JP2005354491A - Multi-function terminal and its control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multi-function terminal lower in power consumption. <P>SOLUTION: The multi-function terminal has a radio communication control means for performing radio communication processing, a high-speed control means for realizing multi-function, an internal power supply means for supplying power in the multi-function terminal, an interface means for receiving power supply from the outside of the multi-function terminal, a power supply detection means for detecting that power is being supplied by the interface means, and a switching means for switching between the power from the internal power supply means and the power from the interface means and stops the power from the internal power supply means or the interface means to the high-speed control means in response to detecting communication with an extension radio terminal by the radio communication control means. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention has an interface connectable via a PC (Personal Computer) and a USB (Universal Serial Bus), and can realize a copy / scanner / fax function. The present invention relates to a multifunction terminal having an extension terminal and having a telephone function capable of making a call to a public line by the wireless extension terminal, and a control method thereof.

As a conventional image forming apparatus, during standby, the self-power supply is cut off by the power supply control means, and the minimum operation part is operated by power supply from the external power supply means, thereby realizing power saving. Is known (see, for example, Patent Document 1).
JP 2001-2111274 A

  However, in the conventional image forming apparatus, it is necessary to use a CPU using a high-speed clock in order to perform image processing and recording processing. When operating using a high-speed clock, a line using a handset There is a problem in that current consumption during normal processing such as a call becomes large.

  Further, in the above-described conventional example, the high-speed processing unit accesses the ROM and RAM using a bus when performing wireless communication, and thus generates a noise of a cordless frequency band, thereby causing a cordless sound quality deterioration. There is.

It is an object of the present invention to provide a multifunction terminal with lower power consumption.

The present invention provides a multi-function terminal having a plurality of operation modes and capable of accommodating a wireless extension wireless terminal, a radio communication control means for performing radio communication processing, a high-speed control means for realizing multi-function, Internal power supply means for supplying power in the multifunction terminal, interface means for receiving power supply from outside the multifunction terminal, and power supply detection means for detecting that power is supplied by the interface means And switching means for switching between the power from the internal power supply means and the power from the interface means, and when communication with the extension wireless terminal is detected by the wireless control means, Multi-fan that stops power from internal power supply means or interface means Deployment is a terminal.

According to the present invention, there is an effect that the power consumption of the multifunction terminal is further reduced.

  The best mode for carrying out the invention is the following examples.

  FIG. 1 is a block diagram showing a multifunction terminal 102 and its surroundings that are Embodiment 1 of the present invention.

  The multi-function terminal 102 has a telephone function and can communicate with the partner terminal 100 via a public line 101 such as an analog telephone line or ISDN.

  A PC (personal computer) 103 is connected to the multi-function terminal 102 via USB and IEEE1394, and can supply power.

  The wireless extension terminal 104 is wirelessly connected to the multi-function terminal 102 and can perform voice calls and data communication.

  FIG. 2 is a diagram illustrating an internal configuration of the multifunction terminal 102.

  The multi-function terminal 102 includes a wireless control unit 200, a high-speed control unit 201, a ROM 202, a RAM 203, a communication processing unit 204, an analog switch unit 205, a handset 206, a speaker 207, a sound source unit 208, a USBi / F209, switching unit 210, main body power supply 211, key input unit 212, hook detection unit 213, display unit 214, recording unit 215, reading unit 216, document detection unit 217, modem 218, Address and data bus 219, data signal line 220, radio section 221, and switch 222.

  The radio control unit 200 controls the communication processing unit 204, the switch unit 205, the sound source unit 208, and the radio unit 221, and controls a call with the counterpart terminal 100 using the housed extension radio terminal 104. Also, the power (Vcc) from the main unit power supply and the power (Vbus) signal from the PC are input to the port of the radio control unit 200, the state of the port is periodically detected, and the power Vcc from the main unit power supply is detected. It is checked whether it is operating or operating with the power Vbus from the PC, and the power supply to the high-speed control unit 201 is controlled. The wireless control unit 200 may be a one-chip microcomputer that has an internal ROM and RAM and is operable.

  The high-speed control unit 201 inputs signals to and from each unit via the data bus 219, and controls each component connected to the data bus 219 according to the input signal. That is, the high-speed control unit 201 controls display processing, copying, transmission / reception processing by a printer, and a modem according to a processing program stored in the ROM 202.

  The ROM 202 stores a program. The program monitors power supply control for controlling power supply from the PC 103, the key input unit 212 and the hook detection unit 213, detects a user request, and records a recording unit 215 or a reading unit. 216 is controlled, reading and recording operations for realizing copying and PC printing, and modem 218 are controlled to realize transmission and reception of mail by a data modem, FAX transmission and reception as a facsimile modem, display of a number display, and output of a voice synthesis signal. It is a program.

  The ROM 202 is configured by an E2PROM or a flash ROM capable of writing and erasing data.

  A RAM 203 is a memory used when the high-speed control unit 201 executes each process including reading and recording processes. Unlike the ROM 202, the RAM 203 stores temporary data. The RAM 203 is backed up by a battery or the like and stores the created character message, the received character message, the setting contents of various service functions, and the contents registered in the telephone directory. The RAM 203 may be configured by an E2PROM that is a nonvolatile memory.

  The communication processing unit 204 is an interface that accommodates the public line 101. When the public line 101 is an analog line, the communication processing unit 204 is connected to the telephone line of the central office switch and is configured by a full-wave rectifier circuit using a diode. The communication processing unit 204 includes a polarity matching circuit for matching the polarity of the line voltage, a ringer detection circuit that is connected to a subscriber line of the circuit exchange and detects a call signal from the office exchange, a handset 206 or When an off-hook operation is performed by pressing an off-hook key, a line loop is formed, and a relay circuit for sending a selection signal such as a dial pulse to the station, and a transformer circuit for performing 2-wire to 4-wire conversion, It is constituted by.

  In the first embodiment, an analog line is used. However, a digital line such as ISDN may be used.

  The analog switch unit 205 switches input / output of signals from the modem 218 and analog input / output signals such as the sound source unit 208, handset 206, and speaker 207 to the communication processing unit 204 under the control of the wireless control unit 200. The analog switch unit 205 has an attenuator inside and can convert the level of the analog signal.

  The handset 206 performs voice input / output. The speaker 207 outputs a ring tone and stored voice data, and monitors during FAX communication.

  The sound source unit 208 is a sound source of a holding tone or a ringing melody, stores sound source data therein, and outputs an analog signal under the control of the wireless control unit 200. It is also a sound source that outputs call progress stones such as DT, BT, RBT.

  The USBi / f 209 is connected to the PC 103 via a cable, receives power from the PC 103, and supplies power (Vbus) from the PC 103 to the switching unit 210. The USBi / f 209 includes a driver IC for performing data transmission / reception with the PC 103 and a transformer.

  The switching unit 210 switches between the power from the main body power supply 211 and the power from the USBi / f 209, and switches SW1 and SW2 that switch and supply the communication processing unit and the high-speed processing unit according to the power state. It is configured.

  The main body power supply 211 is configured by a switching power supply using AC or a battery using a secondary battery, and supplies power (Vcc) to the switching unit 210 and the power supply OFF block.

  The “power OFF block” includes a display unit 214, a recording unit 215, a reading unit 216, a document detection unit 217, and a modem 218.

  The key input unit 212 uses a dial number, URL, etc., 0-9, *, #, a dial key for inputting alphabets and symbols, etc. using the above keys, a transmission key for controlling facsimile transmission / reception, a reception key, Off-hook key to control line ON / OFF, answering machine key to set up answering machine, “good night key” to press when you do not want to ring incoming calls, function key to set function, pressing function key When the function selection mode is entered, the selection key such as a set key for selecting and setting is selected.

  The hook detection unit 213 particularly detects ON / OFF of the handset, controls line ON / OFF, detects a hook key, and detects an on-hook / off-hook state related to the start and disconnection of a call.

  The display unit 214 displays a time display, a line state during communication and a state such as an error. The display unit 214 is mainly composed of a liquid crystal or the like, and displays a character message input by the key input unit 212 or a received character message. In addition, the setting contents of various service functions of the telephone are also displayed. The display unit 214 includes a liquid crystal panel (TFT, DSTN) that performs display, a backlight that enables color display, and an inverter. When the key input or the like is not performed for a predetermined time due to the setting of the main control unit, the display unit 214 controls the inverter and the driver to stop the display.

  The recording unit 215 is a recording unit provided with known printing means such as a thermal type, thermal transfer type printer, laser beam printer, ink jet printer or the like, and decodes MH, MR, and MMR encoded digital data, and performs this decoding. The converted data is printed as print data.

  The reading unit 216 includes a known document reading unit such as a CCD or a contact sensor array. The reading unit 216 converts analog data read by the reading unit into digital data, and converts the converted digital data into digital data. , MH, MR, MMR and the like are encoded and output by a known encoding method.

  The document detection unit 217 detects the presence or absence of a transmission document on the reading unit 216 and notifies the high-speed control unit 201 of the detection result.

  The modem 218 is a digital signal processor and functionally realizes a data modem function for transmitting and receiving mail and a function of a facsimile modem for transmitting and receiving a facsimile by G3 FAX under the control of the high-speed control unit 201.

  The address and data bus 219 is used by the high-speed control unit 201 to set each unit.

  The data signal line 220 is a data signal line for exchanging commands for controlling various operations between the wireless control unit 200 and the high-speed control unit 201.

  The wireless unit 221 includes an antenna for performing wireless communication with an extension wireless terminal, an RF module, and a baseband IC that modulates and demodulates transmission / reception signals.

  The activation switch 222 is a switch that triggers power supply processing to the entire high-speed processing unit when the user requests it when power supply to the entire high-speed processing unit is stopped when the user requests it. .

  Next, an operation for switching between the power from the USBi / f 209 and the power from the main body power supply 211 will be described.

  FIG. 3 is a diagram illustrating an operation in which the switching unit 210 switches between the power from the USBi / f 209 and the power from the main body power supply 211.

[Switching unit configuration]
The switching unit 210 includes a changeover switch SW1 and a changeover switch SW2.

  The changeover switch SW1 is a relay that can operate using Vbus as a power source. The changeover switch SW2 is a relay that can operate using Vcom as a power source.

  The power switched between Vbus and Vcc by the changeover switch SW1 is Vcom, and this power Vcom is supplied to the entire communication processing unit. The power switched between Vbus and Vcc by the changeover switch SW2 is Vsel, and this power Vsel is supplied to the entire high-speed processing unit.

[Normal operation when the main unit is turned on and a PC is connected]
When the PC is not connected to the USBi / f 209, power is not supplied to the Vbus. Only Vcc from the main body power supply 211 is supplied to the switching unit 210.

  When Vbus is not supplied, the changeover switch SW1 uses Vbus as an operating power supply, so the switch is switched to the Vcom side.

[Power-saving operation when main unit power is ON and PC is not connected]
When the PC is not connected to the USBi / f 209, power is not supplied to the Vbus. In this state, when the wireless control unit 200 shifts to the power saving mode or performs a voice call using the extension wireless terminal, the wireless control unit 200 stops supplying the power Vsel to the high-speed communication processing unit.

  In order to stop the power to the high speed processing unit, the changeover switch SW2 stops the output to Vsel by setting the control signal lines Vcnt1 = 'H' and Vcnt3 = 'H'.

[Normal operation when the main unit is turned on and a PC is connected]
When a PC is connected to the USBi / f 209, power is supplied to Vbus. In this process, when the high speed control unit 201 detects the power Vbus from the USBi / f 209 and detects that the Vcc from the main body power supply 211 is also supplied, Vcnt1 = 'H' and Vcnt3 = 'L' are set. To do. By this processing, the changeover switch SW2 supplies Vcc to the high speed processing unit.

  Further, the power Vcc of the main body power supply 211 is supplied to the communication processing unit by setting Vcnt2 = 'H'.

[Power saving when the main unit is turned on and a PC is connected]
When a PC is connected to the USBi / f 209, Vbus power is supplied. In this state, when the wireless control unit 200 determines that the high-speed processing unit has shifted to the sleep state or that the extension wireless terminal has made a voice call with the counterpart terminal 100, the power Vsel to the high-speed processing unit is set. Perform processing to shut off.

  In this process, when the high speed control unit 201 detects the power Vbus from the USBi / f 209 and detects that the Vcc from the main body power supply 211 is also supplied, Vcnt1 = 'H' and Vcnt3 = 'H' are set. To do. By this process, the changeover switch SW2 stops supplying the power Vcc to the high speed processing unit.

  Further, the power Vbus from the USBi / f 209 is supplied to the communication processing unit by setting Vcnt2 = 'L'.

[Processing when AC is cut off when main unit power is ON and PC is connected]
When the PC is connected to the USBi / f 209, the Vbus power is supplied. In this state, when the wireless control unit 200 determines that the high-speed processing unit has shifted to the sleep state or when the extension wireless terminal determines that the voice call processing is performed with the counterpart terminal 100, the high-speed processing unit The process which interrupts | blocks the electric power Vsel to is performed.

  In this process, when the high speed control unit 201 detects the power Vbus from the USBi / f 209 and detects that the Vcc from the main body power supply 211 is also supplied, Vcnt1 = 'H' and Vcnt3 = 'H' are set. To do. By this process, the changeover switch SW2 stops supplying the power Vcc to the high speed processing unit.

  Further, the power Vbus from the USBi / f 209 is supplied to the communication processing unit by setting Vcnt2 = 'L'.

  After this processing, the wireless control unit 200 sets Vcnt2 = ‘L’ and stops output from the main body power supply 211 in order to shift to further power saving.

[Processing when power is turned on when the main unit is turned off and a PC is connected]
When a PC is connected to the USBi / f 209, Vbus power is supplied. In this state, when the wireless control unit 200 determines that the high-speed processing unit has shifted to the sleep state or determines that the extension wireless terminal performs voice call processing with the counterpart terminal 100, the wireless control unit 200 proceeds to the high-speed processing unit. The process which interrupts | blocks electric power Vsel of is performed.

  In this process, when the high-speed control unit 201 detects the power Vbus from the USBi / f 209 and detects that Vcc from the main body power supply 211 is not supplied, Vcnt1 = 'L' and Vcnt3 = 'L' are set. To do. With this process, the changeover switch SW2 stops supplying the power Vbus to the high-speed processing unit.

  Further, the power Vbus from the USBi / f 209 is supplied to the communication processing unit by setting Vcnt2 = 'L'.

  Next, the operation of the first embodiment will be described.

  FIG. 4 is a flowchart showing the operation of the high speed control unit 201 in the multifunction terminal 102.

  The high-speed control unit 201 periodically monitors a predetermined port, and checks whether the currently supplied power is supplied from the USB i / f 209. The wireless control unit 200 checks whether Vcc is supplied from the main body power supply 211 (S101). If no power is supplied from the main body power supply, it is confirmed that Vbus is supplied from the USBi / f 209 (S102).

  When the high speed control unit 201 detects that Vcc from the main body power supply 211 is not supplied (S102), the high speed control unit 201 determines that it is operating by Vbus from the USBi / f 209, and the host PC 103 via the USB i / f 209. Only blocks that can be enumerated. Further, a process for masking an interrupt or a detection signal from a block operating with a Vcc power supply is performed. In addition to masking the input signal, the analog signal from the reading unit 216 provided in the high-speed control unit 201 is converted to an A / D converter unit that performs analog / digital conversion, a PWM unit that controls the recording unit 215, and the like. The internal clock is stopped and initialization such as reset processing is performed (S103). The peripheral block is reset so as not to consume power.

  When the initialization process is completed, the system is operated with the minimum power supplied from the PC, and the PC 103 is requested for the power required for the radio control unit 200 (S104). To make a line call, a current of about 200 to 300 mA is sufficient to operate.

  When it is detected that the desired power supply is not permitted after the power request to the PC 103 (S105), the operation process with the minimum power is continued (S112), and it is monitored whether the processing time elapses (S113). When it is detected that the predetermined time has elapsed, the process of monitoring the bus power is started again.

  When the PC 103 detects that the high-speed control unit 201 is allowed to supply the desired power (S105), the high-speed control unit 201 determines that the desired power from the USB i / f 209 has been supplied. The control unit 200 is notified (S106). After this processing, the high-speed control unit 201 analyzes the signal sent from the wireless control unit 200 and checks whether high-speed processing such as high-speed copying or printing is started (S107).

  The high-speed control unit 201 also checks whether or not the wireless control unit 200 is requested to enter the sleep mode via the data signal line 220 (S108). If it is not required to enter the sleep mode, it is checked whether other processing is required (S107).

  When the high-speed control unit 201 detects that the wireless control unit 200 has requested to enter the sleep mode (S108), the high-speed control unit 201 backs up data to the RAM 203 or the like and places the periphery of the high-speed control unit 201 in the sleep state. The process of shifting to (S109). When the transition to sleep is completed (S110), the high speed control unit 201 notifies the radio control unit 200 that the entire high speed control unit 201 is in sleep (S111).

  FIG. 5 is a flowchart illustrating an operation when power is not supplied from the main body power supply 211 of the wireless control unit 200 in the multifunction terminal 102.

  When activated, the wireless control unit 200 first detects its own port and determines whether it is operating with Vcc from the main body power supply 211 and whether it is operating with Vbus from the USBi / f 209 (S201). ).

  If it is determined that power is not supplied from the main body power supply 211 (S201), only the block capable of performing the initialization operation with the high-speed control unit 201 is operable, and the operations of other internal blocks and peripheral blocks are performed. Stop (S202). This process reduces the power consumption after the power is turned on, and enables operation with power from the USB.

  During this processing, when the wireless control unit 200 receives a notification from the high-speed control unit 201 through the USBi / f 209 that an operable current can be supplied (S203), the entire communication processing unit can be operated. The state is initialized (S204). Thereafter, communication-related communication processing is performed (S205).

  After shifting to the normal process, it is monitored whether a predetermined time has passed (S206). If the predetermined time has not elapsed, it is monitored by the notification from the communication processing unit 204 or the wireless unit 221 whether or not the extension wireless terminal has made or received a call (S214). When the wireless control unit 200 detects that an outgoing / incoming call has been made from the extension wireless terminal (S214), the wireless control unit 200 starts a process of stopping power to the entire high-speed control unit (S207).

  When a predetermined time elapses during normal operation (S206), the wireless control unit 200 starts a process of stopping the supply of power to the entire high-speed processing unit (S207). This process controls the port signal (Vcnt1) of the wireless control unit 200 and stops the transmission of the primary FET of the main body power supply 211. By stopping the operation of the photocoupler that controls the primary-secondary transmission, it is possible to stop the supply of power from the main body power supply 211.

  The wireless control unit 200 detects the state of its own port, confirms that Vcc is no longer supplied (S208), and performs communication processing using the power (Vbus) from the USBi / f 209 (S209).

  During this processing, when the wireless control unit 200 detects that the key input unit 212 has requested processing such as copying or faxing (S210), the port signal (Vcnt1) is controlled to control the photocoupler of the main body power supply 211. And power is supplied from the main body power supply 211 (S211). After this processing is completed, high-speed processing such as copying and FAX communication is started (S212).

  FIG. 6 is a flowchart illustrating an operation when there is power from the main body power supply 211 of the communication control unit in the multifunction terminal 102 according to the first embodiment.

  When the wireless control unit 200 monitors its own port and detects that power from the main body power supply is supplied (S301), it confirms that the power from the USBi / f 209 is also supplied at the same time.

  At the start of this process, the communication processing unit operates based on the power supply from the main body power supply 211.

  When the wireless control unit 200 detects that power is supplied from the USBi / f 209, the wireless control unit 200 monitors whether a predetermined time has elapsed (S302). When it is detected that the predetermined time has elapsed, a signal requesting to enter the sleep state is output to the high speed control unit 201 (S304). If the predetermined time has not elapsed, the wireless control unit 200 monitors whether an outgoing / incoming call using the extension wireless terminal has been performed based on a notification from the communication processing unit 204 or the wireless unit 221 (S303).

  If no outgoing / incoming call is detected, it is monitored again whether a predetermined time has passed (S302). When it is detected that an outgoing / incoming call has been made using the extension wireless terminal 104, the wireless control unit 200 outputs a signal requesting to enter a sleep state to the high-speed control unit 201 (S304).

  After this processing, when the high-speed control unit 201 is notified via the data signal line 220 that the sleep state has been entered (S305), Vcc from the main body power supply 211 supplied to the high-speed processing unit is cut off. Processing is executed (S306). This process is a process for controlling the switching unit 210 and stopping the output of the power Vsel to the high-speed processing unit.

  The wireless control unit 200 operates based on the power supply from the USBi / f 209, and controls the switching unit 210 so as to supply the power from the USBi / f 209 instead of the power from the main body power supply 211. (S307). The wireless control unit 200 detects the state of the port and detects that Vbus is supplied to the wireless control unit 200 (S308).

  After this processing, the high-speed control unit 201 stops the output of the main body power supply 211 by controlling the control line Vcnt1 and stopping the control of the photocoupler of the main body power supply 211 (S309). When the wireless control unit 200 detects that the output of the main body power supply 211 has been stopped by monitoring its own port (S310), it detects whether there is a request from the changeover switch unit 222 that requires high-speed processing. To do.

  When it is detected by monitoring its own port that it is not receiving power from the USB i / f 209 when receiving power from the main body power supply 211 (S301), whether a predetermined time has passed after the detection. Whether or not is monitored (S311).

  If the predetermined time has not elapsed, the wireless control unit 200 monitors whether the outgoing / incoming call using the extension wireless terminal is performed based on the notification from the communication processing unit 204 or the wireless unit 221 (S312).

  If no outgoing / incoming call is detected, it is monitored again whether a predetermined time has passed (S311). When it is detected that an outgoing / incoming call has been made using the extension wireless terminal 104, the wireless control unit 200 outputs a signal requesting to enter a sleep state to the high-speed control unit 201 (S313).

  When the predetermined time has elapsed, the wireless control unit 200 notifies the high-speed control unit 201 of a request to shift to the sleep state using the data signal line 220 (S313).

  After receiving this notification from the high-speed control unit 201 (S314), the switching unit 210 is controlled to stop supplying the power Vsel to the high-speed processing unit (S315). ). If the supply of power to the high-speed processing unit is stopped after this processing, only the communication processing unit shifts to a mode in which the main body power supply 211 operates (S316). Thereafter, when a high-speed operation process such as copying or FAX is requested from the changeover switch unit 222 (S317), the process of controlling the switching unit 210 and supplying the power Vsel from the main body power supply 211 again is performed at high speed. (S318).

  In the first embodiment, the communication processing unit 204 is an analog line. However, a network controller or ADSL that enables Internet connection by ISDN DSU (Digital Service Unit) or VOIP may be used in the first embodiment. .

According to the above embodiment, the power consumption of the multifunction terminal is further reduced. Further, according to the above embodiment, since the bus access of the high-speed processing unit is stopped during wireless communication, it is possible to provide a multi-function terminal with reduced radio noise and good call quality.

  FIG. 7 is a diagram showing a multifunction terminal 402 that is Embodiment 2 of the present invention and its surroundings.

  The partner terminal 400 is a partner terminal that can communicate with the multifunction terminal 402. The public line 401 is an analog telephone line or a public line such as ISDN. The multi-function terminal 402 is a multi-function terminal 402 that has a telephone function and can communicate with a partner terminal via a public line 401. A PC (personal computer) 403 is connected to the multi-function terminal 402 via USB or IEEE1394, and can supply power.

  FIG. 8 is a diagram showing an internal configuration of the multifunction terminal 402.

  The multifunction terminal 402 includes a communication control unit 500, a high-speed control unit 501, a ROM 502, a RAM 503, a communication processing unit 504, an analog switch unit 505, a handset 506, a speaker 507, a sound source unit 508, and a USBi. / F509, switching unit 510, main body power supply 511, key input unit 512, hook detection unit 513, display unit 514, recording unit 515, reading unit 516, document detection unit 517, modem 518, Address and data bus 519 and data signal line 520.

  The communication control unit 500 controls the communication processing unit 504, the switch unit 505, the key input unit 512, and the hook detection unit 513, and controls a call with the counterpart terminal 400 using the handset 506. Also, the power (Vcc) from the main unit power supply and the power (Vbus) signal from the PC 403 are input to the port of the communication control unit 500, the state of the port is periodically detected, and the power Vcc from the main unit power supply is used. It confirms whether it is operating or operating with the power Vbus from the PC, and controls the supply of power to the high-speed control unit 501. The communication control unit 500 may be a one-chip microcomputer that has an internal ROM and RAM and is operable.

  The high-speed control unit 501 inputs a signal to and from each unit via the data bus 519, and controls each component connected to the data bus 519 in accordance with the input signal. That is, the high-speed control unit 501 controls transmission / reception processing by a copy, a printer, and a modem according to a processing program stored in the ROM 502.

  The ROM 502 controls power supply for controlling power supply from the PC 403, controls the recording unit 515 and the reading unit 516, reads and records operations for realizing copying and PC printing, and controls the modem 518 to send mail by a data modem. Stores programs for realizing transmission / reception, FAX transmission / reception as a facsimile modem, display of a number display, and output of a voice synthesis signal. The ROM 502 is composed of an E2PROM or a flash ROM capable of writing and erasing data.

  The RAM 503 is a memory used when the high-speed control unit 501 executes each process including reading and recording processes. Unlike ROM 502, temporary data is stored here. The RAM 503 is backed up by a battery or the like, and stores the created character message, the received character message, the setting contents of various service functions, and the contents registered in the phone book. Further, the RAM 503 may be configured by E2PROM or the like which is a nonvolatile memory.

  The communication processing unit 504 is an interface that accommodates the public line 401. In the case of an analog line, the communication processing unit 504 is connected to the telephone line of the central office switch, is configured by a full-wave rectifier circuit using a diode, and matches the polarity of the line voltage. When a ringer detection circuit connected to a subscriber line of a circuit exchange and detecting a ringing signal from the office exchange, an off-hook operation by pressing the handset 506 or an off-hook key is performed, a line loop is formed and A relay circuit for sending a selection signal such as a dial pulse, and a transformer circuit for performing 2-wire-to-wire conversion.

  In the second embodiment, an analog line is used. However, a digital line such as ISDN may be used.

  The analog switch unit 505 switches input / output of signals from the modem 518 and analog input / output signals such as the sound source unit 508, the handset 506, and the speaker 507 to the communication processing unit 504 under the control of the communication control unit 500. The internal attenuator can be used to convert the analog signal level.

  The handset 506 performs voice input / output. The speaker 507 outputs a ring tone or stored voice data and monitors during FAX communication.

  The sound source unit 508 is a sound source of a holding tone or a ringing melody, stores sound source data therein, and outputs an analog signal under the control of the communication control unit 500. It is also a sound source for outputting call progress stones such as DT, BT, RBT.

  The USBi / f 509 is connected to the PC 403 by a cable, receives power from the PC 403, and supplies power (Vbus) from the PC 403 to the switching unit 510. A driver IC and a transformer are provided in preparation for data transmission / reception with the PC 403.

  The switching unit 510 is configured by a switch SW11 and a switch SW12 that switch between the power from the main body power supply 511 and the power from the USBi / f 509 and switch the power supply to the communication processing unit and the high-speed processing unit depending on the power state. ing.

  The main body power supply 511 is configured by a switching power supply using AC or a battery using a secondary battery, and supplies power (Vcc) to the switching unit 510 and the power supply OFF block. As the “power OFF block”, a display unit 514, a recording unit 515, a reading unit 516, a document detection unit 517, and a modem 518 can be considered.

  The key input unit 512 uses a dial number, URL, etc., 0-9, *, #, dial keys for inputting alphabets and symbols, etc., transmission keys for controlling facsimile transmission / reception, reception keys, lines By pressing an off-hook key to control ON / OFF, an answering machine key to set up an answering machine, a “good night key” to be pressed when an incoming call is not desired, a function key for setting a function, or a function key When entering the function selection mode, it is composed of selection keys such as a set key for selecting and setting.

  The hook detection unit 513 particularly detects ON / OFF of the handset and controls line ON / OFF. Also, a hook key is detected to detect an on-hook / off-hook state related to the start or disconnection of a call.

  The display unit 514 displays a time display, a line status during communication, a status such as an error, and the like, and is mainly composed of a liquid crystal or the like. The display unit 514 also displays a character message key-input by the key input unit 512 and a received character message. Furthermore, the setting contents of various service functions of the telephone are also displayed.

  The internal structure of the display unit 514 includes a liquid crystal panel (TFT, DSTN) to be displayed, a backlight that enables color display, and an inverter. When the key input or the like is not performed for a predetermined time due to the setting of the main control unit, the display unit 514 controls the inverter and the driver and stops the display.

  The recording unit 515 is a recording unit provided with known printing means such as a thermal type, thermal transfer type printer, laser beam printer, ink jet printer or the like, and decodes MH, MR, and MMR encoded digital data, and performs this decoding. The converted data is printed as print data.

  The reading unit 516 includes known document reading means such as a CCD or a contact sensor array, converts analog data read by the reading means into digital data, and converts the converted digital data into MH, MR. , Encoded by a known encoding method such as MMR, and output.

  The document detection unit 517 detects the presence of a transmission document on the reading unit 516 and notifies the high-speed control unit 501 of the detection result.

  The modem 518 is a digital signal processor and functionally implements a data modem function for sending and receiving mail and a facsimile modem function for sending and receiving a facsimile by G3 FAX under the control of the micro high-speed control unit 501.

  The address and data bus 519 is used by the high-speed control unit 501 to set each unit.

  The data signal line 520 exchanges commands for controlling various operations between the communication control unit 500 and the high-speed control unit 501.

  Next, an operation for switching the power from the USBi / f 509 and the main body power supply 511 will be described.

[Switching unit configuration]
FIG. 9 is a diagram showing the switching unit 510 in the multifunction terminal 402.

  The switching unit 510 includes a changeover switch SW11 and a changeover switch SW12.

  The power switched between Vbus and Vcc by the changeover switch SW11 is Vcom, which supplies power to the entire communication processing unit. The electric power switched between Vbus and Vcc by the changeover switch SW12 is Vsel, and the electric power is supplied to the entire high-speed processing unit.

  The changeover switch SW11 is a relay that can operate using Vbus as a power source. The changeover switch SW12 is a relay that can operate using Vcom as a power source.

[Normal operation when main unit power is ON and PC403 is not connected]
When the PC 403 is not connected to the USBi / f 509, power is not supplied to the Vbus, and only Vcc from the main body power supply 511 is supplied to the switching unit 510.

  When Vbus is not supplied, the changeover switch SW11 uses Vbus as the operating power supply, so that the switch is switched to the Vcom side.

[Power-saving operation when main unit power is ON and PC403 is not connected]
When the PC 403 is not connected to the USBi / f 509, power supply to the Vbus is not performed. In this state, when the communication control unit 500 shifts to the power saving mode, the communication control unit 500 performs high-speed communication. Processing to stop the power Vsel to the processing unit is performed.

  In order to stop the power to the high speed processing unit, the control signal line Vcnt1 = 'H' and Vcnt3 = 'H' are set, and the changeover switch SW12 stops the output to Vsel.

[Normal operation when main unit power is ON and PC403 is connected]
When the PC 403 is connected to the USBi / f 509, power is supplied to the Vbus. In this process, when the communication control unit 500 detects the power Vbus from the USBi / f 509 and detects that the Vcc from the main body power supply 511 is also supplied, Vcnt1 = 'H' and Vcnt3 = 'L' are set. To do. By this processing, the changeover switch SW12 supplies Vcc to the high speed processing unit.

  Further, the power Vcc of the main body power supply 511 is supplied to the communication processing unit by setting Vcnt2 = 'H'.

[Power saving when main unit power is ON and PC403 is connected]
When the PC 403 is connected to the USBi / f 509, Vbus power is supplied. In this state, when the communication control unit 500 determines that the high-speed processing unit has shifted to the sleep state, the communication control unit 500 performs a process of cutting off the power Vsel to the high-speed processing unit.

  In this process, when the communication control unit 500 detects the power Vbus from the USBi / f 509 and detects that the Vcc from the main body power supply 511 is also supplied, Vcnt1 = 'H' and Vcnt3 = 'H' are set. To do. As a result, the changeover switch SW12 stops supplying the power Vcc to the high-speed processing unit.

  Also, the power Vbus from the USBi / f 509 is supplied to the communication processing unit by setting Vcnt2 = 'L'.

[Processing when AC is cut off when main unit power is ON and PC403 is connected]
When the PC 403 is connected to the USBi / f 509, Vbus power is supplied. In this state, when the communication control unit 500 determines that the high speed processing unit has shifted to the sleep state, the communication control unit 500 cuts off the power Vsel to the high speed processing unit.

  In this process, when the communication control unit 500 detects the power Vbus from the USBi / f 509 and detects that Vcc is also supplied from the main body power supply 511, Vcnt1 = 'H' and Vcnt3 = 'H' are set. . As a result, the changeover switch SW12 stops supplying the power Vcc to the high-speed processing unit.

  Further, the power Vbus is supplied from the USBi / f 509 by setting Vcnt2 = 'L' to the communication processing unit.

  After this processing, the communication control unit 500 sets Vcnt2 = ‘L’ and stops output from the main body power supply 511 in order to further shift to power saving.

[Processing at power-on when main unit power is off and PC 403 is connected]
When the PC 403 is connected to the USBi / f 509, Vbus power is supplied. In this state, when the communication control unit 500 determines that the high-speed processing unit has shifted to the sleep state, the communication control unit 500 performs a process of cutting off the power Vsel to the high-speed processing unit.

  In this process, when the communication control unit 500 detects the power Vbus from the USBi / f 509 and detects that the Vcc from the main body power supply 511 is not supplied, Vcnt1 = 'L' and Vcnt3 = 'L' are set. To do. With this process, the changeover switch SW12 stops supplying the power Vbus to the high-speed processing unit.

  Further, the power Vbus from the USBi / f 509 is supplied to the communication processing unit by setting Vcnt2 = 'L'.

  Next, the operation of the second embodiment will be described.

  FIG. 10 is a flowchart illustrating the operation of the high-speed controller 501 in the multifunction terminal 402 according to the second embodiment.

  The high-speed control unit 501 periodically monitors a predetermined port and detects whether or not the currently supplied power is the power supplied from the USB i / f 509. The communication control unit 500 detects whether Vcc from the main body power supply 511 is supplied (S401). If no power is supplied from the main body power supply, it is confirmed that Vbus is supplied from the USBi / f 509 (S402).

  When the high-speed control unit 501 detects that Vcc is not supplied from the main body power supply 511 (S402), the high-speed control unit 501 determines that it is operating with Vbus from the USBi / f 509, and communicates with the host PC 403 via the USB i / f 509. Operate only blocks that can be enumerated.

  Further, an interrupt or a detection signal from a block operating with the Vcc power supply is masked. In addition to masking the input signal, the circuit provided in the high-speed control unit 501, that is, the A / D converter unit that performs analog / digital conversion of the analog signal from the reading unit 516, and the recording unit 515 are controlled. The internal clock is stopped and the reset process is initialized to the PWM unit or the like (S403). Reset processing is performed on the peripheral blocks so as not to consume power.

  When the initialization process is completed, the system is operated with the minimum power supplied from the PC 403, and a process of requesting the PC 403 for the power required for the communication control unit 500 is performed (S404). To make a line call, a current of about 200 to 300 mA is sufficient to operate.

  If it is detected that the desired power supply is not permitted after the power request to the PC 403 (S405), the operation process with the minimum power is continued (S412), and it is monitored whether the processing time has passed (S413). When it is detected that the predetermined time has elapsed, the processing for monitoring the bus power is started again.

  When the PC 403 detects that the high-speed control unit 501 is allowed to supply the desired power (S405), the high-speed control unit 501 indicates that the desired power from the USBi / f 509 has been supplied. The communication control unit 500 is notified (S406). After this processing, the high-speed control unit 501 analyzes the signal sent from the communication control unit 500, and detects that high-speed processing such as high-speed copying or printing has started (S407).

  The high-speed control unit 501 detects that the communication control unit 500 requests to enter the sleep mode via the data signal line 520 (S408). If it is not required to enter the sleep mode, it is detected that another process is requested (S407).

  When the high-speed control unit 501 detects that the communication control unit 500 requests to enter the sleep mode (S408), the high-speed control unit 501 backs up data to the RAM 503 or the like and places the periphery of the high-speed control unit 501 in the sleep state. The process of shifting to (S409). When the transition to sleep is completed (S410), the high speed control unit 501 notifies the communication control unit 500 that the entire high speed control unit 501 has gone to sleep (S411).

  FIG. 11 is a flowchart illustrating the operation of the multifunction terminal 402 according to the second embodiment when no power is supplied from the main body power supply 511 of the communication control unit 500.

  When the communication control unit 500 is activated, it first detects its own port and determines whether it is operating with Vcc from the main power supply 511 or Vbus from the USBi / f 509 (S501).

  When it is determined that there is no power supply from the main body power supply 511 (S501), only the blocks that can perform the initialization operation with the high-speed control unit 501 are operable, and the operations of other internal blocks and peripheral blocks are stopped. (S502). With this process, power consumption after power-on is reduced, and operation with power from the USB becomes possible.

  During this process, if the high-speed control unit 501 receives a notification that the communication control unit 500 can supply an operable current via the USBi / f 509 (S503), the entire communication processing unit is put into an operable state. Initialization is performed (S504). Thereafter, communication-related communication processing is performed (S505). When a predetermined time elapses after shifting to the normal processing (S506), the communication control unit 500 starts a process of stopping the supply of power to the entire high-speed processing unit (S507). This process controls the port signal (Vcnt1) of the communication control unit 500 and stops the transmission of the primary FET of the main body power supply 511. When this control is performed, the power supply from the main power supply 511 can be stopped by stopping the operation of the photocoupler that controls the primary-secondary transmission.

  The communication control unit 500 detects the state of its own port, confirms that Vcc is not supplied (S508), and performs communication processing using the power (Vbus) from the USBi / f 509 (S509).

  When the communication control unit 500 detects from the key input unit 512 that processing such as copying or faxing has been requested during this processing (S510), it controls the port signal (Vcnt1) and is provided in the main unit power supply 511. The photocoupler is made operable and power is supplied from the main body power supply 511 (S511). After this processing is completed, high-speed processing such as copying and FAX communication is started (S512).

  FIG. 12 is a flowchart illustrating an operation when receiving power from the main body power supply 511 of the communication control unit in the multifunction terminal 402 according to the second embodiment.

  When the communication control unit 500 monitors its own port and detects that the power from the main body power supply is supplied (S601), it checks whether the power from the USBi / f 509 is also supplied at the same time.

  At the start of this processing, the communication processing unit operates based on power supply from the main body power supply 511.

  When the communication control unit 500 detects that power is being supplied from the USBi / f 509, the communication control unit 500 outputs a signal requesting to enter the sleep state to the high speed control unit 501 (S602). ). After this processing, when the sleep state is notified from the high-speed control unit 501 via the data signal line 520 (S604), Vcc from the main body power supply 511 supplied to the high-speed processing unit is cut off. Processing is performed (S604). This process is a process for controlling the switching unit 510 to stop the output of the power Vsel to the high-speed processing unit.

  Further, the communication control unit 500 operates based on the power supply from the USB i / f 509, and controls the switching unit 510 to supply the power from the USB i / f 509 instead of the power from the main body power supply 511. (S605).

  The communication control unit 500 detects the state of the port, and detects that Vbus is supplied to the communication control unit 500 (S606).

  After this processing, the communication control unit 500 controls the control line Vcnt1, and stops the output of the main body power supply 511 by stopping the control of the photocoupler of the main body power supply section 511 (S607). When the communication control unit 500 detects that the output of the main body power supply 511 has stopped by monitoring its own port, it detects whether there is a request from the key input unit 512 that requires high-speed processing.

  When it is detected by monitoring its own port that it is not receiving power from the USB i / f 509 when receiving power from the main body power supply 511 (S601), whether or not a predetermined time has passed since the detection Is monitored (S609). When the predetermined time has elapsed, the communication control unit 500 notifies the high-speed processing unit 501 of a request to shift to the sleep state using the data signal line 520 (S610).

  After receiving this notification from the high-speed control unit 501 (S611), the switching unit 510 is controlled to stop supplying the power Vsel to the high-speed processing unit (S612). .

  If the power supply to the high-speed processing unit is stopped after this processing, only the communication processing unit shifts to a mode in which the main body power supply 511 is operated (S613). Thereafter, when high-speed operation processing such as copying or FAX is requested by the key input unit 512 or the like (S614), the switching unit 510 is controlled, and the power Vsel from the main body power supply 511 is supplied again to the high-speed control unit. Is performed (S615).

In the second embodiment, an analog line is connected to the communication processing unit 504, but instead of doing this, a network controller or ADSL that enables Internet connection using ISDN DSU (Digital Service Unit), VOIP, The communication processing unit 504 may be connected.

It is a block diagram which shows the multifunction terminal 102 which is Example 1 of this invention, and its periphery. 2 is a diagram illustrating an internal configuration of a multifunction terminal 102. FIG. It is a figure which shows the operation | movement which the switching part 210 switches the electric power from USBi / f209 and the electric power from the main body power supply 211. FIG. 5 is a flowchart showing the operation of the high-speed control unit 201 in the multifunction terminal 102. 7 is a flowchart illustrating an operation when power is not supplied from the main body power supply 211 of the wireless control unit 200 in the multifunction terminal 102. 5 is a flowchart illustrating an operation when there is power from a main body power supply 211 of the communication control unit in the multifunction terminal 102 according to the first embodiment. It is a figure which shows the multifunction terminal 402 which is Example 2 of this invention, and its periphery. 2 is a diagram showing an internal configuration of a multifunction terminal 402. FIG. It is a figure which shows the switch part 510 in the multifunction terminal 402. FIG. 10 is a flowchart illustrating an operation of a high-speed control unit 501 in the multifunction terminal 402 according to the second embodiment. 6 is a flowchart illustrating an operation when power is not supplied from the main body power supply 511 of the communication control unit 500 in the multifunction terminal 402 according to the second embodiment. 10 is a flowchart illustrating an operation when receiving power from a main body power supply 511 of a communication control unit in the multifunction terminal 402 according to the second embodiment.

Explanation of symbols

100, 400 ... partner terminal,
102, 402 ... multifunction terminal,
103, 403 ... PC,
104 ... extension wireless terminal,
200 ... wireless control unit 500 ... communication control unit,
201, 501, high-speed control unit,
209, 509 ... USBi / f,
210, 510 ... switching unit,
211, 511 ... AC power source (main body power source),
SW1, SW2, SW11, SW12 ... switches.

Claims (16)

In a multi-function terminal equipped with a plurality of operation modes and capable of accommodating an extension wireless terminal using radio,
Wireless communication control means for performing wireless communication processing;
Control means for realizing the multi-function;
Internal power supply means for supplying power in the multifunction terminal;
Interface means for receiving power supply from outside the multi-function terminal;
Power supply detection means for detecting that power is supplied by the interface means;
Switching means for switching between power from the internal power supply means and power from the interface means;
A multifunction terminal characterized in that when the communication with the extension wireless terminal is detected by the wireless control means, the power from the internal power supply means or the interface means to the control means is stopped. In claim 1,
The wireless communication control means determines that the high-speed control means has switched to the sleep mode after detecting that power is not supplied from the internal power supply means but is supplied with power from the interface means. Then, the multifunction terminal is a means for stopping the supply of power to the high-speed control unit controlled by the high-speed control means. In claim 2,
The wireless control means detects that the power from the internal power supply means and the power from the interface means are being received, and then stops the power to the high-speed control unit, and then supplies the internal power supply. A multi-function terminal, characterized in that it is means for stopping the output of the means. In claim 3,
The wireless control means is means for stopping power to the high-speed control unit after detecting that power is received from a main body power supply but not supplied with power from the interface means. Multifunction terminal. In a multifunction terminal having a plurality of operation modes,
Communication control means for performing call processing;
Control means for realizing the multi-function;
Internal power supply means for supplying power in the multifunction terminal;
Interface means for receiving power supply from outside the multi-function terminal;
Power supply detection means for detecting that power is supplied via the interface means;
Switching means for switching between power from the internal power supply means and power from the interface means;
And the communication control means is a means for setting the control means to a sleep mode when it is determined that the control means can receive the supply of power from the interface means. . In claim 5,
The communication control means determines that the control means has switched to the sleep mode after detecting that the power is not supplied from the internal power supply means and is supplied with power from the interface means. A multifunction terminal characterized in that it is means for stopping the supply of electric power to the control unit controlled by the control means. In claim 6,
The communication control means detects that the power from the internal power supply means and the power from the interface means are received, and then stops the power to the control unit, and then supplies the internal power supply. A multi-function terminal, characterized in that it is means for stopping the output of the means. In claim 7,
The communication control means is means for receiving power from the internal power supply means and stopping power to the control unit after detecting that power is not supplied from the interface means. Multifunction terminal to do. A multi-function terminal that has a plurality of operation modes and can accommodate a wireless communication unit, an interface unit that receives power supply from outside the multi-function terminal, and an internal power supply that supplies power in the multi-function terminal In a control method of a multi-function terminal comprising a switching unit that switches between the power from the power supply unit and the internal power supply unit, and the power from the interface unit, and a control unit that realizes multi-function,
A wireless communication control process for performing wireless communication processing;
A power supply detection step of detecting that power is supplied by the interface unit;
A power control step of stopping power from the internal power supply unit or the interface unit to the control unit when communication with the wireless communication unit is detected by the radio control step;
A method for controlling a multifunction terminal, comprising: In claim 9,
In the wireless communication control step, it is determined that the control unit has switched to the sleep mode after detecting that there is no power supply from the internal power supply unit but is receiving power supply from the interface unit. And a method of controlling the multifunction terminal, wherein the power supply to the controller is stopped. In claim 10,
After the wireless control step detects that the power from the internal power supply unit and the power from the interface unit are received, the power to the control unit is stopped, and then the internal power supply unit A method for controlling a multifunction terminal, characterized in that the output is stopped. In claim 11,
The wireless control step is a step of stopping power to the control unit after detecting that power is received from the internal power supply unit but not being supplied from the interface unit. A control method of a multi-function terminal characterized. A multi-function terminal that has a plurality of operation modes and can accommodate a communication control unit that performs call processing. An interface unit that receives power supply from outside the multi-function terminal and power in the multi-function terminal In a control method for a multi-function terminal comprising: an internal power supply unit that performs switching between power from the internal power supply unit and power from the interface unit; and a control unit that realizes multi-function. In a multifunction terminal having an operation mode,
A power supply detection step of detecting that power is supplied via the interface unit;
A switching step of switching between power from the internal power supply unit and power from the interface unit;
And the communication control step is a step of setting the control unit to a sleep mode when it is determined that the control unit can receive power from the interface unit. Control method. In claim 13,
When the communication control step detects that the power is not supplied from the internal power supply unit and receives the power supply from the interface unit, and then determines that the control unit has switched to the sleep mode. A method for controlling a multifunction terminal, characterized in that it is a step of stopping the supply of power to the control unit. In claim 14,
The communication control step detects the supply of power from the internal power supply unit and the power from the interface unit, and then stops power supply to the control unit and then supplies the internal power supply. A method for controlling a multifunction terminal, characterized by being a step of stopping output of a unit. In claim 15,
The communication control step is a step of receiving power from the internal power supply unit and stopping power to the control unit after detecting that power is not received from the interface unit. To control the multifunction terminal.

Images