data signal, there is no electrical influence on the data signal.

  [Other Embodiments]

  (1) In the above embodiment, the configuration of the printer device 40 is shown as an example of the electronic device 2 connected to the external device 6 through the network 4, but the configuration is not limited to such configuration. For example, any electronic device connected using the LAN standard communication cable 8 and having a master-slave relationship with the external device 6 may be used. For example, a scanner device, a FAX, a photographing device, a TV device, a recorder, Equipment may be used.

  (2) In the above-described embodiment, the configuration in which the PHY 22 and the LAN controller 24 that are communication processing units are shifted to the power saving state when the connection state with the network 4 is released has been described. In the electronic device 2 or the printer device 40, for example, the power supply is controlled to the functional units other than the pulse transformer 20 that monitors the network connection, the connection monitoring unit 30 including the processor core 58, the power supply control unit 32, and the comparator 52. Also good. For example, the memory controller 34, the memory 36, the interface control circuit 38, and the function control unit 12 may be set as such function units. In this case, the functional unit that cuts power supply may be connected to the second power supply unit 28 and VDD 64.

    According to such a configuration, standby power can be suppressed when the network 4 is disconnected.

  (3) Further, in the power supply control of the electronic device 2, the power supply to the processor core 58 may be cut off. A printer device 140 illustrated in FIG. 13 is an example of the electronic device 2 of the present disclosure. The printer device 140 includes a printer control unit 142 and a printer engine 44. The printer control unit 142 includes, for example, the MCU 50, and monitors the transition of the connection state of the network 4 from the voltage value of the center tap signal of the pulse transformer 20 as described above, and performs power supply control.

  The MCU 50 includes, for example, the power supply control unit 32, the processor core 58, the memory controller 34, the LAN controller 24, and the like described above. In the power supply control unit 32, for example, a connection monitoring unit 80 is configured together with the switch circuit 59.

  For example, when the printer device 140 shifts to the power saving mode, the connection monitoring unit 80 configures a wake-up circuit that detects resumption of connection with the network 4 instead of the processor core 58. For example, when the LAN_on signal from the comparator 52 changes from Low to Hi, the connection monitoring unit 80 outputs an instruction to resume power supply to the switch circuit 59. As a result, the power supply control unit 32 switches the pow_ctl signal from Low to Hi for the FET 54 and resumes power supply by the VDD 64.

  For example, when the LAN_on signal from the comparator 52 changes from Hi to Low, the processor core 58 outputs a power supply stop instruction to the power supply control unit 32 and also instructs the connection monitoring unit 80 to switch the connection monitoring function. Should be output.

  In addition to supplying power to the PHY 22 and the LAN controller 24 as described above, the VDD 64 may supply power to the processor core 58, the memory controller 34, the memory 36, the video controller 56, and the like. Then, when the power of the external device 6 is turned off or when the connection with the network 4 is canceled due to the disconnection of the communication cable 8 or the like, the mode shifts to a power saving mode in which power supply to the VDD 64 is stopped.

  In the present embodiment, the printer device 140 uses, for example, only the LAN as the interface connector 14 for connecting to the external device 6. However, the present invention is not limited to this. The printer device 140 may be provided with a USB (Universal Serial Bus) or the like as another interface, for example. In such a power supply control process, it is only necessary that interfaces other than the LAN are not connected to the external device 6 or the connection with the network 4 is stopped.

  FIG. 14 shows an example of the power control process. In this power supply control process, the processor core 58 monitors the potential fluctuation of the pulse transformer 20 (S41). As described above, the connection value of the network 4 is determined by taking in the voltage value of the center tap signal of the pulse transformer 20 by the comparator 52 and detecting the voltage value equal to or higher than the reference voltage value. Then, it is determined whether or not the network 4 is disconnected (S42). If the connected state is maintained (NO in S42), the monitoring process is continued. When it is determined that the voltage value decreases and the network 4 is disconnected (YES in S42), a control instruction is output to the power supply control unit 32, and power supply by the VDD 64 is stopped (S43).

  After power supply is stopped, the connection monitoring unit 80 of the power supply control unit 32 monitors the potential of the pulse transformer 20 instead of the suspended processor core 58 (S44). When the connection of the network 4 is resumed, the connection monitoring unit 80 of the power supply control unit 32 determines whether or not the detection signal of the comparator 52 is input (S45). When the network 4 is connected (S45) YES), the connection monitoring unit 80 becomes active, and power supply is resumed by switching the switch circuit 59 (S46).

  Such a configuration can also execute the power saving process.

As described above, the preferred embodiments and the like have been described for the electronic device of the present disclosure and the power supply control method thereof, but the present invention is not limited to the above description, and is described in the claims, or It goes without saying that various modifications and changes can be made by those skilled in the art based on the gist of the invention disclosed in the specification, and such modifications and changes are included in the scope of the present invention.

2 Electronic device 4 Network 6 External device 8 Communication cable 10 Control unit 12 Function control unit 14, 15, 16 Interface connector 20 Pulse transformer 21 Communication processing unit 22 PHY
24 LAN Controller 26 First Power Supply Unit 28 Second Power Supply Unit 30 Connection Monitoring Unit 32 Power Supply Control Unit 34 Memory Controller 36 Memory 40 Printer Device 42 Printer Control Unit 44 Printer Engine 50 MCU
52 Comparator 54 FET
58 Processor Core 59 Switch Circuit 60 Power Supply Generation Unit 62 VDDC
64 VDD
70 Primary winding 72 Secondary winding 74 Center tap 76 Center tap 80 Connection monitoring unit 140 Printer device 142 Printer control unit

Claims (6)

A communication processing unit for processing data to be transmitted / received via a network;
A connection monitoring unit for monitoring a transition of a connection state between the communication processing unit and the network from a potential fluctuation of communication noise generated by transmission / reception of the data;
A power supply unit for supplying power to the communication processing unit;
A power supply control unit that controls power supply to the communication processing unit according to a connection state between the communication processing unit and the network;
An electronic device comprising: When the connection between the communication processing unit and the network is released based on the monitoring result from the connection monitoring unit, the power supply control unit stops power supply to the communication processing unit, and the communication processing unit When connection with the network is resumed, power supply to the communication processing unit is resumed.
The electronic device according to claim 1. The connection monitoring unit detects the potential fluctuation from a center tap of a pulse transformer that performs signal conversion processing of the received data, and monitors the transition of the connection state with the network.
The electronic device according to claim 1 or 2. The communication processing unit includes at least a LAN controller and a PHY.
The electronic device according to claim 1, claim 2, or claim 3. The power supply unit supplies power to the communication processing unit that processes data sent and received via the network,
The connection monitoring unit monitors the transition of the connection state between the communication processing unit and the network from the potential fluctuation of communication noise generated by the transmission and reception of the data,
The power supply control unit controls power supply to the communication processing unit according to a connection state between the communication processing unit and the network.
Electronic device power control method. When the connection between the communication processing unit and the network is released based on the monitoring result from the connection monitoring unit, the power supply control unit stops power supply to the communication processing unit, and the communication processing unit When connection with the network is resumed, power supply to the communication processing unit is resumed.
The power control method for an electronic device according to claim 5.

Images