JP2004130525A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an image forming apparatus in which a status inquired from a network is replied with energy as low as possible and at a low cost even if the image forming apparatus is in sleep state. <P>SOLUTION: A DCON 201 and a controller 202 are connected through a microcomputer Q301, a parallel/serial converting section Q302, a serial/parallel converting section Q303 and signal switching circuits Q304, Q305, Q306 and Q308. A status group detected by sensor groups 208 and 209 is communicated when the image forming apparatus is operating in low power consumption mode, otherwise a command is communicated in addition to the status group detected by the sensor groups 208 and 209. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image forming apparatus having a low power consumption mode that consumes less power than a normal standby mode.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is a system in which a printer (including a copying machine and a multifunction peripheral) and a computer are connected to a network.
[0003]
FIG. 24 is a block diagram illustrating an example of a network system including a conventional image forming apparatus, and corresponds to, for example, a configuration example of a network system used by a plurality of users in a network environment.
[0004]
In FIG. 24, the network system has a configuration in which a plurality of personal computers (PC 1103a, PC 1103b), a copying machine 1101a, a copying machine 1101b, and a server 1102 are connected to a network. The copying machine (both the copying machine 1101a and the copying machine 1101b) includes a printer unit 1201, a reader unit 1216, a controller unit 1202, and a DC power supply 1203. The controller unit 1202 exchanges data with the outside via a network, controls ON / OFF of the DC power supply 1203, and controls the reader unit 1216 and the printer unit 1201.
[0005]
Normally, the copying machine shifts to a sleep mode (an energy saving mode or a low power consumption mode) in order to save energy when a copying operation and a printing operation are not performed for a predetermined time.
[0006]
Also, application software for managing a network is known. This is software that can be installed on a PC to know the status of a copier connected to a network. For example, when a paper out condition occurs, the status of the copying machine can be displayed on the PC. Even when the copiers 1101a and 1101b are in the sleep state, when a print request is received from the PC 1103a or 1103b connected to the network, this is detected and the DC power supply 1203 of the copier is activated to start the entire copier. Perform wake-up print output.
[0007]
[Problems to be solved by the invention]
However, the above-described related art has the following problems.
[0008]
When an image forming apparatus connected to a network, for example, a copying machine is in a sleep state, and a PC inquires about the latest status such that the copying machine is updated at any time, the controller unit 1202 inside the copying machine supplies a DC power supply. 1201 was started, power was supplied to all inside the engine, communication was performed with the reader unit 1216 and the printer unit 1201 to detect the status of the heard status, and the result was returned to the network. .
[0009]
Therefore, it is necessary to supply power to the entire copying machine or to keep the power on at all times whenever the status of the copying machine is heard, even though the energy saving state of the sleep state is achieved. This is in conflict with recent energy conservation.
[0010]
SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and an object of the present invention is to provide a response to a heard status even when an image forming apparatus such as a copying machine or a digital multifunction peripheral is in a sleep state. Another object of the present invention is to provide a mechanism that can be realized with as little energy as possible and at low cost.
[0011]
[Means for Solving the Problems]
According to a first aspect of the present invention, in an image forming apparatus having a low power consumption mode that consumes less power than in a normal standby mode, an image forming unit (a printer unit (not shown)) that performs an image forming process based on input image data A plurality of detection means (switches SW501 to SW505 shown in FIG. 5 and sensors Q607 to Q615 shown in FIG. 6) for detecting a status group of the image forming means; and a plurality of detection means connected to the plurality of detection means. An image forming control unit (DCON 201 shown in FIG. 3) for performing control, a main control unit (controller 202 shown in FIG. 3) for performing main control of the image forming apparatus, and the main control unit and the image forming control unit. Interface means (microcomputer Q301, parallel-serial conversion unit Q302, serial-parallel conversion unit Q3 shown in FIG. 3) 3, the signal switching circuits Q304, Q305, Q306, Q308), and the interface means communicates a status group detected by the plurality of detection means in the low power consumption mode, At times other than time, a command is communicated in addition to the status group detected by the plurality of detection means.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
[First Embodiment]
FIG. 1 is a block diagram illustrating an example of a network system to which a server device and an image forming apparatus according to the first embodiment of the present invention can be applied. An image forming apparatus to which the present invention can be applied includes a printing apparatus (printer) adopting an electrophotographic system, an ink jet system, or another printing system, a facsimile, or a digital composite which performs a complex image process including a facsimile process. Needless to say, the machine is included. Hereinafter, a digital MFP will be described as an example.
[0013]
Referring to FIG. 1, digital multifunction peripherals 101a and 101b are operated by supplying power from a DC power supply 203 to a printer unit (DCON 201), a reader unit (RCON 216), and a controller 202 as described later.
[0014]
102 is a server, 103a and 103b are personal computers (PCs), and the above-mentioned devices are connected by Ethernet (registered trademark) 104 of a local area network. The printer 103 is connected to the PCs 103a and 103b and the server 102 shown in FIG. 1 via the Ethernet (registered trademark) 104 to receive a print job from the PCs 103a and 103b, and to respond to a status inquiry from the PCs 103a and 103b. And output information.
[0015]
The status referred to here is the current accumulation status and processing status of the job, the current paper cassette size setting, whether there is paper in the paper cassette, the optional connection status, and whether there is toner. And so on. Further, the digital multifunction peripheral has a facsimile function and is communicably connected to the outside via a predetermined communication line (for example, a telephone line).
[0016]
Regarding the same components as those of a general copying machine of this digital multifunction machine, in brief, the reading of a document is converted into digital data using photoelectric conversion such as a CCD or a contact sensor. In printing, a latent image is formed on a photoconductor charged at a high pressure using a laser, an image of a toner serving as a developer is formed on the latent image, and the image is transferred to a transfer sheet.
[0017]
In addition, the digital multi-function peripheral according to the present embodiment has two standby modes, that is, a standby mode and a sleep mode, and one of operations such as a copy operation, a print operation, a facsimile transmission operation, a facsimile reception operation, and a scanner operation. This is a mode in which a composite operation is performed.
[0018]
Here, the standby mode is a mode in which the above-described operation is not performed, but the above-described operation can be started immediately.The sleep mode does not perform the above-described operation, and the above-described operation can be started immediately. Although it is not possible, this mode consumes less power than the standby mode.
[0019]
FIG. 2 is a block diagram illustrating a control configuration of the digital multifunction peripherals 101a and 101b illustrated in FIG.
[0020]
In FIG. 2, reference numeral 201 denotes a control board (DCON) which controls print control for receiving and printing video data from a controller 202, which will be described later, via an interface IF-1, and includes sensor groups 208, 209, and 210 required for various print controls. They are connected by interfaces IF-2, 3, and 4, connected by a DC load group 211 for printing to an interface IF-5, and connected to a laser 212 for exposing the photoconductor by an IF-6, and they are connected. Control.
[0021]
Also, the DCON 201 is connected to a paper discharge option 213 for sorting by an interface IF-17, is connected to a paper feed option 214 for increasing the number of cassettes for paper feed by an interface IF-18, and controls various information by serial communication. I have.
[0022]
The sensors are divided into three groups, each of which is a sensor A group 208 for performing regular detection during sleep as well as during copying / printing and standby, and sleeping, as well as during copying / printing and standby. If it is determined that it is necessary according to the state of the sensor A group even during the middle, the sensor B group 209 for performing more detailed detection, the detection is performed only during copying / printing or during standby, and during sleep, It is divided into a sensor C group 210 that does not perform any detection.
[0023]
The DCON 201 is connected to an AC driver 205 to be described later through an interface IF-7, and controls an AC load group 215 connected to the DCON 201. The AC load group 215 includes a heater (not shown) for heating and melting the toner to fix the toner on the sheet. The power supplied to the DCON 201 includes power supplied only during operation and standby, and power supplied also during sleep. Power supplied only during operation and standby is supplied from the DC power supply 203 via the PW-DC-2, and power supplied also during sleep is supplied from the controller 202 via the interface IF-1.
[0024]
Reference numeral 205 denotes an AC driver, which is a switch element such as a triac or SSR in response to an ON / OFF signal from the DCON 201 via the IF-7, and supplies or de-energizes the AC load to the AC load group 215 via the PW-AC-3. Switch energization.
[0025]
Reference numeral 216 denotes a control board (RCON), which controls a scanner system, and includes an image sensor for reading an image, a group of sensors 217, 218, and 219 for controlling paper of an original, and interfaces IF-12, 13, and 14. , And connected to the DC load group 220 via the interface IF-15 to control them.
[0026]
Further, sensors connected to the RCON 216 are also divided into three groups, and a sensor D group 217 that performs regular detection also during sleep, as well as during copying / printing and standby, and during copying / printing. If the group of sensors D changes even during sleep as well as during standby, then the group of sensors E 218 performs detection for more detailed detection, and performs detection only during copying / printing or during standby to perform sleep. The inside is divided into a sensor F group 219 that does not perform any detection.
[0027]
An image sensor 221 converts an image into an electric signal, formats the electric signal into a predetermined format, and transfers video data to a controller 202 described later via IF-16 and IF-9.
[0028]
Reference numeral 202 denotes a main control board (controller), which is connected to the DCON 201 by an interface IF-1, and connected to the RCON 216 by an IF-9. At the time of copying by this connection, the video data of the original is sent from the RCON 216 to the controller 202, and after processing the video data, the video data is sent from the controller 202 to the DCON 201. At this time, the controller 202 performs processing such as converting the format of the video data, processing the video data, and synchronizing the transfer of the video data with the timing of the printer. Also, by connecting to the operation unit 222 via IF-19, input from the operator and display to the operator can be performed. Reference numeral 223 denotes a power switch among them, and this input from the IF-20 triggers a transition to sleep and a return from sleep to standby.
[0029]
Further, the controller 202 can be connected to the DC power supply 203 via IF-8 to control ON / OFF of some DC power outputs included in the PW-DC-1, 2, 3. Further, the controller 202 is connected to the FAX-UNIT 206 via the IF-11, and is connected to the telephone line at the other end. Further, the controller 202 is connected to the LAN-UNIT 207 via the IF-10, and is connected to the Ethernet (registered trademark) at the other end. Here, the LAN-UNIT 207 is not limited to Ethernet (registered trademark), but is assumed to be a communication unit according to a predetermined protocol. It goes without saying that both wireless and wired are applicable.
[0030]
Reference numeral 204 denotes an AC input unit. AC100V is input from a power outlet via a PW-AC-1 path, and a circuit for detecting leakage, a circuit for removing noise, and a circuit for discharging the X capacitor. Through the PW-AC-2 path to the DC power supply 203 and the AC driver 205. The image sensor 221 is a sensor for reading an image.
[0031]
FIG. 3 is a block diagram illustrating the configuration of the DCON 201 shown in FIG. 2, and the same components as those in FIG. 2 are denoted by the same reference numerals.
[0032]
In FIG. 3, P5VB and P5VC are 5V power supplies, respectively. P5VB is a power supply supplied from the DC power supply 203, and is supplied during copying / printing and during standby. 301 to 309 are interface circuits (IF circuits). Note that the controller 202 controls the DC power supply 203 to turn on / off P5VB. P5VC is a power supply supplied from the controller 202 via the IF-1, and is always ON during copying / printing and standby, and is ON only when necessary during sleep.
[0033]
When necessary during sleep, the controller uses the parallel-serial conversion unit (parallel / serial conversion unit) Q302 and the serial-parallel conversion unit (serial / parallel conversion unit) Q303 to control the sensor A group 208 and the sensor B group 209. It is time to perform detection. The P5VC is ON / OFF controlled by the controller 202.
[0034]
A microcomputer Q301 has at least a ROM and a RAM therein, and operates according to a program written in the ROM. One of the roles of the microcomputer Q301 is to monitor the status. The microcomputer Q301 detects sensors A and B groups 208 and 209, which will be described later, at an input port, and opens and closes a door, opens and closes a cassette, paper size, and the presence or absence of paper. As a part of the status, the controller 202 (addressed to the main CPU or sub CPU) is notified by serial communication of IF-1.
[0035]
The other main roles of the microcomputer Q301 are to control the printing, to detect the state of the input ports connected to the sensors A, B, and C groups 208, 209, and 210, and to output the signals connected to the printer DC load group 211. A port and an output port connected to the AC driver 205 perform ON / OFF control of the ports to execute sheet transport control, high-pressure control, fixing heater control, and the like.
[0036]
Reference numeral Q309 denotes a gate array which receives video data from the IF-1, controls a laser unit 212 via an IF circuit 308 and an IF-6, and exposes a photoconductor (not shown) based on the video data to the photoconductor using the laser. A latent image is formed thereon as a distribution of the charged state. Further, the microcomputer Q301 writes a set value for operating the gate array Q309 via the bus.
[0037]
As serial communication signals from IF-1, SDATA_C2D which is a serial data signal from controller 202 to DCON 201, SDATA_D2C which is a serial data signal from DCON 201 to controller 202, and SCLK ↓ signal which is a serial data transfer clock. Among them, SDATA_C2D and SDATA_D2C are connected to the serial communication terminal of the microcomputer Q301 by signal switching circuits Q304, Q305, Q306, and Q308 for switching the connection destination in the state of the SLEEP signal when the SLEEP signal is low except in the sleep mode. And communicates with a main chip Q701 of the controller shown in FIG.
[0038]
Various kinds of information such as commands and status can be exchanged for communication contents other than the sleep. Note that no transfer clock is connected to the microcomputer Q301, and asynchronous communication is performed between the controller 202 and the transfer clock unnecessary.
[0039]
Next, during sleep, the SLEEP signal is high, and the signals SDATA_D2C, SDATA_C2D, and SCLK ↓ are connected to the serial-parallel conversion unit Q303 and the parallel-serial conversion unit Q302 by the signal switching circuits Q304, Q305, Q306, and Q308. It is clear from the configuration that the communication contents at the time of sleep cannot exchange various kinds of information as at times other than sleep, and the serial communication between the controller 202 and the DCON 201 is for status communication. Thus, the notification destination of information such as status can be changed between during sleep (during the energy saving mode) and when not sleeping.
[0040]
The LOAD signal is connected to the serial-parallel conversion unit Q303. During the LOAD, the serial-parallel conversion unit Q303 loads the data of the internal serial register to the buffer inside the serial-parallel conversion unit Q303 directly connected to the output terminals Q0 to Q15, and is not performing the LOAD. At times, it holds the data in the buffer.
[0041]
The serial register in the serial-to-parallel converter Q303 is output from the SO terminal of the serial-to-parallel converter Q303 in LSB first in synchronization with SCLK ↓. The data of the SI terminal of the serial-parallel converter Q303 is stored in the MSB of the shift register of the serial-parallel converter Q303 in synchronization with the clock. The SO terminal of the serial-parallel conversion unit Q303 is connected while the SDATA_D2C signal to be transmitted to the controller is in the sleep state. The SI terminal of the serial-to-parallel conversion unit Q303 is connected to the paper feed option 214 in cascade during sleep.
[0042]
Conversely, the parallel-to-serial conversion unit Q302 is also connected to the LOAD signal, and during the LOAD, loads the data of the input terminals D0 to D15 to the serial register inside the parallel-to-serial conversion unit Q302. The serial register inside the parallel-serial conversion unit Q302 is output from the SO terminal of the parallel-serial conversion unit Q302 in LSB first in synchronization with SCLK ↓. The data of the SI terminal of the parallel-serial conversion unit Q302 is stored in the MSB of the shift register of the parallel-serial conversion unit Q302 in synchronization with the clock. The SI terminal of the parallel-serial conversion unit Q302 is connected while the SDATA_C2D signal received from the controller is in the sleep state. The SO terminal of the parallel-to-serial conversion unit Q302 is connected to the paper feed option 214 in cascade during sleep.
[0043]
As described above, according to the configuration of FIG. 3, the sleep signal from the main chip Q701 shown in FIG. 7, which will be described later, shuts off P5VB, which is the power supply to the microcomputer Q301, in accordance with the High instruction, and Power is saved. In addition, since the signal switching circuits Q304, Q305, Q306, and Q308 are driven instead of the microcomputer Q301, communication of information such as status with the controller 202 can be continuously performed while saving power.
[0044]
FIG. 4 is a diagram illustrating an interface between the controller 202 and the DCON 201 illustrated in FIG.
[0045]
In FIG. 4, C_P_READY is a signal for the DCON 201 to confirm that the communication preparation of the controller 202 is OK. P_P_READY is a signal for the controller 202 to confirm that DCON communication preparation is OK.
[0046]
SCLK ↓ is a clock signal for serial communication. SDATA_C2D is a data signal from the serial communication controller to the DCON 201. SDATA_D2C is a data signal from the DCON 201 of the serial communication to the controller 202.
[0047]
PSTART is a signal by which the controller 202 notifies the DCON 201 of the start of printing. VREQ is a signal that the DCON 201 requests the controller to start outputting sub-scan video data in response to the PSTART signal. VSYNC is a signal that informs the DCON 201 that the controller 202 starts outputting valid main scanning lines after a predetermined number of main scanning lines, and is a signal that follows VREQ.
[0048]
HREQ is a signal that the DCON 201 requests the controller 202 to start outputting main scan video data every main scan. HSYNC is a signal that informs the DCON 201 that the controller 202 outputs valid video data after a predetermined number of VIDEO_CLKs for each main scan, and is a signal that follows HREQ. VIDEO_CLK is a transfer clock of VIDEO_DATA.
[0049]
VIDEO_DATA is an 8-bit video data signal. The SLEEP signal is a signal output to the DCON 201 from the controller 202 which becomes HIGH during sleep. The LOAD signal is a signal for loading the data of the serial-parallel conversion and the parallel-serial conversion, and is a signal for controlling the power supply of some sensors. P5VC is a 5V power supply that can be turned on / off and supplied from the controller 202 to the DCON 201.
[0050]
FIG. 5 is a diagram for explaining the IF circuit 2 (in the IF circuit 2 and the IF circuit 3 (301)) which is an interface between the DCON 201 and the sensor A group 208 shown in FIG. Note that the sensor A group 208 is a group of sensors configured by the mechanical micro switches shown in FIG. The same components as those in FIG. 3 are denoted by the same reference numerals.
[0051]
In FIG. 5, an SW 501 is a door open / close detection switch that detects opening / closing of a door that needs to be opened when a user accesses a process system such as a fixing device or a drum cartridge. SW502 is a cassette open / close detection upper switch that detects open / close of the upper cassette.
[0052]
SW503 is a cassette open / close detection lower switch that detects open / close of the lower cassette. An SW 504 is a discharge option connection detection switch that detects connection of the discharge option. SW505 is a paper feed option connection detection switch that detects connection of the paper feed option. In FIG. 5, P5VC is a power supply.
[0053]
Q501 and Q502 are PNP transistors, which control on / off of power supplied from the switch SW501 to the switch SW505.
[0054]
R501, R502, R503, R504, and R505 are resistors for limiting a current value supplied from the switch SW501 to the switch SW505.
[0055]
R-IN0 is a signal for detecting ON / OFF of the switch SW501. R-IN1 is a signal for detecting ON / OFF of the switch SW502. R-IN2 is a signal for detecting ON / OFF of the switch SW503. R-IN3 is a signal for detecting ON / OFF of the switch SW504. R-IN4 is a signal for detecting ON / OFF of the switch SW505. The SLEEP signal and the LOAD signal are signals for controlling the supply of P5VC.
[0056]
With such a configuration, in the IF circuit 2, when the PNP transistor Q501 and the PNP transistor Q502 are in the ON state, it is possible to detect on / off of the switches SW501 to SW505.
[0057]
When it is not necessary to detect on / off of the switch SW501 to the switch SW505, the transistors Q501 and Q502 are controlled to be in an off state, and energy consumption is suppressed by not supplying a current from the switch SW501 to the switch SW505. Is possible.
[0058]
FIG. 6 is a diagram for explaining the IF circuit 3 (in the IF circuit 2 and the IF circuit 3 (301)) which is an interface between the DCON 201 and the sensor B group 209 shown in FIG. Note that the sensor B group is a sensor group based on the photo interrupters shown in FIG.
[0059]
In FIG. 6, Q607 is a cartridge detection sensor for detecting the presence or absence of a cartridge. Q608, Q609, Q610, and Q611 are an upper paper size 0 sensor, an upper paper size 1 sensor, an upper paper size 2 sensor, and an upper paper presence sensor for detecting the paper size of the upper cassette.
[0060]
Reference numerals Q612, Q613, Q614, and Q615 denote a lower paper size 0 sensor, a lower paper size 1 sensor, a lower paper size 2 sensor, and a lower paper presence / absence sensor for detecting the paper size of the lower cassette.
[0061]
The IF circuit 3 is an interface circuit with the sensor B group 209 shown in FIG. P5VC is a power supply shown in FIG. The SLEEP signal and the signal from R-OUT0 are input signals of the IF circuit 3 shown in FIG. The power supply to the photointerrupter sensor is controlled by these signals. R-IN5 to RIN-13 are output signals from the IF circuit 3 corresponding to the outputs of the respective sensors. As described above, power is efficiently supplied to the sensor B group 209 when necessary, so that sensor information can be efficiently acquired and power saving can be realized.
[0062]
Q602, Q604, and Q606 are PNP transistors that are on / off controlled by the SLEEP signal and control power supply to the photointerrupter sensor. Q601, Q603, and Q605 are PNP transistors that are on / off controlled by R-OUT0, R-OUT1, and R-OUT2, respectively, and that control power supply to the photointerrupter sensor. R601 to R609 are current limiting resistors for controlling the current to the photo interrupter.
[0063]
In such a configuration, since the sensor B group 209 is configured to select the power supply based on the transmission data, it is possible to turn off the power to the photointerrupter sensor except when necessary. This makes it possible to reduce power consumption during sleep.
[0064]
FIG. 7 is a diagram illustrating a detailed configuration of the controller 202 illustrated in FIG.
[0065]
In FIG. 7, reference numerals 701 to 708 denote interface circuits (IF circuits), each of which controls an interface between a specific device and a one-chip microcomputer Q702 or a main chip Q701.
[0066]
In FIG. 7, P5VA, P5VB and P5VC are 5V power supplies, respectively, and P5VA and P5VB are power supplies supplied from the DC power supply 203. P5VA is always supplied to drive the sub CPU and the like. P5VB is supplied only during an image forming operation such as copying / printing and during standby. P5VC is a power supply realized based on the power supply of P5VA, is a power supply that is turned on / off by Q705 in the controller 202, and can perform control to supply power intermittently to DCON and RCON. . In addition, unnecessary power consumption can be reduced by saving power other than P5VA in the energy-saving mode (sleep mode). In particular, P5VB shuts down the power supply circuit in the power supply. Has a great effect.
[0067]
P5VA, P5VB, and P5VC are commonly applied to not only FIG. 7 but also FIGS. 3, 4, 5, 6, 8, 9, and 10. The power supply of P5VA, P5VB, and P5VC is controlled according to the flowcharts of FIGS. 11, 12, 13, and 14.
[0068]
The main chip Q701 uses the RAMQ704, which is backed up by the battery BT701 and retains data even when the power is off, as a work area, a microprocessor that executes a control program stored in the ROMQ703, an interrupt control circuit that controls various interrupt signals, and a DMA control. It controls the whole controller including circuits, various timers, image processing circuits, resolution conversion circuits, input / output port interface circuits, and the like.
[0069]
It further includes a PLL circuit connected to X'tal (X701) and outputting an internal operation clock. This PLL circuit stops clock output when the microprocessor enters a power saving sleep state, thereby reducing power consumption of the entire chip. It has a function to keep it low.
[0070]
The one-chip microcomputer (sub-chip) Q702 has the same configuration as a general microcomputer such as a CPU, a RAM, and a ROM, and does not employ complicated logic as compared with the main chip, and has a low CPU clock frequency. For this reason, a microcomputer with low power consumption is used because it has a small-capacity memory. Then, even in the sleep state, the one-chip microcomputer can execute a part of the normal operation of the main chip, such as updating the status and driving the LAN-UNIT 207 for notification of information to the outside. As will be described later in detail, power supply control during sleep, status monitoring, monitoring and response of commands from the network, and the like can also be executed.
[0071]
An interrupt signal 709 from a one-chip microcomputer (sub chip) Q702 is input to an NMI (non-maskable interrupt) terminal of the main controller (main chip) Q701, and if the NMI is input while the microprocessor is in a sleep state, The sleep state is released, the PLL circuit is enabled, a clock is supplied to the entire main chip, and the main chip starts operating again.
[0072]
The one-chip microcomputer Q702 monitors the sensor signals of the RCON 216 and the DCON 201 in the sleep state, and monitors the sleep return signal of the FAX-UNIT 206. Further, in sleep mode, a command response and status information are sent to the LAN-UNIT 207 instead of the main chip Q701.
[0073]
Commands and data can be exchanged between the one-chip microcomputer Q702 and the main chip Q701 by serial communication 710. The interrupt signal 709 from the one-chip microcomputer Q702 is input to the NMI terminal of the main chip. An Active signal 711 indicating whether the main chip Q701 is in the sleep state or the operation state is input to the one-chip microcomputer Q702.
[0074]
A power switch 223 is provided on the operation unit 222, and the digital multifunction peripheral of the present embodiment shifts to a sleep state or returns from the sleep state according to an input of the power switch 223.
[0075]
However, the transition to the sleep state is not limited to the input of the power switch 223, and automatically shifts to the sleep state when the digital multifunction peripheral is in the standby state for a predetermined time which can be selected by the setting from the operation unit 222. You can do it.
[0076]
Also, the return from the sleep state is made not only by the input of the power switch 223 but also by a command from the LAN or a call signal from the telephone line, as described later.
[0077]
The Sleep signal 712 indicating the transition to the sleep state is set to the “H” level during sleep, and sends a signal from the main chip Q701 to the RCON 216 via the IF circuit 706 with the RCON, and to the DCON 201 via the IF circuit 701 with the DCON.
[0078]
During sleep, the power supply other than P5VA is turned off by the DC power supply by a control signal from the one-chip microcomputer Q702, and the power supply of the P5VC is intermittently turned on / off by the transistor Q705 to reduce power consumption.
[0079]
The RCON 216 converts an image signal from a photoelectric conversion element such as a CCD into an analog signal, performs a read image process such as a shading process, and outputs an 8-bit video signal.
[0080]
It also outputs the state of various sensors such as the document size to the controller, and also controls the motor of the reading unit. IF-9 includes a vertical synchronization signal (output), a horizontal synchronization signal (output), a vertical synchronization request signal (input), a horizontal synchronization request signal (input), a clock (output), a video signal 8 bit (input), and a video signal ready. There are signal lines such as a signal (input), a sleep signal 712 (output), and a load signal (output), and RCON sensor information is input through serial communication.
[0081]
The IF circuit 706 with the RCON 216 sends each signal of IF-9 to the main chip Q701. However, since the main chip Q701 cannot receive a signal during sleep, the signal is sent to the one-chip microcomputer Q702, and this switching is performed by a sleep signal 712 from the main chip Q701.
[0082]
The DCON 201 records an image as described with reference to FIG. IF-1 has the signal line described with reference to FIG. 4, and the sensor signal of DCON 201 is input by serial communication together with the command status signal.
[0083]
The IF circuit 701 with the DCON 201 sends each signal of IF-1 to the main chip Q701. However, since the main chip Q701 cannot receive a signal during sleep, the signal is sent to the one-chip microcomputer Q702, and this switching is performed by a sleep signal 712 from the main chip Q701.
[0084]
In the IF-1, eight Video_data signals are normally used for transferring image signals, and during sleep, seven sensor signals and a Load signal are switched and used by a Sleep signal. The number of IF-1 signal lines may be saved.
[0085]
When reading an image, the video signal input from the RCON 216 via the IF-9 is transferred to the image processing unit to perform image processing, and is stored in the RAM Q704.
[0086]
At the time of image recording, the image data in the RAM Q704 is read, image processing and resolution conversion are performed based on the recording paper size and various settings, and the image data is output to the DCON 201 via the IF-1.
[0087]
The LAN-UNIT 207 includes a physical layer (PHY) for connecting to Ethernet (registered trademark), an Ethernet (registered trademark) connection circuit for controlling the MAC layer, a LAN control unit for controlling communication of IEEE802.3, and the like.
[0088]
The LAN-UNIT IF circuit 702 is a USB or IEEE 1284 interface circuit, and transmits information received from the LAN-UNIT 207 via the IF-10 to the main chip Q701, and transmits information from the main chip to the LAN-UNIT 207.
[0089]
For example, when a command for requesting the status of the digital multifunction peripheral of the present embodiment is detected via the LAN-UNIT 207, the status request command is transmitted from the LAN-UNIT IF circuit 702 to the main chip Q701, and The necessary status held in the storage unit (RAM) by the Q 701 is transmitted from the main chip Q 701 to the LAN-UNIT IF circuit 702, and the LAN-UNIT IF circuit 702 sends this information to the LAN-UNIT 207 via the IF-10. .
[0090]
When a print job comes from a PC on the network, a command to request printing is transmitted from the LAN-UNIT IF circuit 702 to the main chip Q701, and when printing is possible, a response of print OK is sent from the main chip Q701. The information is transmitted to the LAN-UNIT IF circuit 702, and the LAN-UNIT IF circuit 702 sends this information to the LAN-UNIT 207 via the IF-10.
[0091]
When a PC (information processing device) on the network receives this response, the print data is subsequently transmitted. Therefore, with the same signal flow, the print data is input to the main chip Q701, and the necessary image is transmitted from the main chip Q701. After being subjected to the processing, it is temporarily stored in the RAM. Then, the image data is sent to the DCON 201 as an image signal of IF-1 and recorded in the same manner as the processing at the time of image recording.
[0092]
The above is a case where the main chip Q701 is operating normally, and the operation during sleep is slightly different from the above operation.
[0093]
In the sleep mode, the exchange of commands with the network is performed by the one-chip microcomputer Q702. The LAN-UNIT IF circuit 702 transmits information received from the LAN-UNIT 207 via the IF-10 to the one-chip microcomputer Q702, and transmits information from the one-chip microcomputer Q702 to the LAN-UNIT 207.
[0094]
In sleep mode, the main chip Q701 is in a sleep state and cannot transmit or receive signals. Therefore, the one-chip microcomputer Q702 receives and monitors status information from the IF circuit 706 with the RCON 216 and the IF circuit 701 with the DCON 201. ing. As will be described with reference to a diagram (flow chart) shown separately, upon receiving a status request command from the LAN-UNIT 207, the one-chip microcomputer Q702 sends status information to the LAN-UNIT 207 as a response.
[0095]
When the digital MFP is released from sleep for the reason that a print job to the digital MFP according to the present embodiment occurs during sleep, the command received from the LAN-UNIT 207 must first return from sleep. The one-chip microcomputer Q702 determines whether or not the content cannot be processed. When a command that cannot be processed without returning from sleep, such as a print request, is received, the one-chip microcomputer Q702 issues an instruction to the power control IF circuit 705 to turn on the power dropped during sleep, and The circuit 705 sends a power-on signal to the DC power source 203.
[0096]
On the other hand, an interrupt signal (NMI) 709 is output to the NMI terminal of the main chip Q701, and the main chip Q701, which has received the interrupt signal 709 from the NMI terminal, is described with reference to another diagram (flow chart). Then, the state shifts from the sleep state to the normal state. When the one-chip microcomputer Q702 confirms by the Active signal 711 that the main chip Q701 is in the normal state, the one-chip microcomputer Q702 transmits the content of the received command to the main chip Q701 by serial communication 710. When the main chip Q701 determines that the digital multifunction peripheral has become ready to process the received command (when it is confirmed that the print command has started up in a recording-capable state), the main chip Q701 is required for the LAN-UNIT 207. A good response.
[0097]
FAX-UNIT 206 is a CODEC that encodes and decodes image data, modulates the encoded data for FAX transmission, and a MODEM that demodulates a received FAX signal, a FAX control unit that executes a FAX protocol, and calls. It includes a CI detection circuit that detects a signal (CI) and outputs a CI detection signal, an off-hook detection circuit that detects an off-hook and outputs an off-hook detection signal, and the like.
[0098]
An IF circuit 703 with the FAX-UNIT 206 is an IEEE1284 interface circuit, and exchanges commands and image data with the FAX-UNIT 206 via the IF-11. Also, it receives a CI detection signal (input) and an off-hook detection signal (input).
[0099]
At the time of FAX transmission, the image data in the RAM Q704 is sent to the FAX-UNIT 206 to perform FAX transmission, and at the time of FAX reception, the image data is received from the FAX-UNIT 206 and temporarily stored in the RAM. Then, the image data is sent to the DCON 201 as an image signal of IF-1 and recorded in the same manner as the processing at the time of image recording.
[0100]
At the time of sleep, a CI detection signal and an off-hook detection signal in the IF-11 are monitored, and when a CI arrival or an off-hook is detected, a start signal 713 from a facsimile is transmitted to the one-chip microcomputer Q702 and the main chip Q701. Upon receiving the activation signal 713 from the facsimile, the one-chip microcomputer Q702 starts up the power supply and restores the main controller from the sleep mode so that it can respond to the command from the facsimile unit 206.
[0101]
In the above description, the start signal 713 from the FAX is input to both the one-chip microcomputer Q702 and the main chip Q701. However, the FAX start signal 713 is input only to the one-chip microcomputer Q702, and the one-chip microcomputer Q702 performs serial communication. A message 710 may indicate that the fax machine has been activated by an activation signal from the FAX-UNIT 206.
[0102]
FIG. 8 is a diagram for explaining the configuration of the RCON 216 shown in FIG. 2, and the same components as those in FIG. 2 are denoted by the same reference numerals.
[0103]
8, the RCON 216 has a configuration in which the printer DC load group 211 is replaced with the reader DC load group 220 in FIG. 2 as compared with the DCON shown in FIG. Reference numerals 901 to 904, 908, and 909 denote interface circuits (IF circuits). The IF circuit 901 includes an IF circuit 2 and an IF circuit 3 of the RCON 216. The IF circuit 902 includes an IF circuit DC-3 of the RCON 216.
[0104]
The IF circuit 903 includes an IF circuit 4 with the RCON 216. The IF circuit 904 includes the IF circuit 5 of the RCON 216. The IF circuit 908 is the IF circuit 6 of the RCON 216. The IF circuit 909 is the IF circuit 1 of the RCON 216.
[0105]
The RCON 216 does not include the AC driver 205, the IF circuit 305, the paper discharge option 213, the IF circuit 306, the paper feed option 214, the IF circuit 307, the laser circuit 212, and the IF circuit 308 in FIG. Also, there are no signal lines connected to them. The image sensor 221 is a sensor for reading an image.
[0106]
PW-DC-3 is a power supply IF of the RCON 216. Q901 is a microcomputer of the RCON 216. Q902 is a serial-parallel conversion unit of the RCON 216. Q903 is an RCON serial / parallel conversion unit. Q904 and Q906 are three-state buffers of the RCON 216.
[0107]
FIG. 9 is a diagram for explaining the interface between the IF circuit 2 and the sensor A group provided in the paper feed option 214 shown in FIG. 3. The basic configuration and operation are provided in the RCON 206 and the DCON 201. This is equivalent to the IF circuit 2.
[0108]
In FIG. 9, a sensor A group provided in the paper feed option 214 is a group of sensors configured by micro switches. In the group of sensors A, SW1002 is a cassette open / close detection upper switch that detects open / close of the upper cassette. SW1003 is a cassette open / close detection lower switch that detects open / close of the lower cassette. P5VC is the power supply shown in FIG.
[0109]
In the IF circuit 2 in the paper feed option 214, Q1001 and Q1002 are PNP transistors, which control on / off of power supplied to switches from a switch SW1002 to a switch SW1003. R1002 and R1003 are resistors for limiting a current value supplied from the switch SW1002 to the switch SW1003.
[0110]
R-IN17 is a signal for detecting ON / OFF of SW1002. R-IN18 is a signal for detecting ON / OFF of SW1003. The SLEEP signal and the LOAD signal are signals for controlling the supply of P5VC.
[0111]
With such a configuration, the IF circuit 2 in the paper feed option 214 can detect the on / off state of the switches SW1002 to SW1003 when the transistors Q1001 and Q1002 are in the on state.
[0112]
When the on / off detection of the switch SW1003 from the switch SW1002 is not required, the transistors Q1001 and Q1002 are controlled to be in an off state, and the current consumption is suppressed by not supplying the current from the switch SW1002 to the switch SW1003. Is possible.
[0113]
The IF circuit 2 in the paper feed option 214 can communicate with the IF circuit 18 (307) in the DCOM 201 via the IF-18 shown in FIG. The S-OUT2 of the IF circuit 18 (307) is connected to the parallel-serial conversion unit Q302, the S-IN2 of the IF circuit 18 (307) is connected to the serial-parallel conversion unit Q303, and the S-IN2 of the IF circuit 18 (307) is connected. LOAD, SLEEP, and SCLK ↓ are output from the IF circuit 309.
[0114]
FIG. 10 is a diagram for explaining the interface between the IF circuit 3 provided in the paper feed option 214 shown in FIG. 3 and the sensor B group. Basically, the IF circuit 3 provided in the RCON 216 and the DCON 201 is used. And has the same operation.
[0115]
In FIG. 10, a sensor B group provided in the paper feed option 214 is a sensor group using a photo interrupter. In the sensor B group, Q1108 is an upper paper size 0 sensor for detecting the paper size of the upper cassette. An upper paper size 1 sensor Q1109 detects the paper size of the upper cassette. Q1110 is an upper paper size 2 sensor for detecting the paper size of the upper cassette. Q1111 is an upper paper presence sensor for detecting the presence of paper in the upper cassette.
[0116]
Q1112 is a lower paper size 0 sensor for detecting the paper size of the lower cassette. A lower paper size 1 sensor Q1113 detects the paper size of the lower cassette. Q1114 is a lower paper size 2 sensor for detecting the paper size of the lower cassette. Q1115 is a lower paper presence sensor for detecting the presence or absence of paper in the lower cassette.
[0117]
P5VC is a power supply shown in FIG. SLEEP signals and R-OUTs 17 to 18 are input signals of the IF circuit 3. The power supply to the photointerrupter sensor is controlled by these signals.
[0118]
R-IN22 to RIN-29 are output signals from the IF circuit 3.
[0119]
Q1104 and Q1106 are PNP transistors which are on / off controlled by a SLEEP signal to control power supply to the photointerrupter sensor.
[0120]
Q1103 and Q1105 are PNP transistors which are on / off controlled by R-OUT17 and R-OUT18, respectively, to control power supply to the photointerrupter sensor. R1102 to R1109 are current limiting resistors for controlling the current to the photo interrupter.
[0121]
The IF circuit 3 in the paper feed option 214 can communicate with the IF circuit 18 in the DCON 201 via the IF-18 shown in FIG. The S-OUT2 of the IF circuit 18 (307) is connected to the parallel-serial conversion unit Q302, the S-IN2 of the IF circuit 18 (307) is connected to the serial-parallel conversion unit Q303, and the S-IN2 of the IF circuit 18 (307) is connected. LOAD, SLEEP, and SCLK ↓ are output from the IF circuit 309.
[0122]
With such a configuration, it is possible to turn off the power to the photointerrupter sensor except when necessary.
[0123]
In the above configuration, the transition to the power saving sleep state, the return to the normal state, and the status monitoring of the DCON 201 and the RCON 216 in the sleep state, the command monitoring from the LAN-UNIT 207, and the status transmission to the LAN-UNIT 207 are performed. It is controlled by a one-chip microcomputer Q702 (hereinafter, sub CPU) and a main chip Q701 (hereinafter, main CPU).
[0124]
Hereinafter, these operations will be described with reference to the flowcharts of FIGS. 11, 12, 13, and 14.
[0125]
FIG. 11 is a flowchart illustrating an example of a first control procedure in the image forming apparatus according to the present invention, and corresponds to an operation procedure of the sub CPU based on a program stored in a ROM or another storage medium (not shown). Note that S201 to S217 indicate each step.
[0126]
The sub CPU is connected to the DC power supply P5VA and operates at all times, and the operation is roughly classified into a sleep state in which the main CPU is in the HALT state and a normal state in which the main CPU operates normally. First, the normal state will be described.
[0127]
It is determined whether the ACTIVE signal 711 from the main CPU is in the ON state. If the ACTIVE signal 711 is in the ON state (S201), the state is the normal state, the status of the DCON 201 and the RCON 216 is received from the main CPU (S202), and the power switch 223 is received. Is repeated (S203).
[0128]
Here, when it is determined that the power switch 223 has been pressed, a system down request (SYSTEM DOWN) is transmitted to the main CPU so as to shift the entire system to the power saving sleep state (S204). Here, the status reception and the system down request are performed using the serial communication 710 between the sub CPU and the main CPU.
[0129]
On the other hand, when the ACTIVE signal from the main CPU is turned off (S201), the state shifts to the power saving sleep state. Although the cause of the OFF of the ACTIVE signal will be described later, when the power saving sleep mode is entered, the power supply control IF circuit 705 is first instructed to turn off the power supply P5VB to the DCON 201 and the RCON 216 (S205).
[0130]
Next, the status monitoring timers of the DCON 201 and the RCON 216 are started (S206). This timer is a timer for measuring an interval for acquiring the status, and in this embodiment, measures 100 msec.
[0131]
Until the time of 100 msec is counted, whether there is a FAX job request (S207), whether there is a print job request (S208), whether the power switch is pressed (S209), or whether there is a status request from an external device (S210) ) Is repeated, and when there is a job request (Yes in S207 and S208) and when the power switch is pressed (Yes in S209), the power supply control IF circuit 705 supplies the power supply P5VB to the DCON 201 and the RCON 216 system. The main CPU activation signal 709 is turned ON (S212), and after the main CPU is activated (ACTIVE signal ON) (S213), the activation factor in step S209 and the LAN in steps S207 and S208 are instructed. -Information such as commands received from UNIT Was transferred to the main CPU (S214), the process returns to step S201, shifts to the normal state.
[0132]
The presence or absence of a FAX job in step S207 is determined based on the CI detection signal and the off-hook detection signal supplied from the FAX-UNIT-IF circuit 703 described above. The presence or absence of a print job is determined by a command supplied from the LAN-UNIT-IF circuit 702 described above, and this command is transferred to the main CPU.
[0133]
On the other hand, if there is a status request from the external device (S210), a status response for transmitting the held latest status to the external device via the LAN-UNIT 207 is performed (S215). The status information transmitted (notified) to the external device is displayed as status information on a display unit provided in the external device, so that the user can check the latest status.
[0134]
The status of the DCON 201 and the RCON 216 transmitted here is the latest status of the status received from the main CPU in step S202 or the status obtained in step S217.
[0135]
Until the status monitoring timer measures 100 msec (S216), the processing from step S207 is repeated. When the status monitoring timer measures 100 msec (S216), the status is acquired from DCON 201 and RCON 216 (S217), and the processing from step S206 is performed. repeat. The details of the status acquisition operation in step S217 will be described later with reference to FIG.
[0136]
As described above, according to the flowchart of FIG. 11, the power of the P5VB power is saved unless a process such as a process related to image formation / a power switch is pressed is detected. In addition, the sub CPU consuming less power can respond to the status request (S210) from the outside, even though the main CPU is saving power. The status responding to the outside is updated in accordance with the processing in step S217, and power saving is also performed in the status processing in step S217.
[0137]
Next, the operation of the main CPU will be described with reference to the flowchart of FIG.
[0138]
FIG. 12 is a flowchart illustrating an example of a second control procedure in the image forming apparatus according to the present invention, and corresponds to an operation procedure of the main CPU based on a program stored in a ROM or another storage medium (not shown). In addition, S301 to S322 indicate each step.
[0139]
Like the sub CPU, the main CPU is always connected to the DC power supply P5VA and operates at all times. The main CPU includes a sleep state in which the CPU clock (X701) is stopped, a facsimile transmission, a facsimile transmission, and a print operation. All of the operations of the present system, such as a scanning operation and a status request response from an external device, are roughly classified into a normal state in which all operations can be performed.
[0140]
When the main CPU enters the normal state (from the HALT state), first, the ACTIVE signal 711 is turned on (S301). As described above, this operation causes the sub CPU to enter the normal state. Next, an activation factor and a command are received from the sub CPU (S302). At this time, the command to be received is a command received from the LAN-UNIT by the sub CPU as described above, and is processed in step S307 and subsequent steps.
[0141]
Next, the sleep signal 712 is turned off (S303). As described above, by this operation, in the controller, in the DCON-IF circuit 701 and the RCON-IF circuit 706, the serial communication IF with the DCON 201 and RCON 216 is switched from the sub CPU to the main CPU.
[0142]
Also in the DCON 201 and the RCON 216, the sleep state of the DCON microcomputer Q301 and the RCON microcomputer Q901 is released at the same time as the serial communication IF is switched from the hardware configuration to the DCON microcomputer Q301 and the RCON microcomputer Q901.
[0143]
Next, the power saving sleep transition timer is started (S304). This timer measures the time from the normal state to the transition to the power-saving sleep state again. In the present embodiment, it measures one hour. Until one hour is counted, statuses are received from the DCON 201 and the RCON 216 (S305), and there is a system down request from the sub CPU (S306), a FAX job request (S307), and a print job request. (S308), whether there is a job request from the DCON microcomputer Q301 (S309), whether there is a job request from the RCON microcomputer Q901 (S310), and whether there is a status request (status response job) from an external device (S311). repeat.
[0144]
Then, when there is a system down request (S306), a transition process to a power saving sleep state from step S315 described later is performed.
[0145]
If there is a job request, a predetermined job is executed (S312), the power saving sleep transition timer is set to one hour again, restarted (S313), and the process returns to step S305.
[0146]
The presence or absence of the FAX job is determined based on the CI detection signal and the off-hook detection signal supplied from the FAX-UNIT-IF circuit 703 or the command received from the sub CPU in step S302. The presence or absence of a print job is determined by the command supplied from the LAN-UNIT-IF circuit 702 described above or the command received from the sub CPU in step S302. Job requests from DCON and RCON are received by respective serial communication IFs.
[0147]
The presence or absence of a status request from an external device is determined by the command supplied from the LAN-UNIT-IF circuit 702 described above. The job can be executed by any general method, and a detailed description thereof will be omitted.
[0148]
On the other hand, if the power saving sleep transition timer measures one hour, that is, if one hour has passed without any job being executed (S314), the power saving sleep mode after step S315 is performed in order to shift to the power saving sleep state by itself. Perform transition processing to the state.
[0149]
Next, transition processing to the power saving sleep state after step S315 will be described. As described above, the power saving executed when the system down request is issued from the sub CPU (S306), or when the main CPU shifts itself to the power saving sleep state by the power saving sleep transition timer (S314). In the transition to the sleep state, first, a power-off notice is transmitted to DCON and RCON via the serial communication IF (S315), and the reception of a power-off permission response from the DCON 201 and RCON 216 is waited for (S316).
[0150]
The DCON and RCON microcomputers are configured to perform a predetermined power-off process upon receiving the power-off notice, and transmit a power-off permission to the main CPU upon completion.
[0151]
When the power-off permission response is received from both the DCON and RCON microcomputers (S316), the status of DCON and RCON is transmitted to the sub CPU (S317). The DCON and RCON statuses transmitted here are the latest statuses received from the DCON microcomputer and the RCON microcomputer in step S305.
[0152]
Next, the sleep signal 712 is turned on (S318). As described above, in the controller, the serial communication IF for DCON and RCON is switched from the main CPU to the sub CPU in the DCON-IF circuit 701 and the RCON-IF circuit 706 in the controller. Also in DCON and RCON, the serial communication IF switches from the DCON microcomputer Q301 and the RCON microcomputer Q901 to a hardware configuration, and at the same time, the DCON microcomputer and the RCON microcomputer enter a sleep state.
[0153]
Next, the ACTIVE signal 711 is turned off (S319). As described above, this operation causes the sub CPU to enter the power saving sleep state.
[0154]
Next, the main CPU switches itself to the HALT state in which the CPU clock (X701) is stopped, and the transition to the power saving sleep state is completed (S320). This state continues until an interrupt is generated by the main CPU activation signal 709 supplied from the sub CPU. When an interrupt occurs (S321), the HALT state is released (S322), and the process proceeds to step S301 in the normal state. I do.
[0155]
Next, an operation in which the sub CPU acquires the status from DCON during the power saving sleep will be described with reference to the flowcharts of FIGS.
[0156]
FIGS. 13 and 14 are flowcharts showing an example of a third control procedure in the image forming apparatus according to the present invention. The operation procedure of the sub CPU based on a program stored in a ROM (not shown) or other storage medium (FIG. 11 (a detailed procedure of the status acquisition processing procedure of step S217). S401 to S430 indicate each step.
[0157]
First, P5VC is turned on in order to enable the DCON and the hardware serial communication block of the sheet feeding unit to operate (S401). By driving the P5VC, as shown in FIGS. 5 and 6, the IF circuits 2 and 3 are energized, and the sensors A and B enter a state where signals can be detected. This control is equivalent to controlling the supply of power (power supply to the sensor group) required for updating the status which is saved in the energy saving mode when the status is updated, and the status updated according to the control is shown in FIG. An external device is notified via the LAN-UNIT 207 based on the processing of the sub CPU in the "status response" of step S215 of step S215.
[0158]
Next, the LOAD signal is set to L (S402), and after waiting for 100 μsec (hereinafter, “usec”) until the input data of the parallel-serial conversion unit Q302 becomes stable (S403), the LOAD signal is set to H to determine the input data of the parallel-serial conversion unit. (S404).
[0159]
Next, transmission data “0000 (Hex)” is set so as to turn off the power supply to the sensor B group 209 (S405), and 32 clocks clk are output from SCLK, thereby transmitting and receiving 32-bit data. (S406). Thereby, the state of the sensor A group can be received. At this time, the information of the sensor B group is also received, but since the power supply is OFF, control is performed so that invalid data is obtained.
[0160]
More specifically, transmission data “0000 (hex)” is transmitted to the serial-parallel conversion unit Q303 via SDATA_C2D, and data of R-IN31 to R-IN0 is received from the parallel-serial conversion unit Q302 via SDATA_D2C. . However, R-IN5 to R-IN16 and R-IN19 to R-IN31 received at this time are invalid data. If the paper feed unit is not connected, the upper 16 bits of the transmission / reception data become invalid data.
[0161]
Next, the LOAD signal is set to L (S407), and after waiting for 100 usec (S408), the LOAD signal is set to H and the output data of the serial-parallel conversion unit Q303 is determined (S409). Here, the next transmission data, which is a register for checking a change in status, is cleared to 0 and initialized (S410). This step S410 is a step for clearing the communication buffer.
[0162]
Next, the received status of the sensor A group is compared with the latest status that has been acquired.
[0163]
If the door open / close detection switch (SW501), which is bit0 (R-IN0) of the reception data, is open (S412), the bit0 of the next transmission data is set (the set here is "0" to "1"). ), And the detection result of the cartridge detection (Q607) is output to the R-IN5 when the next data is transmitted (S413).
[0164]
When the cassette open / close detection upper switch (SW502), which is bit 1 (R-IN1) of the received data, changes from the open state to the closed state (S414), the bit 1 of the next transmission data is set, and the upper cassette size is set when the next data is transmitted. The detection results of the 0 sensor (Q608), the upper cassette size 1 sensor (Q609), the upper cassette size 2 sensor (Q610), and the upper paper presence / absence detection sensor (Q611) are output to R-IN6 to R-IN9. (S415).
[0165]
When the cassette open / close detection lower switch (SW503), which is bit 2 (R-IN2) of the received data, has changed from the open state to the closed state (S416), bit 2 of the next transmission data is set, and the lower cassette size is set when the next data is transmitted. The detection results of the 0 sensor (Q612), the lower cassette size 1 sensor (Q613), the lower cassette size 2 sensor (Q614), and the lower paper presence / absence detection sensor (Q615) are output to R-IN10 to R-IN13. (S417).
[0166]
If the paper feed option connection detection switch (SW505), which is bit 4 (R-IN4) of the received data, detects the presence of the connection (S418), it determines the change in the cassette open / close state of the optional cassette after step S419, and connects. If the absence is detected, the processing after step S423 is executed.
[0167]
When the optional cassette open / close detection upper sensor, which is bit 17 (R-IN17) of the received data, changes from the open state to the closed state (S419), bit 17 of the next transmission data is set, and the optional upper cassette size 0 is set when the next data is transmitted. The detection results of the sensors, the optional upper cassette size 1 sensor, the optional upper cassette size 2 sensor, and the optional upper paper presence / absence detection sensor are output to R-IN22 to R-IN25 (S420).
[0168]
When the optional cassette open / close detection lower sensor, which is bit 18 (R-IN18) of the received data, changes from the open state to the closed state (S421), the bit 18 of the next transmission data is set, and the optional lower cassette size 0 is set when the next data is transmitted. The detection results of the sensor, the optional lower cassette size 1 sensor, the optional lower cassette size 2 sensor, and the optional lower paper presence / absence detection sensor are output to R-IN26 to R-IN29 (S422).
[0169]
Here, when the next transmission data is "0" (S423), it is a case where it is not necessary to detect the state of the sensor B group, and only the data of the sensor A group that has changed is updated and P5VC is turned off. (S424), and the status acquisition / determination process ends. By the processing in step S424, after the status update is completed, control for saving power required for status update is realized, and power consumption can be further reduced.
[0170]
If the next transmission data is other than "0" (S423), this is a case where the state of the sensor B group needs to be detected, and the secondary acquisition and determination processing of the status after step S425 is performed. As described above, in the determination processing in step S423, when the door is detected to be open in step S412 or when there is a change in the opening and closing of the cassette, the data of the sensor B group is collected in conjunction therewith. As a result, status data can be efficiently collected. Conversely, when there is a high possibility that the data of the sensor B group is not necessary, further power saving can be measured without performing status collection based on the sensor B group.
[0171]
First, 32 bits of data are transmitted from the next transmission data described above by outputting 32 clocks clk from SCLK (S425). (At this time, the received data is invalid data and is discarded.) Next, the LOAD signal is set to L (S426), and after waiting for 100 usec (S427), the LOAD signal is set to H (S428). By this operation, the output data of the serial-parallel conversion unit is determined, and the state of the sensor B group is determined as input data of the parallel-parallel conversion unit. Then, 32 clocks clk are output again from SCLK, and the state of the sensor B group is acquired by receiving 32 bits of data (S429).
[0172]
At this time, the transmitted data is invalid because the LOAD signal is not turned ON / OFF.
[0173]
Next, of the received data, only valid data is updated (S430), and the processing from step S424 is performed, and the status acquisition / determination processing ends.
[0174]
The valid data is the received data bit5 when bit0 of the data transmitted in step S429 is 1, and the received data bit6 to 9 when bit1 of the transmitted data is 1 and transmitted. When bit 2 of the data is 1, bits 10 to 13 are used. When bit 17 of the transmitted data is 1, bits 22 to 25 of the received data are used. When bit 18 of the transmitted data is 1, bit 26 of the received data is used. To 29, and all other data are invalid data.
[0175]
In this flowchart, the DCON and the status acquisition / determination operation from the sheet feeding unit have been described. However, the status of the sensor D group (217) and the sensor E group (218) can be changed for the RCON in the same manner. It has an acquisition / judgment function. When the status acquisition / judgment is performed from the DCON or the sheet feeding unit, the status acquisition / judgment from the RCON is also executed at the same time.
[0176]
As described above, according to the flowcharts of FIGS. 13 and 14, P5VA necessary for detecting a predetermined signal from the outside including the sub CPU is always energized, and at the same time, image formation (laser-related 212 and the like) and paper supply drive (supply) are performed. P5VB necessary for driving the paper option 213) can be shifted to a power saving state.
[0177]
As described above, according to the present embodiment, in an image forming apparatus such as a digital multifunction peripheral, a copier, and a printer that can be connected to a network, further power saving can be realized as compared with the related art, and an external device can be used. Can now respond to updated status requests.
[0178]
Further, in an image forming apparatus such as a digital multi-function peripheral, a copier, and a printer having a plurality of various sensors, a status response to an external device can be performed by a sub CPU that consumes less power than the main CPU. .
[0179]
[Second embodiment]
In the first embodiment, when the status of the copying machine is requested from the network during sleep, the sub CPU (one-chip microcomputer Q702) transmits status information to the external device instead of the main CPU (main chip Q701). Although the configuration has been described, the sub CPU transmits status information to the proxy server (server 102) only when the state changes during sleep, and when the status of the copying machine is requested from the network, the sub CPU May not be responded, and the proxy server may respond. Hereinafter, the embodiment will be described.
[0180]
FIG. 15 is a diagram illustrating a detailed configuration of the controller 202 according to the second embodiment of the present invention, and the same components as those in FIG. 7 are denoted by the same reference numerals. Hereinafter, only the configuration different from the first embodiment will be described, and the description of the same configuration will be omitted.
[0181]
In FIG. 15, reference numeral 714 denotes a wakeup signal. The wakeup signal 714 is a signal output from the LAN-UNIT 207 to the main chip Q701 when the LAN-UNIT 207 recognizes an IP address, decodes an IP packet, and further recognizes a “wakeup command”.
[0182]
Further, as described above, in the present embodiment, even during sleep, the one-chip microcomputer Q702 does not send a command response or status information to the LAN-UNIT 207 instead of the main chip Q701, and simply executes the RCON 216 in the sleep state. The configuration is such that the sensor signal of the DCON 201 is monitored, and the sleep return signal from the FAX-UNIT 206 or the LAN-UNIT 207 is monitored.
[0183]
In the present embodiment, P5VA, P5VB, and P5VC in FIGS. 3 to 10 are power-controlled according to the flowcharts in FIGS.
[0184]
When the main chip Q701 is operating normally, similarly to the first embodiment, when a command for requesting the status of the digital multifunction peripheral of the present embodiment is detected via the LAN-UNIT 207, a status request is issued. Is transmitted from the LAN-UNIT IF circuit 702 to the main chip Q701, and the necessary status held by the main chip Q701 in the storage unit (RAM) is transmitted from the main chip Q701 to the LAN-UNIT IF circuit 702. The UNIT IF circuit 702 sends this information to the LAN-UNIT 207 via the IF-10.
[0185]
When a print job comes from a PC on the network, a command to request printing is transmitted from the LAN-UNIT IF circuit 702 to the main chip Q701, and when printing is possible, a response of print OK is sent from the main chip Q701. The information is transmitted to the LAN-UNIT IF circuit 702, and the LAN-UNIT IF circuit 702 sends this information to the LAN-UNIT 207 via the IF-10.
[0186]
When a PC (information processing device) on the network receives this response, the print data is subsequently transmitted. Therefore, with the same signal flow, the print data is input to the main chip Q701, and the necessary image is transmitted from the main chip Q701. After being subjected to the processing, it is temporarily stored in the RAM. Then, the image data is sent to the DCON 201 as an image signal of IF-1 and recorded in the same manner as the processing at the time of image recording.
[0187]
The above is a case where the main chip Q701 is operating normally, and the operation during sleep is slightly different from the above operation.
[0188]
During sleep, as shown in FIG. 16 described later, the exchange of commands with the network is performed by the proxy server. This proxy server is located on the same workstation as the network server 102 shown in FIG. 1, and receives a “proxy request command” from the digital multi-function peripherals 101a and 101b of the present embodiment, thereby transmitting digital data transmitted from the PCs 103a and 103b. It responds to commands to the addresses of the multifunction peripherals 101a and 101b on behalf of the digital multifunction peripherals 101a and 101b.
[0189]
It is assumed that the addresses and status information of the digital multifunction peripherals 101a and 101b have been sent to the proxy server 102 together with the proxy request command. However, when the status of the digital multifunction peripherals 101a and 101b of the present embodiment changes, the digital multifunction peripherals 101a and 101b notify the status to the proxy server.
[0190]
At the time of sleep, the main chip Q701 is in a sleep state and cannot transmit / receive a signal. Therefore, the one-chip microcomputer Q702 receives and monitors status information from the IF circuit 706 with RCON and the IF circuit 701 with DCON. are doing.
[0191]
As described in a separate figure (flow chart), when there is a change in the status, the one-chip microcomputer Q702 issues the interrupt signal NMI709 to the main chip Q701, as described above, to temporarily return the main chip from the sleep state.
[0192]
When the return of the main chip is confirmed by the Activec signal 711, the one-chip microcomputer Q702 transmits status information to the main chip Q701 by serial communication 710. Upon receiving the status information, the main chip Q701 sends an instruction to send the status to the proxy server 102 and status data to the LAN-UNITIF circuit 702, and the LAN-UNITIF circuit 702 sends this to the LAN-UNIT207. , The LAN-UNIT 207 transmits a new status to the proxy server 102, and the status information of the digital multifunction peripherals 101a and 101b inside the proxy server 102 is updated. If the digital multifunction peripherals 101a and 101b return from sleep due to a change in status during sleep, the digital multifunction peripherals 101a and 101b return to the sleep state again after transmitting a status update command to the proxy server 102.
[0193]
When the digital copiers 101a and 101b go out of sleep due to a print job to the digital copiers 101a and 101b during sleep or the like, a wakeup command is sent from the proxy server 102 to the LAN-UNIT 207. Upon recognizing the wakeup command, the LAN-UNIT 207 sends a wakeup signal 714 to the LAN-UNITIF circuit 702, and the LAN-UNITIF circuit 702 that has received the wakeup signal 714 converts the wakeup signal 714 into the one-chip microcomputer Q702 and the main chip Q701. To send to.
[0194]
When the one-chip microcomputer Q702 receives the wakeup signal 714, the power supply is turned on in the same manner as when the FAX start signal 713 is received from the IF circuit 703 with the FAX-UNIT 206, as will be described with reference to a separate figure (flow chart). And returning the main controller from sleep to a state where it can respond to a command from the FAX-UNIT 206. Specifically, the one-chip microcomputer Q702 issues an instruction to the power supply control IF circuit 705 to start up the power that has been dropped during sleep, and the power supply control IF circuit 705 sends a power-on signal to the DC power supply 203. Send out. On the other hand, an interrupt signal NMI 709 is output to the main chip Q701, and the main chip Q701 having received the NMI 709 shifts from the sleep state to the normal state as described with reference to another diagram (flow chart).
[0195]
Here, a configuration is described in which the wakeup signal 714 is input to both the one-chip microcomputer Q702 and the main chip Q701. However, the wakeup signal is input only to the one-chip microcomputer Q702, and the one-chip microcomputer Q702 transmits the serial communication 710. May be transmitted to the main chip Q701 by the Wakeup signal 714 from the LAN-UNIT 207.
[0196]
Hereinafter, commands and responses between the digital multifunction peripheral and the proxy server and the PC on the network in the sleep mode according to the present embodiment will be described with reference to FIG.
[0197]
FIG. 16 is a schematic diagram showing the exchange of command responses between the PCs 103a and 103b and the digital multifunction peripherals 101a and 101b on the network 104 including the proxy server 102 shown in FIG.
[0198]
In normal times, when a command for acquiring the status of the digital multifunction peripherals 101a and 101b and a command 1501 such as a print request are issued from the PCs 103a and 103b to the digital multifunction peripherals 101a and 101b, the digital multifunction peripherals 101a and 101b respond thereto. Returns a response 1502.
[0199]
When the digital multifunction peripherals 101a and 101b shift to the sleep state, in the present embodiment, the digital multifunction peripherals are basically connected to the network 104. Since a proxy reception response is not issued, a proxy request command 1503 is issued to the server 102 when shifting to sleep. At this time, status information (sensor information and the like) of the digital multifunction peripherals 101a and 101b is sent to the server 102 together with the command.
[0200]
When the server 102 receives the proxy request command 1503 and holds the status information of the digital multi-function peripheral in a storage device (not shown) and is ready to operate as a proxy server, the server 102 performs a proxy for the digital multi-function peripherals 101a and 101b. A reception response 1504 is returned. Upon receiving the proxy reception response 1504, the digital multifunction peripherals 101a and 101b enter a sleep state. Thereafter, the digital multifunction peripherals 101a and 101b do not respond to the command 1505 for the digital multifunction peripherals 101a and 101b. (Response 1506).
[0201]
If there is a change in the status of the digital multifunction peripherals 101a and 101b during sleep, the digital multifunction peripherals 101a and 101b temporarily return from sleep and send a new status together with the status update command 1507 to the proxy server 102. Upon receiving this, the proxy server 102 updates the status information of the digital multi-function peripheral held in the storage device (not shown), and returns a status update response 1508 to the digital multi-function peripherals 101a and 101b when the status update is completed. The digital multifunction peripherals 101a and 101b enter the sleep state again.
[0202]
Also, if the proxy server 102 receives a command 1509 that requires the digital MFPs 101a and 101b to operate, such as a print request to the digital MFPs 101a and 101b during sleep, the proxy server 102 performs A wakeup command 1510 is sent to the multifunction peripherals 101a and 101b.
[0203]
Upon receiving the wakeup command 1510, the digital multifunction peripherals 101a and 101b return from the sleep state by this command and become ready to receive a command from the network 104, and return a wakeup response 1511 to the proxy server 102. The proxy server 102 that has received the wakeup response 1511 returns a resend request response 1512 of the previous command to the requesting PC. This is because the digital multifunction peripherals 101a and 101b receive a command such as a print request.
[0204]
The PCs 103a and 103b issue a print request command 1513 to the digital multifunction peripherals 101a and 101b again. In response, the digital multifunction peripherals 101a and 101b return a print acceptance response 1514 to the PCs 103a and 103b, and the PCs 103a and 103b perform printing. The data 1515 is sent to the digital multifunction peripherals 101a and 101b. Thereafter, normal print jobs are exchanged.
[0205]
Although FIG. 16 illustrates a general command as an example to briefly explain the operation of the present invention, the timing and contents of the command and response are not limited to this.
[0206]
In the above configuration, the transition to the power saving sleep state, the return to the normal state, the status monitoring of the DCON 201 and the RCON 216 in the sleep state, and the status transmission to the proxy server 102 are performed by the one-chip microcomputer Q702 (hereinafter, sub- CPU) and a main chip Q701 (hereinafter, main CPU). Hereinafter, these operations will be described with reference to the flowcharts of FIGS.
[0207]
FIGS. 17 and 18 are flowcharts showing an example of the fourth control procedure in the image forming apparatus according to the present invention, which corresponds to the operation procedure of the sub CPU based on a program stored in a ROM or other storage medium (not shown). I do. In addition, S1201 to S1219 indicate each step.
[0208]
The sub CPU is connected to the DC power supply P5VA and operates at all times, and the operation is roughly classified into a sleep state in which the main CPU is in the HALT state and a normal state in which the main CPU operates normally. First, the normal state will be described.
[0209]
It is determined whether the ACTIVE signal 711 from the main CPU is in the ON state. If the ACTIVE signal 711 is in the ON state (Yes in S1201), it is in the normal state, and the status of the DCON 201 and RCON 216 is received from the main CPU (S1202). The operation of monitoring the switch 223 is repeated (S1203).
[0210]
Here, if it is determined that the power switch 223 has been pressed, a system down request (SYSTEM DOWN) is transmitted to the main CPU to shift the entire system to the power saving sleep state (S1204). Here, the status reception and the system down request are performed using the serial communication 710 between the sub CPU and the main CPU.
[0211]
On the other hand, when the ACTIVE signal from the main CPU is turned off (No in S1201), the state shifts to the power saving sleep state. Although the reason why the ACTIVE signal is turned off will be described later, when the power saving sleep state is entered, the power supply control IF circuit 705 is first instructed to turn off the power supply P5VB to the DCON 201 and RCON 216 systems (S1205).
[0212]
Next, the status monitoring timers of the DCON 201 and the RCON 216 are started (S1206). This timer is a timer for measuring an interval for acquiring the status, and in this embodiment, measures 100 msec.
[0213]
Until the time of 100 msec is counted, monitoring of whether there is a FAX job request (S1207), whether there is a print job request (S1208), or whether the power switch is pressed (S1209) is repeated, and if there is a job request. When the power switch is pressed (Yes in S1207 and S1208) and when the power switch is pressed (Yes in S1209), the power control IF circuit 705 is instructed to turn on the power supply P5VB to the DCON 201 and the RCON 216 (S1210), and the main CPU start signal 709 is issued. Is turned on (S1211), and after waiting for the activation of the main CPU (ACTIVE signal ON) (S1219), the process returns to step S1201 and shifts to the normal state.
[0214]
The presence or absence of a FAX job in step S1207 is determined based on the CI detection signal and the off-hook detection signal supplied from the FAX-UNIT-IF circuit 703 described above. The presence / absence of a print job is determined by the wakeup signal supplied from the LAN-UNIT-IF circuit 702 described above.
[0215]
Further, the processing from step S1207 is repeated until the status monitoring timer measures 100 msec (S1212), and when the status monitoring timer measures 100 msec (Yes in S1212), the status is acquired from the DCON 201 and RCON 216 (S1213). Details of this status acquisition operation will be described later with reference to FIGS.
[0216]
In this status acquisition operation, the status received from DCON and RCON is compared with the status previously received from the main CPU in step S1202 (the status immediately before shifting to the power saving sleep state), and it is determined whether there is any change. (S1214). Here, if it is determined that there is no change (No in S1214), the process returns to step S1206, and periodic status reception, job request, and monitoring of the power switch are repeated.
[0217]
On the other hand, if it is determined in step S1214 that the status has changed (Yes in S1214), the main CPU activation signal 709 is turned on (S1215), and then the main CPU is activated (ACTIVE signal ON) (S1216). ), The statuses received from DCON and RCON are transmitted to the main CPU (S1217), and a request to shift to the HALT state is issued as the next operation instruction to the main CPU (S1218), and the process returns to step S1201 and again. Wait for the main CPU to transition to the power saving sleep state (Active signal OFF). The transmission of the status and the request to shift to the HALT state are performed using serial communication (710) between the sub CPU and the main CPU.
[0218]
As described above, according to the flowcharts of FIGS. 17 and 18, the power of the P5VB is conserved unless processing such as during processing related to image formation / pressing of the power switch is detected. The status transmitted to the proxy server 102 is updated in accordance with the processing in step S1217, and power saving is also performed in the status processing in step S1217.
[0219]
FIG. 19 is a flowchart illustrating an example of a fifth control procedure in the image forming apparatus according to the present invention, and corresponds to an operation procedure of the main CPU based on a program stored in a ROM or another storage medium (not shown). In addition, S1301 to S1324 indicate each step.
[0220]
Like the sub CPU, the main CPU is always connected to the DC power supply P5VA and operates at all times. The main CPU includes a sleep state in which the CPU clock (X701) is stopped, a facsimile transmission, a facsimile transmission, and a print operation. All operations of this system, such as a scanning operation and a status inquiry response from an external device, are roughly classified into a normal state in which all operations can be performed.
[0221]
When the main CPU enters the normal state (from the HALT state), first, the ACTIVE signal 711 is turned on (S1301). As described above, this operation causes the sub CPU to enter the normal state. Next, the status of DCON and RCON in the HALT state is received from the sub CPU (S1302). Here, it is determined whether there is a HALT request from the sub CPU (S1303). If there is a HALT request from the sub CPU, it is determined that a status change has occurred in DCON or RCON during the power saving sleep state. The CPU detects it, determines that the main CPU has been started, and performs a transition process to a power saving sleep state from step S1318 described later.
[0222]
On the other hand, if there is no HALT request in step S1303, as described above, the sub CPU detects a power switch press or a FAX / print request, and determines that the main CPU has been activated. Perform processing.
[0223]
First, the sleep signal 712 is turned off (S1304). As described above, by this operation, in the controller, in the DCON-IF circuit 701 and the RCON-IF circuit 706, the serial communication IF with the DCON 201 and RCON 216 is switched from the sub CPU to the main CPU.
[0224]
Also in the DCON 201 and the RCON 216, the sleep state of the DCON microcomputer Q301 and the RCON microcomputer Q901 is released at the same time as the serial communication IF is switched from the hardware configuration to the DCON microcomputer Q301 and the RCON microcomputer Q901.
[0225]
Next, the power saving sleep transition timer is started (S1305). This timer measures the time from the normal state to the transition to the power saving sleep state again. In the present embodiment, the timer measures one hour. Until one hour is counted, statuses are received from the DCON 201 and the RCON 216 (S1306), whether there is a system down request from the sub CPU (S1307), whether there is a FAX job request (S1308), or a print job request. (S1309), whether there is a job request from the DCON microcomputer Q301 (S1310), whether there is a job request from the RCON microcomputer Q901 (S1311), or whether there is a status inquiry response job request from an external device (S1312). .
[0226]
If there is a system down request (Yes in S1307), a power-off notice is transmitted to DCON and RCON via the serial communication IF (S1316), and reception of a power-off permission response from DCON 201 and RCON 216 is waited. (S1317).
[0227]
When a power-off permission response is received from both the DCON and the RCON microcomputer, a transition process to a power saving sleep state from step S1316 described later is performed. The DCON and RCON microcomputers are configured to perform predetermined power-off processing upon receiving a power-off notice, and transmit a power-off permission to the main CPU upon completion.
[0228]
On the other hand, if there is a job request (Yes in any of steps S1308 to S1312), a predetermined job is executed (S1313), the power saving sleep transition timer is set to one hour again, and restarted (S1314). The process returns to step S1306.
[0229]
The presence or absence of the FAX job is determined based on the CI detection signal and the off-hook detection signal supplied from the FAX-UNIT-IF circuit 703 or the command received from the sub CPU in step S1302. The presence / absence of a print job is determined based on the weak signal supplied from the LAN-UNIT-IF circuit 702 described above, and a wakeup response and a print acceptance response are supplied to the LAN-UNIT-IF circuit 702 prior to execution of the job. . Job requests from DCON and RCON are received by respective serial communication IFs. The job can be executed by any general method, and a detailed description thereof will be omitted.
[0230]
On the other hand, when the power saving sleep transition timer measures one hour, that is, when one hour has passed without any job being executed (Yes in S1315), the system in and after step S1316 changes to the power saving sleep state by itself. A down process and a process of shifting to a power saving sleep state after step S1318 are performed.
[0231]
Next, processing for shifting to the power saving sleep state after step S1318 will be described. As described above, when the HALT request is issued from the sub CPU (Yes in S1303), or when the system down request is issued from the sub CPU (Yes in S1307), or when the power saving sleep transition timer determines that the main CPU The process for shifting to the power saving sleep state, which is executed when shifting to the power saving sleep state (Yes in S1315), firstly performs a status transmission process to the proxy server 102 (S1318). In the status transmission process, transmission of the proxy request command 1503 (FIG. 16) to the proxy server 102, reception of the proxy reception response 1504, and transmission of the DCON and RCON status are executed in a series of processes. The status of DCON and RCON transmitted here is the status received from the sub CPU in step S1302 when the cause is the HALT request factor, and otherwise, the status of the DCON microcomputer is determined in step S1306. , The latest status received from the RCON microcomputer.
[0232]
Next, the same DCON and RCON status is transmitted to the sub CPU (S1319). As described above, after the sub CPU shifts to the power saving sleep state, the status becomes a reference status for determining whether or not the status has changed.
[0233]
Next, the sleep signal 712 is turned on (S1320). As described above, in the controller, the serial communication IF for DCON and RCON is switched from the main CPU to the sub CPU in the DCON-IF circuit 701 and the RCON-IF circuit 706 in the controller. Also in DCON and RCON, the serial communication IF switches from the DCON microcomputer Q301 and the RCON microcomputer Q901 to a hardware configuration, and at the same time, the DCON microcomputer and the RCON microcomputer enter a sleep state.
[0234]
Next, the ACTIVE signal 711 is turned off (S1321). As described above, this operation causes the sub CPU to enter the power saving sleep state.
[0235]
Next, the main CPU itself is set to the HALT state in which the CPU clock (X701) is stopped, and the transition to the power saving sleep state is completed (S1322). This state continues until an interrupt is generated by the main CPU activation signal 709 supplied from the sub CPU. When an interrupt occurs (S1323), the HALT state is released (S1324), and the process proceeds to step S1301 in the normal state. I do.
[0236]
Hereinafter, the operation of the sub CPU acquiring the status from DCON during the power saving sleep will be described with reference to the flowcharts of FIGS.
[0237]
20 to 22 are flowcharts showing an example of a sixth control procedure in the image forming apparatus according to the present invention. The operation procedure of the sub CPU based on a program stored in a ROM (not shown) or another storage medium (FIG. 17 (a detailed procedure of the status acquisition processing procedure of step S1213). In addition, S1401 to S1444 indicate each step.
[0238]
First, P5VC is turned on in order to enable the DCON and the hardware serial communication block of the sheet feeding unit to operate (S1401).
[0239]
Next, the LOAD signal is set to L (S1402), and after waiting 100 sec until the input data of the parallel-serial conversion unit Q302 becomes stable (S1403), the LOAD signal is set to H to determine the input data of the parallel-serial conversion unit (S1404).
[0240]
Next, the transmission data “0000 (Hex)” is set so that the energization of the sensor B group 209 and the sensor G group is turned off (S1405), and 32 clocks clk are output from SCLK, whereby the 32-bit data is output. Data is transmitted and received (S1406). At this time, the transmission data “0000 (hex)” is transmitted to the serial-parallel conversion unit Q303 via SDATA_C2D, and the data of R-IN31 to R-IN0 is received from the parallel-serial conversion unit Q302 via SDATA_D2C. However, R-IN5 to R-IN16 and R-IN19 to R-IN31 received at this time are invalid data. If the paper feed unit is not connected, the upper 16 bits of the transmission / reception data become invalid data.
[0241]
Next, the LOAD signal is set to L (S1407), and after waiting 100 sec (S1408), the LOAD signal is set to H, and the output data of the serial-parallel conversion unit Q303 is determined (S1409). Here, the next transmission data, which is a register for checking a status change, is cleared to 0 and initialized (S1410), and a change flag indicating the presence or absence of a change is initialized to OFF (S1411).
[0242]
Next, the received statuses of the sensor A group and the sensor G group are compared with the acquired latest status.
[0243]
If the door open / close detection switch (SW501), which is bit0 (R-IN0) of the received data, is changing (Yes in S1412), the change flag is turned on (S1413). If the door open / close detection switch (SW501) is in the open state (Yes in S1414), bit0 of the next transmission data is set (the setting here indicates setting from "0" to "1"). Then, the detection result of the cartridge detection (Q607) is output to the R-IN5 when the next data is transmitted (S1415).
[0244]
If the cassette open / close detection upper switch (SW502), which is bit 1 (R-IN1) of the received data, has changed (Yes in S1416), the change flag is turned on (S1417). Further, when the cassette open / close detection upper switch (SW502) changes from the open state to the closed state (Yes in S1418), bit1 of the next transmission data is set, and when the next data is transmitted, the upper cassette size 0 sensor (Q608) and the upper The detection results of the cassette size 1 sensor (Q609), the upper cassette size 2 sensor (Q610), and the upper paper presence / absence detection sensor (Q611) are output to R-IN6 to R-IN9 (S1419).
[0245]
If the cassette open / close detection lower switch (SW503), which is bit2 (R-IN2) of the received data, has changed (Yes in S1420), the change flag is turned on (S1421). Further, when the cassette open / close detection lower switch (SW503) changes from the open state to the closed state (Yes in S1422), bit2 of the next transmission data is set, and the lower cassette size 0 sensor (Q612) and the lower The detection results of the cassette size 1 sensor (Q613), the lower cassette size 2 sensor (Q614), and the lower paper presence / absence detection sensor (Q615) are output to R-IN10 to R-IN13 (S1423).
[0246]
Next, when the paper discharge option connection detection switch (SW504), which is bit 3 (R-IN3) of the received data, is changed (Yes in S1424), the change flag is turned on (S425).
[0247]
If the feed option connection detection switch (SW505), which is bit 4 (R-IN4) of the received data, has changed (Yes in S1426), the change flag is turned on (S1427).
[0248]
Further, when the paper feed option connection detection switch (SW505) detects the presence of the connection (Yes in S1428), the change of the cassette open / close state of the optional cassette after step S1429 is determined, and the absence of the connection is detected. If there is (No in step S1428), the processing from step S1437 is executed.
[0249]
In step S1429, if the option cassette opening / closing detection upper stage, which is bit17 (R-IN17) of the received data, is changed (Yes in S1429), the change presence flag is turned on (S1430). Further, when the upper part of the optional cassette open / closed detection changes from the open state to the closed state (Yes in S1431), the bit 17 of the next transmission data is set, and the optional upper cassette size 0, the optional upper cassette size 1, the optional The detection result of the upper cassette size 2, the optional upper-stage paper presence / absence detection is output to R-IN22 to R-IN25 (S1432).
[0250]
Next, when the lower part of the option cassette open / close detection, which is bit18 (R-IN18) of the received data, has changed (Yes in S1433), the change flag is turned ON (S1434). Further, when the lower position of the optional cassette open / closed detection changes from the open state to the closed state (S1435), the bit 18 of the next transmission data is set, and at the time of next data transmission, the optional lower cassette size 0, the optional lower cassette size 1, and the optional lower cassette 1 are set. The detection result of the size 2, optional lower paper presence / absence detection is output to R-IN26 to R-IN29 (S1436), and the process proceeds to step S1437.
[0251]
In step S1437, when the next transmission data is “0” (Yes in S1437), it is not necessary to detect the state of the sensor B group and the sensor H group, and the changed sensor A group and sensor G group Is updated, P5VC is turned off (S1438), and the status acquisition / determination process ends.
[0252]
On the other hand, if the next transmission data is other than “0” (No in S1437), this is a case where it is necessary to detect the states of the sensor B group and the sensor H group, and the secondary acquisition and determination processing of the status after step S1439 I do.
[0253]
First, 32 bits of data are transmitted from the next transmission data by outputting 32 clocks clk from SCLK (S1439). At this time, the received data is invalid data and is discarded. Next, the LOAD signal is set to L (S1440), and after waiting 100 sec (S1441), the LOAD signal is set to H (S1442). By this operation, the output data of the serial-parallel conversion unit is determined, and the state of the sensor B group is determined as input data of the parallel-parallel conversion unit. Then, 32 clocks clk are output again from SCLK, and 32-bit data is received (S1443) to acquire the state of the sensor B group. At this time, the transmitted data is invalid because the LOAD signal is not turned ON / OFF.
[0254]
Next, of the received data, only valid data is updated (S1444), the processing after step S1438 is performed, and the status acquisition / determination processing ends.
[0255]
The valid data is the received data bit5 when bit0 of the data transmitted in step S1439 is “1”, and is the received data bit6 to 9 when bit1 of the transmitted data is “1”. When bit 2 of the transmitted data is “1”, bits 10 to 13 are used. When bit 17 of the transmitted data is “1”, bits 22 to 25 of the received data are used. In the case of "1", the received data are bits 26 to 29, and all other data are invalid data.
[0256]
Note that the change presence flag described in this flowchart is used to determine whether or not there is a status change in the sub CPU in step S1214 in FIG. 17 described above.
[0257]
In this flowchart, the DCON and the status acquisition / determination operation from the sheet feeding unit have been described. However, the status of the sensor D group 217 and the sensor E group 218 is acquired and determined for the RCON in the same manner. It has a function, and when performing status acquisition / determination from the DCON and the paper feed unit, status acquisition / determination from the RCON is also performed at any time.
[0258]
Further, in step S1414, when the door open / close detection switch (SW501) is open, in step S1418, the cassette open / close detection upper switch (SW502) changes from the open state to the closed state, and in step S1422, the cassette open / close detection lower switch (SW502). When the switch SW503 changes from the open state to the closed state, a bit of the next transmission data is set to control to turn on the power of the sensor B group. However, the door open / close detection switch (SW501), the cassette open / close When certain states such as the open state of the detection upper switch (SW502) and the cassette open / close detection lower switch (SW503) continue, the bit of the next transmission data is turned off, and the power of a part or all of the sensor B group is turned off. It may be configured to be turned off.
[0259]
As described above, the present invention relates to energy saving of printers, copiers, and multifunction peripherals, and more particularly to a system and control method for reducing standby power of printers, copiers, and multifunction peripherals in a network environment. In the network system shown in the present embodiment, when the status of the image forming apparatus is inquired from the network when the image forming apparatuses such as the digital multifunction peripherals 101a and 101b are in the energy saving mode, the proxy server (server 102) responds by proxy. On the other hand, the image forming apparatus in the energy saving mode notifies the proxy server of the status information only when the status of the image forming apparatus changes. Thus, even if the image forming apparatus is in an energy saving mode such as a sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[0260]
Conventionally, since the network side cannot detect when the status of the image forming apparatus such as a copying machine changes, the image forming apparatus has to be frequently asked for the status of the image forming apparatus. In spite of the energy saving state of the sleep state, the status status is inquired to the image forming apparatus, and every time the power supply must be supplied to the entire image forming apparatus. Although there was a problem that the effect was reversed, the network system of the present embodiment consumes a large amount of power by supplying power to the entire image forming apparatus every time the status of the conventional image forming apparatus is heard. To the network side with the minimum necessary power only when the status of the image forming apparatus changes. It has a configuration that notifies the Tasu information. This eliminates the need for the network to frequently ask for the status of the copier, and as a result, it is not necessary to supply power to the entire image forming apparatus every time the status is heard. Thereby, an effect of reducing power consumption can be obtained.
[0261]
Further, in the present embodiment, in the energy saving mode, the main CPU that consumes a large amount of power is set to a sleep state that does not respond to the network, and the main CPU is returned from the sleep state only when there is a change in the status of the image forming apparatus. A reduction in power can be realized.
[0262]
Further, the power consumption is further reduced by stopping the operation of the main CPU and putting it into a sleep state, and allowing the sub CPU having low power consumption to recognize the status of the digital multifunction peripheral in place of the main CPU having high power consumption. .
[0263]
In addition, when the status of the digital multi-function peripheral changes during the energy saving mode, the main CPU is woken up and the status information received by the sub CPU is transferred to the main CPU so that the status information changed by the main CPU can be transmitted to the network. , And low power consumption can be realized.
[0264]
Further, when there is a startup request (Wakeup command) from the network during the energy saving mode, the main CPU is woken up to put the image forming apparatus in a normal state, and it is possible to respond to a print request even during the energy saving mode, and at the same time, to reduce the power consumption. Power can be realized.
[0265]
Therefore, even if the image forming apparatus is in the sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[0266]
Further, according to the present embodiment, in the low power consumption mode, the communication destination of the status group is switched to the sub CPU that consumes relatively less power than the main CPU, so that the image forming apparatus is in the sleep state. Even if a response to the status heard from the network is made, it can be realized with as little energy as possible and at low cost.
[0267]
Further, according to the present embodiment, when the mode shifts from the normal mode to the low power consumption mode, the status information of the sub CPU is transferred to the main CPU, and when the mode shifts from the low power consumption mode to the normal mode, the main CPU transfers the status information. By transferring the held status information to the sub CPU, it is possible to quickly switch to a mode while maintaining accurate status information, and to reply to the status heard from the network even when the image forming apparatus is in the sleep state. In this case, it can be realized with as little energy as possible and at low cost.
[0268]
Except during sleep, the DCON sends the status from the controller to the controller by serial communication in response to a command indicating the status inquiry from the controller to the DCON by serial communication. Serial communication is dedicated to status communication without exchanging commands to DCON, so there is no need to create commands for the controller or judge DCON commands. It is possible to save power. As described above, even when the image forming apparatus is in the sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[0269]
Further, except during the sleep mode, the communication between the DCON and the controller is an asynchronous communication that does not require a transfer clock, which contributes to reduction of radiation noise and saving of IC terminals. In order to match, the frequency of the internal operation clock needs to be several times the transfer clock. On the other hand, at the time of sleep, by setting the transfer clock to the synchronous communication generated by one side, the circuit on the side that does not generate the transfer clock operates with the operation clock having the same frequency as the transfer clock. In this configuration, the energy consumption is generally proportional to the operation clock, so that the power consumption during sleep is reduced. In this way, even if the image forming apparatus is in the sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[0270]
Even when the image forming apparatus is in the sleep state, a plurality of sensors (SW501 to SW505, SW1002 to SW1003 of the sensor group A) for detecting the status group of the printer unit when responding to the status heard from the network. Q607 to Q615, Q1108 to Q1115 of the sensor group B), a microcomputer Q301 connected to each of the sensors and controlling the printer unit, and a parallel-to-serial conversion unit Q302 for receiving the output of each of the sensors and converting the output to serial. And a controller 202 for controlling the entire image forming apparatus. In the energy saving mode, the microcomputer Q301 is turned off, and the microcomputer Q301 notifies the controller 202 of the status group of the printer. By notifying 202 It is possible to realize a status notification of the printer portion during sleep as much as possible less energy.
[0271]
Even when the image forming apparatus is in the sleep state, when responding to the status heard from the network, a minimum necessary portion (a sensor group A for detecting a certain status such as a front door SW or the presence or absence of a cassette, etc.) ), And then power on a limited portion (sensor group B, etc.) to obtain a required status such as paper size, so that acquisition of status information during sleep is minimized by energy (power consumption). ) And at low cost.
[0272]
Further, when there is a change in the minimum required detection portion, power is supplied to the details from that state.
[0273]
Furthermore, when energizing only the minimum necessary detection portion (sensor group A etc.), ON / OFF energization is intermittently applied to the minimum necessary detection portion.
[0274]
Further, when there is a change in the predetermined direction in the minimum necessary detection portion, power is supplied to the detailed detection portion from that state.
[0275]
Further, when a continuous state continues to the minimum necessary detection part, power is supplied to the detection part in detail from that state.
[0276]
Also, the detection result of the minimum necessary detection part (sensor group A etc.) is converted into parallel / serial by the serial-parallel conversion unit Q302, and after being transferred to the controller 202, there is a change in the information obtained from the parallel-serial conversion unit Q302. In this case, power is supplied to the details (sensor group B, etc.) from that state.
[0277]
As described above, even when the image forming apparatus is in the sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[0278]
[Third embodiment]
In the first and second embodiments, as shown in FIG. 7, the sub CPU (one-chip microcomputer Q702) and the main chip Q701 have been described as physically separate pairs. However, the present invention is not limited to this. Rather, the mode in which a predetermined chip (CPU) operates with a high-frequency clock and the mode in which it operates with a low-frequency clock correspond to a main chip and a sub chip, respectively, and save local power in a predetermined chip. It is also assumed that the mode for driving the chip with low power consumption corresponds to a sub-chip.
[0279]
In addition, all configurations obtained by combining the above embodiments are also included in the present invention.
[0280]
Hereinafter, the configuration of a data processing program readable by the image forming apparatus according to the present invention will be described with reference to a memory map shown in FIG.
[0281]
FIG. 23 is a diagram illustrating a memory map of a storage medium that stores various data processing programs that can be read by the image forming apparatus according to the present invention.
[0282]
Although not shown, information for managing a group of programs stored in the storage medium, for example, version information, a creator, and the like are also stored, and information dependent on the OS or the like on the program reading side, for example, a program is identified and displayed. Icons and the like may also be stored.
[0283]
The functions shown in FIG. 11, FIG. 12, FIG. 13 to FIG. 14, FIG. 17 to FIG. 18, FIG. 19, and FIG. Good. In this case, the present invention is applied even when a group of information including a program is supplied to the output device from a storage medium such as a CD-ROM, a flash memory, or an FD, or from an external storage medium via a network. Things.
[0284]
As described above, the storage medium storing the program codes of the software for realizing the functions of the above-described embodiments is supplied to the system or the apparatus, and the computer (or CPU or MPU) of the system or the apparatus stores the storage medium in the storage medium. It goes without saying that the object of the present invention is also achieved by reading and executing the program code thus obtained.
[0285]
In this case, the program code itself read from the storage medium implements the novel function of the present invention, and the storage medium storing the program code constitutes the present invention.
[0286]
As a storage medium for supplying the program code, for example, a flexible disk, hard disk, optical disk, magneto-optical disk, CD-ROM, CD-R, magnetic tape, nonvolatile memory card, ROM, EEPROM, or the like may be used. it can.
[0287]
When the computer executes the readout program code, not only the functions of the above-described embodiments are realized, but also an OS (Operating System) running on the computer based on the instruction of the program code. It goes without saying that a part or all of the actual processing is performed and the functions of the above-described embodiments are realized by the processing.
[0288]
Further, after the program code read from the storage medium is written into a memory provided on a function expansion board inserted into the computer or a function expansion unit connected to the computer, the function expansion is performed based on the instruction of the program code. It goes without saying that a CPU or the like provided in the board or the function expansion unit performs part or all of the actual processing, and the processing realizes the functions of the above-described embodiments.
[0289]
Further, the present invention may be applied to a system including a plurality of devices or to an apparatus including a single device. Needless to say, the present invention can be applied to a case where the present invention is achieved by supplying a program to a system or an apparatus. In this case, by reading a storage medium storing a program represented by software for achieving the present invention into the system or the apparatus, the system or the apparatus can enjoy the effects of the present invention. .
[0290]
Further, by downloading and reading out a program represented by software for achieving the present invention from a database on a network by a communication program, the system or apparatus can enjoy the effects of the present invention. .
[0291]
According to the above-described embodiment, even when the digital multifunction peripheral is in the sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[0292]
Further, in the energy saving mode, the power consumption can be reduced by the sub chip responding to the status request from the network in place of the main chip having large power consumption.
[0293]
Further, in the energy saving mode, the main chip is put into a sleep state to stop the operation, and the sub chip recognizes the status and responds to the status request, thereby further reducing power consumption.
[0294]
Also, when a command such as a print request is received during the energy saving mode and the digital multifunction peripheral needs to be returned to the normal mode, the sub chip judges this, wakes up the main chip, and also prints the print request received by the sub chip. By transferring command information to the main chip, low power consumption is realized while command and response on the network are performed without delay.
[0295]
The present invention is not limited to the above embodiments, and various modifications are possible based on the spirit of the present invention, and they are not excluded from the scope of the present invention.
[0296]
Examples of embodiments of the present invention are listed below.
[0297]
[First embodiment]
In an image forming apparatus having a low power consumption mode that consumes less power than in a normal standby mode, an image forming unit (a printer unit (not shown)) that performs image forming processing based on input image data, and a status group of the image forming unit. A plurality of detecting means for detecting (switches SW501 to SW505 shown in FIG. 5 and sensors Q607 to Q615 shown in FIG. 6) and an image forming control means connected to the plurality of detecting means and controlling the image forming means (FIG. DCON 201), main control means (controller 202 shown in FIG. 3) for performing main control of the image forming apparatus, and interface means (serial communication) for connecting the main control means and the image formation control means by serial communication. The microcomputer Q301, the parallel-to-serial conversion unit Q302, the serial-to-parallel conversion unit Q303, and the signal switching circuit Q304 shown in FIG. Q305, Q306, Q308), and the interface means communicates a status group detected by the plurality of detection means in the low power consumption mode, and transmits the plurality of status groups in other than the low power consumption mode. An image forming apparatus wherein a command is communicated in addition to a status group detected by the detecting means.
[0298]
[Second embodiment]
In an image forming apparatus having a low power consumption mode that consumes less power than in a normal standby mode, an image forming unit (a printer unit (not shown)) that performs image forming processing based on input image data, and a status group of the image forming unit. A plurality of detecting means for detecting (switches SW501 to SW505 shown in FIG. 5 and sensors Q607 to Q615 shown in FIG. 6) and an image forming control means connected to the plurality of detecting means and controlling the image forming means (FIG. DCON 201), main control means (controller 202 shown in FIG. 3) for performing main control of the image forming apparatus, and interface means (serial communication) for connecting the main control means and the image formation control means by serial communication. The microcomputer Q301, the parallel-to-serial conversion unit Q302, the serial-to-parallel conversion unit Q303, and the signal switching circuit Q304 shown in FIG. Q305, Q306, Q308), wherein the interface means performs synchronous communication in the low power consumption mode, and performs asynchronous communication in other than the low power consumption mode. Forming equipment.
[0299]
[Third embodiment]
In an image forming apparatus having a low power consumption mode that consumes less power than in a normal standby mode, an image forming unit (printer unit) that performs image forming processing based on input image data and a status group of the image forming unit are detected. A plurality of detecting means (switches SW501 to SW505 shown in FIG. 5 and sensors Q607 to Q615 shown in FIG. 6) and an image forming control means connected to the plurality of detecting means and controlling the image forming means (shown in FIG. 3) A microcomputer Q301), a parallel-to-serial conversion unit that receives outputs of the plurality of detection units and converts the serial data into serial data (a serial-to-parallel conversion unit Q303 illustrated in FIG. 3), and a main control unit that performs main control of the image forming apparatus (see FIG. Controller 201), and the image format detected by the plurality of detection means depending on whether the mode is the low power consumption mode. Switching means (signal switching circuits Q304, Q305, Q306, Q308 shown in FIG. 3) for switching the notification source of the status group of the means to the main control means to the parallel-serial conversion means or the image formation control means. Characteristic image forming apparatus.
[0300]
[Fourth embodiment]
The switching means (the signal switching circuits Q304, Q305, Q306, and Q308 shown in FIG. 3), in the low power consumption mode, transmits a status group of the image forming means detected by the plurality of detecting means from the parallel-serial conversion means. The image forming control unit notifies the main control unit of a status group of the image forming unit detected by the plurality of detecting units in a time other than the low power consumption mode. The image forming apparatus according to the third embodiment, wherein a notification source to the main control unit is switched.
[0301]
[Fifth embodiment]
An image forming unit that has a low power consumption mode that consumes less power than during normal standby, performs image forming processing based on input image data, a plurality of detecting units that detect a status group of the image forming unit, Image forming control means connected to a plurality of detecting means for controlling the image forming means; main control means for performing main control of the image forming apparatus; and serial communication between the main control means and the image forming control means. A power supply control method in an image forming apparatus having an interface unit connected by communication, wherein a first notification step of communicating a status group detected by the plurality of detection units by the interface unit in the low power consumption mode. (A step not shown) and when the plurality of detecting means detect the interface means at times other than the low power consumption mode. Power control method characterized by having a second notification step of communicating commands in addition to the status group (not shown step).
[0302]
[Sixth embodiment]
An image forming unit that has a low power consumption mode that consumes less power than during normal standby, performs image forming processing based on input image data, a plurality of detecting units that detect a status group of the image forming unit, Image forming control means connected to a plurality of detecting means for controlling the image forming means; main control means for performing main control of the image forming apparatus; and serial communication between the main control means and the image forming control means. A power control method in an image forming apparatus having an interface unit connected by communication, wherein a first communication step (not shown) of performing synchronous communication by the interface unit in the low power consumption mode; A second notification step (not shown) for performing asynchronous communication by the interface means at times other than the power mode. Source control method.
[0303]
[Seventh embodiment]
An image forming unit that has a low power consumption mode with less power consumption than during normal standby, performs image forming processing based on input image data, a plurality of detection units that detect a status group of the image forming unit, An image forming control unit connected to a plurality of detecting units for controlling the image forming unit; a parallel-serial converting unit for receiving outputs of the plurality of detecting units and converting the serial data; and a main unit for performing main control of the image forming apparatus A power control method in the image forming apparatus having a control unit, wherein in the low power consumption mode, a status group of the image forming unit detected by the plurality of detection units is transmitted from the parallel-serial conversion unit to the main control unit. And a first notification step (a step (not shown)) for notifying that the plurality of detection units are not in use except during the low power consumption mode. Power control method and having a second notification step of notifying the status group of image forming means from the image forming control means to said main control means (not shown step), the.
[0304]
[Eighth embodiment]
A program for executing the power supply control method according to any one of the fifth to seventh embodiments.
[0305]
[Ninth embodiment]
A storage medium storing a computer-readable program for executing the power supply control method according to any one of the fifth to seventh embodiments.
[0306]
【The invention's effect】
As described above, according to the present invention, in the low power consumption mode, the interface unit communicates a status group detected by the plurality of detection units, and when not in the low power consumption mode, the interface unit communicates the plurality of statuses. Since commands are communicated in addition to the status group detected by the detection means, the task of generating commands by the main control means and judging the commands of the image forming control means becomes unnecessary. Power can be.
[0307]
Also, in the low power consumption mode, synchronous communication is performed by the interface means, and in other than the low power consumption mode, asynchronous communication is performed by the interface means. By performing communication, power saving in the low power consumption mode can be realized.
[0308]
Furthermore, in the low power consumption mode, the status group of the image forming unit detected by the plurality of detection units is notified from the parallel-serial conversion unit to the main control unit. The status group of the image forming unit detected by the printer is notified from the image forming control unit to the main control unit. Therefore, in the low power consumption mode, the status of the printer is transmitted to the main control unit without activating the image forming control unit. The group can be notified, and power saving in the low power consumption mode can be realized.
[0309]
Therefore, even when the image forming apparatus is in the sleep state, it is possible to respond to the status heard from the network with as little energy as possible and at low cost.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an example of a network system to which an image forming apparatus according to a first embodiment of the present invention can be applied.
FIG. 2 is a block diagram illustrating a control configuration of the digital multi-function peripheral shown in FIG.
FIG. 3 is a block diagram illustrating a configuration of a DCON illustrated in FIG. 2;
FIG. 4 is a diagram illustrating an interface between the controller and DCON shown in FIG. 2;
FIG. 5 is a diagram illustrating an interface between DCON and a sensor A group illustrated in FIG. 2;
FIG. 6 is a diagram illustrating an interface between DCON and a sensor B group illustrated in FIG. 2;
FIG. 7 is a diagram illustrating a detailed configuration of a controller illustrated in FIG. 2;
FIG. 8 is a diagram illustrating a configuration of an RCON shown in FIG. 2;
9 is a diagram illustrating an interface between an IF circuit 2 and a sensor A group provided in the paper feed option shown in FIG. 3;
10 is a diagram illustrating an interface between an IF circuit 3 and a sensor B group provided in the paper feed option shown in FIG.
FIG. 11 is a flowchart illustrating an example of a first control procedure in the image forming apparatus according to the present invention.
FIG. 12 is a flowchart illustrating an example of a second control procedure in the image forming apparatus according to the present invention.
FIG. 13 is a flowchart illustrating an example of a third control procedure in the image forming apparatus according to the present invention.
FIG. 14 is a flowchart illustrating an example of a third control procedure in the image forming apparatus according to the present invention.
FIG. 15 is a diagram illustrating a detailed configuration of a controller according to a second embodiment of the present invention.
FIG. 16 is a schematic diagram showing exchange of command responses between the PC and the digital multi-function peripheral on the network including the proxy server shown in FIG. 1;
FIG. 17 is a flowchart illustrating an example of a fourth control procedure in the image forming apparatus according to the present invention.
FIG. 18 is a flowchart illustrating an example of a fourth control procedure in the image forming apparatus according to the present invention.
FIG. 19 is a flowchart illustrating an example of a fifth control procedure in the image forming apparatus according to the present invention.
FIG. 20 is a flowchart illustrating an example of a sixth control procedure in the image forming apparatus according to the present invention.
FIG. 21 is a flowchart illustrating an example of a sixth control procedure in the image forming apparatus according to the present invention.
FIG. 22 is a flowchart illustrating an example of a sixth control procedure in the image forming apparatus according to the present invention.
FIG. 23 is a diagram illustrating a memory map of a storage medium that stores various data processing programs that can be read by the image forming apparatus according to the present invention.
FIG. 24 is a block diagram illustrating an example of a network system including a conventional image forming apparatus.
[Explanation of symbols]
201 DCON
202 Controller
203 DC power supply
204 AC input section
205 AC Driver
206 FAX-UNIT
207 LAN-UNIT
208 Sensor A group
209 Sensor B group
210 Sensor C group
211 Printer DC load group
212 Laser
213 Paper ejection option
214 Paper feed option
215 AC load group
216 RCON
217 Sensor D group
218 Sensor E group
219 Sensor F group
220 Leader DC load group
221 Image Sensor
222 operation unit
223 Power switch (soft switch)

Claims (1)

In an image forming apparatus having a low power consumption mode with less power consumption than during normal standby,
Image forming means for performing image forming processing based on input image data;
A plurality of detection means for detecting a status group of the image forming means,
An image formation control unit connected to the plurality of detection units and controlling the image formation unit;
Main control means for performing main control of the image forming apparatus;
Interface means for connecting the main control means and the image forming control means by serial communication,
In the interface unit, at the time of the low power consumption mode, a status group detected by the plurality of detection units is communicated. An image forming apparatus, wherein a command is transmitted.

Images