JP2018116423A - Image processing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology of decreasing a delay in control on a load on the basis of control data transmitted by a serial communication without a speed-up of the serial communication in an image processing device that performs a distribution control on loads.SOLUTION: A master control unit 320 receives control data having a set priority from an arithmetic processing unit 301. When receiving the control data that has a transmission destination which is a slave control unit 321, the master control unit 320 stores the control data in a memory 404a or a preferential memory 407a in accordance with the priority of the received control data. The master control unit 320 transmits, to the slave control unit 321 by serial communication, the control data stored in the memory 404a or the preferential memory 407a. At this time, the master control unit 320 transmits, to the slave control unit 321, the control data stored in the preferential memory 407a preferentially to the control data stored in the memory 404a.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an image processing apparatus such as an electrophotographic image forming apparatus.

  In an electrophotographic image forming apparatus, a control system is known in which sub CPUs are individually provided for a plurality of control modules that perform different controls (for example, conveyance control, image formation control, and fixing control). In such a control system, distributed control by a plurality of sub CPUs can be realized by distributing the load of one main CPU to a plurality of sub CPUs. Further, it is possible to shorten the length of the control line arranged between the CPU and the substrate to which the load is connected, compared to the case where one CPU centrally controls many loads.

  In the control system as described above, serial communication is often applied to transmission / reception of data between CPUs (between control modules). In order to avoid a delay in controlling the load based on the control data transmitted by the serial communication, for example, it is necessary to increase the speed of the serial communication. However, the speeding up of serial communication causes unnecessary noise to be generated from the communication line, and communication errors may increase due to the generation of noise.

  Patent Document 1 proposes a technique that enables high-speed communication between control modules connected by a serial communication line without increasing the speed of serial communication. In this technology, in addition to the first communication mode in which serial communication is performed between control modules, communication can be performed in a second communication mode that is faster than serial communication, so that high-speed communication can be performed as necessary. I am doing so.

JP 2014-44558 A

  In the above-described conventional technology, when switching between a communication mode for performing serial communication and a communication mode for performing communication other than serial communication, which is faster than serial communication, the communication mode is set in each control module on the transmission side and the reception side. Processing for switching is required. However, there is a delay in the transmission of control data as the communication mode is switched, and a load control delay may occur. Further, the apparatus cost can be increased to realize the switching of the communication mode.

  The present invention has been made in view of the above problems. An object of the present invention is to provide a technique for reducing delay in load control based on control data transmitted by serial communication without increasing the speed of serial communication in an image processing apparatus that performs load distribution control. To do.

  The present invention can be realized as an image processing apparatus, for example. An image processing apparatus according to an aspect of the present invention is connected to a master control unit and the master control unit via a serial communication line, and the image processing is performed based on control data received from the master control unit by serial communication. A slave control unit for controlling the load of the apparatus, wherein the master control unit is a first memory and a second memory for buffering control data, and the control data set with priority is a higher control unit Storage means for storing the control data in the first memory or the second memory according to the priority of the received control data, and the control data stored in the first memory and the second memory. Communication means for transmitting to the slave control unit by serial communication, wherein control data stored in the second memory is transferred to the control stored in the first memory. In preference over data transmission to the slave control unit, characterized in that it comprises, and the communication means.

  According to the present invention, in an image processing apparatus that performs load distribution control, delay in load control based on control data transmitted by serial communication can be reduced without increasing the speed of serial communication.

FIG. 3 is a diagram showing an example of the appearance of the image forming apparatus 100 Sectional drawing which shows the structure of the image formation part 300 1 is a diagram illustrating a configuration example of a control system of the image forming apparatus 100 The figure which shows the structural example of the control module 303 The figure which shows the structural example of the signal transmitted via a serial bus The figure which shows the example of the relationship between the address designated with respect to data by the arithmetic processing part, and the storage location of the communication data in a master control part The flowchart which shows the procedure of the storage process of the control data to memory or priority memory Flowchart showing the procedure of transmission processing of communication data to the slave control unit

  Below, the form for implementing this invention is demonstrated using drawing. The following embodiments do not limit the invention according to the claims, and all combinations of features described in the embodiments are not necessarily essential to the solution means of the invention.

<Image forming apparatus>
FIG. 1 is a diagram illustrating an example of an appearance of an image forming apparatus 100 that is an image processing apparatus according to an embodiment. The image forming apparatus 100 includes an image reading unit 200, an automatic document feeder (ADF: auto document feeder) 250, an image forming unit 300, and an operation unit 10. The image reading unit 200 is disposed on the image forming unit 300. The ADF 250 is disposed on the image reading unit 200. The image forming apparatus 100 realizes each function of the image forming apparatus (image processing apparatus) by performing load distribution control using a plurality of control units (CPUs).

  The ADF 250 automatically conveys the document onto the platen glass. The image reading unit 200 reads a document conveyed from the ADF 250 and outputs image data. The image forming unit 300 forms an image on a recording material based on image data output from the ADF 250 or image data input from an external device connected via a network. The operation unit 10 has a GUI (graphical user interface) for a user to perform various operations. The operation unit 10 includes a display unit such as a touch panel and can present information to the user.

<Image forming unit>
FIG. 2 is a cross-sectional view illustrating a configuration example of the image forming unit 300. The image forming unit 300 of this embodiment employs an electrophotographic system. The image forming unit 300 includes image forming stations 210Y, 210M, 210C, which form toner images using toners (developers) of yellow (Y), magenta (M), cyan (C), and black (K). With 210K. In FIG. 2, reference numerals are given only to the components of the Y-color station, but the same configuration can be adopted for all four stations. Each station is an example of an image forming unit that forms an image using toner on an image carrier such as the photosensitive member 225 or the transfer belt 226.

  A photosensitive drum (photosensitive member) 225, which is an image carrier for forming a multicolor image, rotates in the direction of arrow A shown in FIG. 2 by a driving force from a motor. Around the photoreceptor 225, a charging unit 221, an exposure unit 218, a developing unit 223, a primary transfer unit 220, a cleaner unit 222, and a charge eliminating unit 271 are arranged.

  The charging unit 221 uniformly charges the surface of the photoconductor 225. The exposure unit 218 forms an electrostatic latent image on the photoconductor 225 by exposing the surface of the charged photoconductor 225 with laser light. The exposure unit 218 forms an electrostatic latent image corresponding to the image data by controlling on and off of the laser light based on the image data sent from the controller 400 via the printer control I / F 215. .

  The developing unit 223 forms a toner image on the photoconductor 225 by developing the electrostatic latent image formed on the photoconductor 225 with a corresponding color toner. Each color toner image formed on the photosensitive member 225 of the image forming station 210Y, M, C, K is transferred onto the transfer belt 226, which is an intermediate transfer member, by the primary transfer unit 220, so that multicolor An image is formed on the transfer belt 226. Note that when a monocolor image is formed, only the image forming station 210K is used. The toner image formed on the transfer belt 226 is conveyed to a contact portion (nip portion) between the secondary transfer roller 231 and the transfer belt 226. The toner remaining on the photosensitive member 225 is removed and collected by the cleaner unit 222.

  The transfer belt 226 is stretched around rollers 227, 228, and 229. The roller 227 functions as a driving roller that drives the transfer belt 226 by a driving force from a driving source. The roller 228 functions as a tension roller that adjusts the tension of the transfer belt 226. The roller 229 functions as a backup roller for the secondary transfer roller 231. The transfer roller attaching / detaching unit 250 is a drive unit for bringing the secondary transfer roller 231 into contact with the transfer belt 226 or separating it from the transfer belt 226. A cleaner blade 232 for scraping off residual toner on the transfer belt 26 is provided downstream of the secondary transfer roller 231 in the moving direction of the peripheral surface of the transfer belt 226.

  When the image formation as described above is started, conveyance of the recording material is started from any of the cassettes 240 and 241 and the manual paper feed unit 253. The cassettes 240 and 241 and the manual sheet feeder 253 include detection sensors 243, 244, and 245 for detecting the presence or absence of a recording material, respectively. The cassettes 240 and 241 and the manual paper feed unit 253 include paper feed sensors 247, 248, and 249 for detecting a pickup failure of the recording material, respectively.

  The recording materials (recording paper) stored or stacked in the cassettes 240 and 241 and the manual paper feed unit 253 are fed one by one to the conveyance path by the pickup rollers 238, 239, and 254, and the vertical path roller pairs 236, 237, etc. Thus, the sheet is conveyed toward the sheet feed roller pair 235. Thereafter, the recording material conveyed by the paper feed roller pair 235 is detected by the registration sensor 256 immediately before the registration roller 255.

  When the passage of the recording material is detected by the registration sensor 256 (or after a predetermined time has elapsed since the detection), the image forming unit 300 stops the operation (rotation) of the registration roller 255 and conveys the recording material. Interrupt. As a result, when the recording material hits the registration roller 255, the skew of the recording material is corrected. Thereafter, when the registration roller 255 is activated, the conveyance of the recording material is resumed by the registration roller 255. The recording material is conveyed to a contact portion (nip portion) between the secondary transfer roller 231 and the transfer belt 226. The toner image formed on the transfer belt 226 is transferred onto the recording material at this nip portion. The registration roller 255 is coupled to a driving source, and is driven to rotate when a driving force is transmitted from the driving source by a clutch.

  The recording material to which the toner image has been transferred passes through the conveyance path 268 and is conveyed to the fixing unit 234 via the conveyance belt 230. In the fixing unit 234, a fixing process of the toner image onto the recording material is performed by the fixing roller 233. Thereafter, the recording material is discharged out of the apparatus. Thereafter, the recording material is conveyed to the discharge path 258 side by the discharge flapper 257 and discharged to the discharge tray 242 by the discharge roller 270. The image forming unit 300 can also form an image on the back surface of the recording material. In that case, the recording material on which the image is formed on the front surface is transported to the back surface path 259 side by the paper discharge flapper 257, thereby being transported in the double-sided path 263. Thereafter, the recording material is conveyed again to the contact portion between the secondary transfer roller 231 and the transfer belt 226, and the image is transferred to the back surface thereof.

<Control system configuration>
Next, a control system of the image forming apparatus 100 according to the present embodiment will be described with reference to FIGS. 3 and 4. FIG. 3 is a diagram illustrating a configuration example of a control system of the image forming apparatus 100. The image forming apparatus 100 includes a plurality (four in this embodiment) of control modules 302 to 305 (conveying module A, conveying module B, image forming module and fixing module), and a master module 306. The various loads described with reference to FIG. 2 in the image forming apparatus 100 are autonomously controlled for each control module.

  The control module 302 (conveying module A) and the control module 303 (conveying module B) control the operation of a load such as a motor that drives various rollers for feeding or conveying the recording material. A control module 304 (image forming module) controls the operation of a load such as a photoconductor, a developing device, a primary charger, and motors for driving various rollers used in the above-described image formation. The control module 305 (fixing module) controls loads such as a fixing device and a motor that drives various rollers for discharging the recording material from the fixing device to the outside of the image forming apparatus 100.

  The master module 306 implements the functions of the image forming apparatus 100 (image forming unit 300) by controlling these four control modules 302 to 305 in an integrated manner. In the present embodiment, the arithmetic processing unit 301 illustrated in FIG. 3 corresponds to the master module 306 and functions as an upper control unit (control module) for the control modules 302 to 305. Hereinafter, the control configuration of each control module shown in FIG. 3 will be described in more detail.

  In the present embodiment, the controller 400 is provided in the image reading unit 200 or the image forming unit 300 and controls the operation of the entire image forming apparatus 100. The controller 400 communicates with the arithmetic processing unit 301 via the printer control unit I / F 215. The arithmetic processing unit 301 transmits instructions (control data) to the control modules 302 to 305 based on the instructions and image data sent from the controller 400 via the printer control I / F 215, thereby controlling the control modules 302 to 305. 305 is controlled.

  Each of the control modules 302 to 305 includes master control units 310, 320, 330, and 340 that are controlled by the arithmetic processing unit 301. The master control units 310, 320, 330, and 340 realize the functions of the control modules by controlling the slave control units to be controlled. The control module 302 further includes slave control units 311 to 314 controlled by the master control unit 310. The control module 303 further includes slave control units 321 and 322 controlled by the master control unit 320. The control module 304 further includes slave control units 331 to 335 controlled by the master control unit 330. The control module 305 further includes slave control units 341 and 342 controlled by the master control unit 340.

  As shown in FIG. 3, the master control units 310, 320, 330, and 340 are connected to the arithmetic processing unit 301 by a one-to-one connection (peer-to-peer connection) via parallel buses (first signal lines) 350 to 353, respectively. Has been. The master control unit 310 is further connected to the slave control units 311 to 314 through a one-to-one connection (peer-to-peer connection) via serial buses (second signal lines) 360 to 363, respectively. Similarly, the master control unit 320 is connected to slave control units 321 and 322 via serial buses 370 and 371, respectively. The master control unit 330 is connected to the slave control units 331 to 335 via serial buses 380 to 384, respectively. The master control unit 340 is connected to the slave control units 341 and 342 via serial buses 390 and 391, respectively.

  Each of the above-described slave control units included in the control modules 302 to 305 controls one or more different loads among various loads of the image forming apparatus 100 (image forming unit 300) described with reference to FIG. . As described above, each slave control unit of the present embodiment is connected to the master control unit via the serial communication line (serial bus), and based on the control data received by serial communication from the master control unit, Control the load.

(Control module 303)
FIG. 4 is a diagram illustrating a specific configuration example of the control modules 302 to 305, and illustrates a configuration example of the control module 303 (conveyance module B) as an example. The control module 303 includes a master control unit 320 and slave control units 321 and 322. The control modules 302, 304, and 305 have the same configuration as the control module 303, except that the number of slave control units and the number of loads that are controlled by each slave control unit may be different. Each master control unit of the control modules 302, 304, and 305 is provided with the same number of communication control units as the number of slave control units.

(Master control unit 320)
The master control unit 320 includes an address decoder 401, a memory 402 and communication control units 403a and 403b connected to the address decoder 401 via an internal bus, and a control unit 408, respectively. The communication control units 403a and 403b are connected to corresponding slave control units 321 and 322 via serial buses 370 and 371, respectively. The control unit 408 is configured by a CPU or the like, and executes processing in accordance with an instruction from the arithmetic processing unit 301 based on control data stored in the memory 402.

  The master control unit 320 includes memories 404a and 404b (first memory) and priority memories 407a and 407b (buffers) for buffering control data received from the arithmetic processing unit 301 and transmitted to the slave control units 321 and 322. A second memory). The address decoder 401 receives control data for which priority is set from the arithmetic processing unit 301, and stores the control data in the first memory or the second memory according to the priority of the received control data. The communication control units 403a and 403b transmit control data stored in the first memory or the second memory to the slave control units 321 and 322 by serial communication. At that time, the communication control units 403a and 403b transmit the control data stored in the second memory to the slave control units 321 and 322 in preference to the control data stored in the first memory.

  In the present embodiment, the address decoder 401 receives address information from the arithmetic processing unit 301 together with control data. This address information corresponds to the load to be controlled based on the control data, and is determined corresponding to the priority. Based on the received address information, the address decoder 401 selects, from the memories 402, 404 a, 404 b and the priority memories 407 a, 407 b, the storage destination of the control data received together with the address information. Hereinafter, a specific configuration and operation of the master control unit 320 will be described.

  When address information and control data received from the arithmetic processing unit 301 via the parallel bus 351 are input, the address decoder 401 analyzes the address information and specifies a write destination (transmission destination) of the control data. . In the present embodiment, this address information indicates an address in the system address space of the image forming apparatus 100 (image forming unit 300) of the present embodiment. The system address space is configured as a space in which the master memory address space used in the master control unit 320 and the slave memory address space used in the slave control units 321 and 322 are integrated.

  When the address decoder 401 specifies that the transmission destination of the control data is the slave control units 321 and 322, the address decoder 401 converts the address information in the system address space received together with the control data into the address information in the slave memory address space. The address decoder 401 selects one of the memories 402, 404a, 404b and the priority memories 407a, 407b included in the master control unit 320 based on the specified transmission destination. Further, the address decoder 401 outputs (converted) address information and control data received from the arithmetic processing unit 301 to the communication control unit 403a or 403b including the selected memory. If the memory 402 is selected, the address decoder 401 stores the received control data in the memory 402.

  The communication control unit 403a includes a memory 404a, a switching unit 405a, a parallel / serial (P / S) conversion unit 406a, and a priority memory 407a, and executes processing according to an instruction from the arithmetic processing unit 301. In the present embodiment, the memories 404a and 404b (first memory) and the priority memories 407a and 407b (second memory) are each configured by a FIFO buffer. As will be described later, address information and control data output from the address decoder 401 and sent to the slave control unit 321 are stored as communication data composed of a plurality of bits in the memory 404a or 407a in the communication control unit 403a. . The communication control unit 403a reads the communication data stored in the memory 404a or the priority memory 407a, and transmits the read communication data to the slave control unit 321 by serial communication via the serial bus 370 (in order of one bit at a time). To do.

  Specifically, the switching unit 405a switches between reading communication data from the memory 404a and reading communication data from the priority memory 407a according to whether communication data (control data) is stored in the priority memory 407a. I do. In the present embodiment, when communication data is stored in the priority memory 407a, a flag (flag) held in the priority memory 407a is set to ON, and when the communication data is not stored, the flag is set. Set to OFF. When the flag held in the priority memory 407a indicates that communication data is stored in the priority memory 407a, the switching unit 405a reads the communication data stored in the priority memory 407a and reads the P / S conversion unit. Output to 406a. At this time, when communication data is stored in the memory 404a, reading of the communication data from the memory 404a is interrupted. In this way, the switching unit 405a reads the communication data stored in the priority memory 407a with priority over the communication data stored in the memory 404a, and outputs the communication data to the P / S conversion unit 406a.

  The switching unit 405a outputs communication data composed of a plurality of bits to the P / S conversion unit 406a in a parallel format. The P / S conversion unit 406a converts the communication data from the parallel format to the serial format by performing P / S conversion on the communication data output from the switching unit 405a. The P / S conversion unit 406a transmits the communication data (serial data) after P / S conversion sequentially (one bit at a time) to the slave control unit 321 via the serial bus 370. Although the configuration and operation of the communication control unit 403a have been described, the same applies to the configuration and operation of the communication control unit 403b.

(Slave control units 321 and 322)
The slave control unit 321 includes a communication control unit 410, an address decoder 411, and load control units 412 to 415. The communication control unit 410 performs serial / parallel (S / P) conversion on the communication data received from the master control unit 320 (communication control unit 403a) via the serial bus 370, thereby converting the communication data into a serial format. To parallel format. The communication control unit 410 outputs the communication data (parallel data) after S / P conversion to the address decoder 411.

  The address decoder 411 analyzes the address information included in the communication data output from the communication control unit 410 and identifies the write destination (transmission destination) of the control data included in the communication data. In the present embodiment, the address decoder 411 analyzes the address information in the slave memory address space included in the communication data output from the communication control unit 410, and writes the control data included in the communication data (transmission destination). Is identified. A plurality (four in this embodiment) of load control units 412 to 415 are connected to the address decoder 411. The address decoder 411 identifies the transmission destination of the control data among these four load control units 412 to 415, and transmits (outputs) the control data to the identified transmission destination.

  Each of the load control units 412 to 415 is connected to a load to be controlled (for example, a stepping motor that drives a conveyance roller). The load control units 412 to 415 execute processing in accordance with an instruction (control data) received from the master control unit 320 via the address decoder 411. Thereby, each of the load control units 412 to 415 controls the operation of the load to be controlled. Although the configuration and operation of the slave control unit 321 have been described, the configuration and operation of the slave control unit 322 are the same.

<Serial communication between master controller and slave controller>
Next, serial communication between the master control unit and the slave control unit in the present embodiment will be described using the serial bus 370 between the master control unit 320 and the slave control unit 321 as an example. The serial bus 370 includes two communication lines, a transmission communication line (Tx communication line) and a reception communication line (Rx communication line) of the master control unit 320. The Tx communication line is used for output (communication) from the master control unit 320 to the slave control unit 321. The Rx communication line is used for output (communication) from the slave control unit 321 to the master control unit 320.

  FIG. 5 is a diagram illustrating a configuration example of signals transmitted via the serial bus 370 between the master control unit 320 and the slave control unit 321. The master control unit 320 sequentially transmits a packet including a plurality of frames as shown in FIG. 5 via the Tx communication line. The packet includes a plurality of frames each including a command signal, a first address signal (H), a second address signal (L), a first data signal (H), a second data signal (L), and a CRC signal. . When the slave control unit 321 successfully receives the packet from the master control unit 320, the slave control unit 321 transmits a packet including a frame including an ACK signal indicating successful reception to the master control unit 320 via the Rx communication line. When the master control unit 320 successfully receives this packet, one communication (that is, transmission of one packet from the master control unit 320 to the slave control unit 321) is completed.

  In the transmission packet from the master control unit 320, the command signal is an 8-bit signal including a command to the slave control unit 321. The first address signal (H) and the second address signal (L) are signals corresponding to the upper 8 bits and the lower 8 bits of the 16-bit address signal indicating the load control units 412 to 415, respectively. The first data signal (H) and the second data signal (L) are 16-bit signals (control data) indicating operations to be executed by the load control unit corresponding to the addresses indicated by the first and second address signals, respectively. It is a signal corresponding to upper 8 bits and lower 8 bits. The CRC signal is an 8-bit CRC signal generated from the command signal, the first and second address signals, and the first and second data signals.

  As shown in FIG. 5, each frame in the transmission packet from the master control unit 320 includes a start bit (1 bit), a data bit (8 bits), a parity bit (1 bit), and a stop bit (1 bit). , Consisting of a total of 11 bits. The start bit is data indicating the start of communication. The data bit corresponds to a signal (control data) portion. The parity bit is data for parity check generated from the data bits. The stop bit is data indicating the end of communication.

<Example of load control in the control system>
Here, all of the control data transmitted from the arithmetic processing unit 301 and sent to one of the load control units 412 to 415 in the slave control unit 321 via the master control unit 320 is stored in the memory 404a in the master control unit 320. Consider a buffered example. Since the memory 404 a functions as a FIFO buffer, the control data stored in the memory 404 a is read by the switching unit 405 a in the order input from the address decoder 401 and transmitted to the slave control unit 321.

When the load to be controlled by the load control unit 412 is the registration roller 255 (a clutch that transmits the driving force from the driving source), the operation (start and stop) of the registration roller 255 is controlled by the load control unit 412. The load control unit 412 controls the operation of the registration roller 255 according to the control data received from the arithmetic processing unit 301 via the master control unit 320. The master control unit 320 transmits control data to the slave control unit 321 (load control unit 412) via the serial bus 370 in units of packets shown in FIG. When the communication rate of serial communication on the serial bus 370 is 3 Mbps, the time Tp required to transmit one packet by the master control unit 320 is
Tp = 7 [frame] × 11 [bit] / 3 [Mbps] = 25.67 [μs]
It is.

  On the other hand, when the registration roller 255 is activated by the load control unit 412 and the conveyance of the recording material stopped at the position of the registration roller 255 in the conveyance path is resumed, if the activation of the registration roller 255 is delayed, Misalignment occurs in the transferred image. Specifically, when a delay occurs in the timing at which the load control unit 412 receives the control data due to the time that the control data is buffered in the memory 404a, the registration roller 255 to be controlled by the load control unit 412. Delay in starting up. As a result, a delay occurs in the timing at which the recording material is conveyed from the position of the registration roller 255 and reaches the position of the secondary transfer roller 231, and a position shift occurs in the image transferred to the recording material by the secondary transfer roller 231.

For example, when image formation is performed at 600 dpi, the distance between adjacent lines in the recording material conveyance direction (sub-scanning direction) is 42.3333 [μm]. In this case, if the conveyance speed of the recording material is 320 mm / s, the time obtained by the following equation after the control data is transmitted from the arithmetic processing unit 301 in order to suppress the image misregistration amount within one line. It is necessary to start the registration roller 255 within Td.
Td = 42.3333 [μm] ÷ 320 [mm / s] = 132.29 [μs]

  According to the times Tp and Td, when a packet including such control data is buffered in the memory 404a, if there are not five or more packets to be transmitted prior to the packet in the memory 404a, The registration roller 255 can be activated within Td. However, if there are five or more previously transmitted packets in the memory 404a, the registration roller 255 cannot be activated within Td due to the time that the packets are buffered in the memory 404a. . This is a cause of image displacement on the recording material as described above. Therefore, in a control that requires real-time performance, such as control of the registration roller 255, it is necessary to be able to prevent a control delay from occurring due to control data buffering.

  Therefore, in the present embodiment, the master control unit 320 gives priority to control data used for control that requires real-time property from among control data received from the arithmetic processing unit 301 (over other control data). Operates to transmit to the slave control unit 321 (priority). Specifically, the address decoder 401 stores communication data (priority data) including control data to be preferentially transmitted among communication data transmitted to the slave control unit 321 in the priority memory 407a. The communication data is stored in the memory 404a. Further, the communication control unit 403a transmits the communication data stored in the priority memory 407a to the slave control unit 321 in preference to the communication data stored in the memory 404a. That is, when communication data exists in the priority memory 407a, the communication control unit 403a transmits the communication data in the priority memory 407a to the slave control unit 321 regardless of the presence / absence of communication data in the memory 404a. Note that the master control unit 320 performs similar transmission control for communication data transmitted to the slave control unit 322. This makes it possible to transmit, for example, a registration roller driving start instruction for accurately aligning the recording material and the image position without impairing real-time performance.

<Setting example of communication data priority>
In the present embodiment, the address information transmitted together with the control data from the arithmetic processing unit 301 to the master control unit 320 corresponds to the transmission destination (for example, any load control unit) and priority of the control data. FIG. 6 is a diagram illustrating an example of the relationship between the address specified for the control data by the arithmetic processing unit 301 and the storage location of the control data in the master control unit 320. As shown in FIG. 6, the slave control units 321 and 322 are associated with different address ranges.

When the address decoder 401 receives the address information and control data from the arithmetic processing unit 301, the address decoder 401 selects a memory as a storage destination of communication data including the address information and control data in accordance with the received address information as follows.
When the address information indicates an address in the range from 0x0000_0000 to 0x0000_FFFF, the memory 402 corresponding to the master control unit 403 is selected.
When the address information indicates an address in the range from 0x0001_0000 to 0x0001_FFFF, the memory 404a corresponding to the slave control unit 321 is selected.
When the address information indicates an address in the range from 0x0002_0000 to 0x0002_FFFF, the memory 404b corresponding to the slave control unit 322 is selected.
When the address information indicates an address in the range from 0x0003_0000 to 0x0003_FFFF, the priority memory 407a corresponding to the slave control unit 321 and storing priority data is selected.
When the address information indicates an address in the range from 0x0004_0000 to 0x0004_FFFF, the priority memory 407b corresponding to the slave control unit 322 and storing priority data is selected.

  The address decoder 401 stores communication data including the received address information and control data in the memory selected as described above. The communication data (priority data) stored in the priority memories 407a and 407b is transmitted to the slave control units 321 and 322 in preference to the communication data stored in the memories 404a and 404b.

  Thus, for example, the arithmetic processing unit 301 can designate the corresponding control data as the priority data by giving a predetermined offset (0x0002_0000 in the present embodiment) to the address in the range corresponding to the slave control unit 321. As a result, the control data designated as the priority data is stored in the priority memory 407a, and is transmitted to the slave control unit 321 with priority over the control data stored in the memory 404a.

  The arithmetic processing unit 301 can designate which of the memories 404a and 404b and the priority memories 407a and 407b is to transmit control data to the slave control units 321 and 322 by setting such address information. That is, the arithmetic processing unit 301 can designate the priority (whether it is priority data) of the control data transmitted to the master control unit 320 and the transmission destination of the control data.

<Storage processing of data in memory>
FIG. 7 is a flowchart illustrating a procedure of control data storage processing in the memory 404a or the priority memory 407a, which is executed by the master control unit 320. In the following, processing executed by the address decoder 401 and the communication control unit 403a according to an instruction from the arithmetic processing unit 301 will be described, but processing executed by the communication control unit 403b can be realized in the same manner.

  First, in step S <b> 701, when the master control unit 320 receives the address information and control data output from the arithmetic processing unit 301 via the parallel bus 351, the master control unit 320 inputs the received address information and control data to the address decoder 401. In step S <b> 702, the master control unit 320 (address decoder 401) analyzes the received address information and selects a memory that stores the received control data, as described with reference to FIG. 6. Specifically, the address decoder 401 selects one of the memories 402, 404a, 404b and the priority memories 407a, 407b included in the master control unit 320.

  When the memory selection is completed, in step S703, the master control unit 320 (address decoder 401) outputs the received communication data including the address information and control data to the communication control unit 403a or 403b corresponding to the selected memory. . Thereafter, the master control unit 320 advances the process to S707 when the priority memory 407a or 407b is selected in S702, and advances the process to S705 when the priority memory 407a or 407b is not selected. When the memory 402 is selected in S702, control data is stored in the memory 402 in S703, and processing according to the control data is executed by the control unit 408.

  In S705, the master control unit 320 (communication control unit 403a) generates a command based on the control data output to the memory 404a which is a non-priority memory. In step S706, the master control unit 320 (communication control unit 403a) stores the generated command and communication data including the address information and control data output from the address decoder 401 in the memory 404a, and the process proceeds to step S710. Proceed. In addition, although the process performed in the communication control part 403a when the memory 404a was selected was demonstrated here, the process performed in the communication control part 403b when the memory 404b is selected is realizable similarly.

  On the other hand, in S707, the master control unit 320 (communication control unit 403a) generates a command based on the control data output to the priority memory 407a. Further, in S708, the master control unit 320 (communication control unit 403a) stores the generated command and communication data including the address information and control data output from the address decoder 401 in the priority memory 407a, and the process is performed in S709. Proceed to

  In S709, the master control unit 320 (communication control unit 403a) sets a flag indicating that control data is stored in the priority memory 407a, and advances the process to S710. Specifically, when there is control data stored in the priority memory 407a, the communication control unit 403a sets a flag (flag) held in the priority memory 407 to ON and exists. If not, the flag is set to OFF. Instead of such a flag, a status register indicating the storage state of the control data in the priority memory 407a may be used. Further, here, the processing executed in the communication control unit 403a when the priority memory 407a is selected has been described, but the processing executed in the communication control unit 403b when the priority memory 407b is selected can be similarly realized. .

  In S710, the master control unit 320 determines whether or not the next address information and control data received from the arithmetic processing unit 301 exist. If the next address information and control data exist, the master control unit 320 performs processing. Returning to S701, the above-described processing is repeated. On the other hand, the master control unit 320 ends the process when the next address information and control data do not exist.

<Transmission processing of communication data to the slave controller>
FIG. 8 is a flowchart showing a procedure of transmission processing of communication data to the slave control unit 321 executed in the master control unit 320. In the following, the process executed by the communication control unit 403a will be described, but the process by the communication control unit 403b can be similarly realized.

  In step S801, the communication control unit 403a (switching unit 405a) confirms the state of the flag held in the priority memory 407a and determines whether the flag is on. If it is determined that the flag is not on, the communication control unit 403a advances the process to S802, and selects communication data stored in the memory 404a as communication data to be transmitted to the slave control unit 321. On the other hand, when determining that the flag is on, the communication control unit 403a advances the processing to S803 and selects communication data stored in the priority memory 407a as communication data to be transmitted to the slave control unit 321. .

  Next, the communication control unit 403a (switching unit 405a) reads the communication data selected in S802 or S803 from the stored memory (memory 403a or priority memory 407a). In step S804, the communication control unit 403a (P / S conversion unit 406a) performs P / S conversion on the read communication data, and sequentially (1 bit at a time) the communication data after the P / S conversion. The data is transmitted to the slave control unit 321 by serial communication via the serial bus 370.

  In this way, if the control data (communication data) is not stored in the priority memory 407a, the communication control unit 403a transmits the control data stored in the memory 404a to the slave control unit 321. On the other hand, if the control data is stored in the priority memory 407a, the communication control unit 403a transmits the control data stored in the priority memory 407a to the slave control unit 321, and then stores the control data stored in the memory 404a. Is transmitted to the slave control unit 321.

  In step S805, the communication control unit 403a determines whether communication data exists in the memory 403a or 407a (that is, whether communication data to be transmitted to the slave control unit 321 exists). If the communication control unit 403a determines that communication data exists in the memory 403a or 407a, the process returns to S801, and the above-described processing is completed until transmission of the last communication data in the memory 403a or 407a is completed. repeat. On the other hand, if the communication control unit 403a determines that there is no communication data in the memory 403a or 407a, the communication control unit 403a ends communication with the slave control unit 321 and ends the processing.

  As described above, in the present embodiment, the master control unit 320 receives control data for which priority is set from the arithmetic processing unit 301. When receiving control data whose destination is the slave control unit 321, the master control unit 320 stores the control data in the memory 404 a or the priority memory 407 a according to the priority of the received control data. The master control unit 320 transmits the control data stored in the memory 404a or the priority memory 407a to the slave control unit 321 by serial communication. At that time, the master control unit 320 transmits the control data stored in the priority memory 407a to the slave control unit 321 in preference to the control data stored in the memory 404a.

  According to this embodiment, in the control system in which the master control unit 320 and the slave control units 321 and 322 perform serial communication, control data with high priority is given priority from the master control unit 320 to the slave control units 321 and 322. It becomes possible to transmit. This makes it possible to reduce or prevent delay in load control based on such control data transmitted by serial communication without speeding up serial communication.

100: Image forming apparatus, 215: Printer control I / F, 400: Controller, 300: Image forming unit, 301: Arithmetic processing unit, 302 to 305: Control module, 306: Master module, 320: Master control unit, 321, 322: Slave control unit, 401, 411: Address decoder, 403a, 403b, 410, 420: Communication control unit, 412-415, 422-425: Load control unit

Claims (10)

An image processing apparatus,
A master control unit;
A slave control unit that is connected to the master control unit via a serial communication line and that controls the load of the image processing device based on control data received by serial communication from the master control unit;
The master control unit
A first memory and a second memory for buffering control data;
Storage means for receiving control data in which priority is set from an upper control unit, and storing the control data in the first memory or the second memory according to the priority of the received control data;
Communication means for transmitting control data stored in the first memory and the second memory to the slave control unit by serial communication, wherein the control data stored in the second memory is transferred to the first memory. The communication means for transmitting to the slave control unit in preference to the stored control data;
An image processing apparatus comprising: If the control data is not stored in the second memory, the communication means transmits the control data stored in the first memory to the slave control unit, and the control data is stored in the second memory. The control data stored in the first memory is transmitted to the slave control unit after the control data stored in the second memory is transmitted to the slave control unit. The image processing apparatus according to 1. The communication means includes switching means for switching between reading of control data from the first memory and reading of control data from the second memory according to whether or not control data is stored in the second memory. The image processing apparatus according to claim 1, wherein the image processing apparatus is provided. The storage unit receives address information corresponding to a load to be controlled based on control data and corresponding to a priority from the upper control unit together with the control data, and based on the address information The image processing apparatus according to claim 1, wherein a memory that is a storage destination of the control data is selected. The storage means selects the first memory when the address information indicates a first range of addresses, and selects the second memory when the address information indicates a second range of addresses different from the first range. The image processing apparatus according to claim 4, wherein the image processing apparatus is selected. The image processing apparatus according to claim 5, wherein the address in the second range is an address obtained by giving a predetermined offset to the address in the first range. The storage means stores communication data including the address information and the control data in the selected memory,
The communication means transmits communication data stored in the first memory or the second memory to the slave control unit by serial communication,
The slave control unit is configured to control a plurality of loads, and controls a load corresponding to address information included in communication data received from the communication unit based on control data included in the communication data. The image processing apparatus according to any one of claims 4 to 6. Each comprising a plurality of slave control units connected to the master control unit via serial communication lines,
The master control unit includes the first memory, the second memory, and the communication unit for each connected slave control unit,
The image processing apparatus according to claim 4, wherein each of the plurality of slave control units is associated with a different address range. The communication means converts control data read from the first memory or the second memory from a parallel format to a serial format and transmits the data to the slave control unit by serial communication. The image processing apparatus according to any one of the above. Image forming means for forming an image on a recording material;
A conveyance roller for conveying a recording material used for image formation by the image forming unit,
The image processing apparatus according to claim 1, wherein the slave control unit controls a motor that drives the transport roller based on control data received from the master control unit. .

Images