JPH11308423A - Image processing unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the processing time by expanding received image information by a prescribed number of times toward a main scanning direction by means of a main scanning recording and reproducing means and managing the storage. SOLUTION: An image forming section is started, image data of images a, a', a" in an image memory are transferred to a laser control, a laser beam scanner is driven to write the data on a photoreceptor drum, a print job is made on paper, a fixing device is used to fix the data, the paper is outputted and an image group is printed on the paper. When an original read section reads an image of an original, how many number of times the original image (a) is expanded in the main scanning direction of the paper is calculated based on a size of the original of the image (a) of the original in the main scanning direction detected by an original size detector and a size of the paper contained in a paper feed device in the main scanning direction, the image (a) contained on the paper in the main scanning direction is obtained according to the result of calculation and the image (a) is expanded by the obtained number of times.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image processing apparatus, such as a digital color copying machine or a printer, which develops a plurality of pieces of image information input as image data on a single recording sheet as a recording medium and outputs the image information. The present invention relates to a processing device.

[0002]

2. Description of the Related Art Japanese Patent Application Laid-Open No. Sho 62-2784 discloses a method of multi-copying a plurality of images on a recording paper as a recording medium.
No. 63 was disclosed.

In the multi-copy system of this digital copying machine, an image stored in a memory is generated a plurality of times in line units and is copied onto a recording paper when a recording scan of one line is performed. there were.

[0004]

However, the multi-copy type digital copying machine described above is divided printing in the main scanning direction, and can only handle transfer processing in line units. Therefore, in order to repeatedly reproduce the original image in the sub-scanning direction, it is necessary to drive the original reading unit again to read the image data of the original, or to have a page memory and create an image group on this page memory. However, there are problems in processing (transfer) time of image information, memory capacity for managing the image information, and the like. In such a digital copying machine, the processing speed from image input to output is slow, and the cost is high. There was a problem that would.

SUMMARY OF THE INVENTION The present invention has been made in consideration of the above problems, and has as its object to provide an image processing apparatus capable of efficiently recording and reproducing an image group in which a plurality of single images are arranged in parallel. .

[0006]

According to the first aspect of the present invention,
Image information input means for inputting image information, image information storage management means for storing and managing the image information input by the image information input means, and an image for performing image processing on the image information Processing means, a recording medium on which the image information is recorded and reproduced, a transport unit for transporting the recording medium in the sub-scanning direction, and an image stored and managed on the recording medium by the image information storage management means An image information recording / reproducing unit comprising a main scanning recording / reproducing unit for sequentially performing image recording in the main scanning direction based on information, and based on image information stored and managed by the image information storage / managing unit.
An image recording / reproducing control unit for controlling recording / reproduction of an image by the image information recording / reproducing unit. There is provided input image information developing means for developing and storing and managing a predetermined number in the main scanning direction by the recording / reproducing means.

According to a second aspect of the present invention, there is provided a photographic image information detecting means for detecting that the image information input from the image information input means is photographic image information, and a photographic image information detecting means for specifying the size of the photographic image information. A photo image information size specifying unit, wherein the input image information developing unit is based on the size information specified by the photo image information size specifying unit,
The number of photographic image information to be developed in the main scanning direction is determined on the image information storage management means.

According to a third aspect of the present invention, the input image information developing means causes the image information input means to input image information a predetermined number of times and stores the image information input from the image information input means into the image information storage means. On the managing means, the storage is managed in the main scanning direction by the main scanning record reproducing means.

According to a fourth aspect of the present invention, there is provided the input image information expanding means for converting the image information input by the image information input means on the image information storage management means in the main scanning direction by the main scanning record reproducing means. To copy and store the data.

According to a fifth aspect of the present invention, the management from input to storage and output of image information is controlled by a DMA method.
MA control means, wherein the input image information expanding means secures a storage area in the image information storage management means according to the number of input images to be expanded, and stores a predetermined number of images in the secured storage area. The information is developed and stored and managed in the main scanning direction.

According to a sixth aspect of the present invention, the management of image information from input to storage and output is controlled by a DMA method.
MA control means, wherein the image recording / reproduction control means repeats the image information developed in the main scanning direction on the image information storage management means by the input image information developing means repeatedly for a predetermined number of times, and transfers one image. Record and reproduce as a group.

According to a seventh aspect of the present invention, the image recording / reproducing control means determines the number of images recordable in the main scanning direction and the number to be recorded / reproduced in the sub-scanning direction by the image information recording / reproducing means. And determining the input image information in the image information storage management means based on the number of images recordable in the main scanning direction determined by the image recording / reproduction control means. It is developed in the scanning direction and stored and managed.

According to an eighth aspect of the present invention, the image recording / reproducing control means is arranged such that, from the size and orientation of the recording medium conveyed by the image information recording / reproducing means, the direction of the image to be reproduced and the main scanning direction. The number of images that can be recorded and the number that can be recorded and reproduced in the sub-scanning direction are determined, and the direction of the image determined by the input image information developing unit and the image recording and reproduction control unit, and the main scanning direction The direction of the input image information developed in the image information storage management means based on the number of images that can be recorded toward the image information, and the image information storage based on the number of images that can be recorded toward the main scanning direction. The direction of the input image information developed in the management means and the development in the main scanning direction are controlled.

According to a ninth aspect of the present invention, there is provided a recording image number setting means for setting the number of images to be recorded and reproduced, and the image recording / reproduction control means is provided for setting the number of images to be recorded and reproduced. Based on the number, the number of images to be recorded and reproduced in the main scanning direction and the number to be recorded and reproduced in the sub-scanning direction are determined by the image information recording / reproducing means. Based on the number of images recordable in the main scanning direction determined by the image recording / reproduction control means, the input image information in the image information storage management means is developed in the main scanning direction and stored and managed.

According to a tenth aspect of the present invention, there is provided a recording image number setting means for setting the number of images to be recorded and reproduced, and the image recording / reproduction control means is provided for setting the number of images to be recorded and reproduced by the recording image number setting means. Based on the number, the size of the recording medium of the image reproduced by the image information recording / reproducing means, the number of images to be recorded and reproduced in the main scanning direction, and the number to be recorded and reproduced in the sub-scanning direction And determining the input image information in the image information storage management means based on the number of images recordable in the main scanning direction determined by the image recording / reproduction control means. It is developed and stored in the scanning direction.

According to an eleventh aspect of the present invention, in the image information recording / reproducing means, at least one side of the image information to be recorded / reproduced is
Recording and reproduction are performed so as to be parallel to and close to at least one side of the recording medium on which the image information is recorded.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The configuration of a digital color copying machine which is an image processing apparatus according to the present invention will be described with reference to FIG. FIG.
1 is a front sectional view of an embodiment of a digital color copying machine.

A document table 111 and an operation panel are provided on the upper surface of the copying machine main body 1.
An automatic document feeder 112 is mounted on the upper surface of the document table 111 so as to be openable and closable with respect to the document table 111, and has a predetermined positional relationship with the surface of the document table 111. Further, an original reading section 110 is provided inside the copying machine main body 1.
And an image forming unit 210.

First, the automatic document feeder 112 mounted on the document table 111 on the upper surface of the copying machine main body 1 is a double-sided automatic document feeder corresponding to a double-sided document. Are conveyed so as to face each other at a predetermined position, and after the image reading on one side is completed, the document is turned over so that the other side faces at a predetermined position on the document base 111 and faces the document base 111. Transport.

After the reading of one side of the original has been completed, the original is discharged, and a double-sided conveying operation is performed for the next original. Note that the above-described document transport and reverse operation are controlled in relation to the operation of the entire copying machine.

In order to read the image of the original conveyed onto the original platen 111 by the automatic two-sided automatic document feeder 112, the original reciprocates below the original platen 111 in parallel along the lower surface of the original platen 111. A document scanning body is arranged.

This original scanning body is provided with a predetermined distance on the lower surface of an original table 111 comprising an exposure lamp for exposing the original image surface and a first mirror for deflecting a reflected light image from the original in a predetermined direction. A first scanning unit 113 that reciprocates in parallel at a scanning speed, and a second and second scanning units that further deflect a reflected light image from a document deflected by a first mirror of the first scanning unit 113 in a predetermined direction. 3
The second scanning unit 11 reciprocates in parallel with the first scanning unit 113 composed of a mirror with a constant speed relationship.
4, an optical lens 115 for reducing a reflected light image from a document deflected by the third mirror of the second scanning unit 114 to form an optical image at a predetermined position, and an optical lens 115
And a photoelectric conversion element 116 that sequentially photoelectrically converts the light image formed by the reduced light image and outputs a reflected light image from the document as an electric signal. The document image information converted into an electric signal by the photoelectric conversion element 116 is
Further, the image data is transferred to an image processing unit described later and subjected to predetermined processing as image data.

Next, the image forming section 210 located on the lower side of the copying main body 1 will be described. A paper feed mechanism 211 is provided below the image forming unit 210 shown in FIG. 1, and separates sheets stored in a sheet tray one by one and supplies the separated sheets toward the recording unit. .

The paper separated and supplied one by one is
The sheet is conveyed at a controlled timing by a pair of registration rollers 212 disposed in front of the image forming unit 210, and is re-conveyed and conveyed at a timing with the image forming unit 210.

Below the image forming unit 210, a transfer / transport belt 213 extending substantially in parallel is disposed. The transfer / transport belt 213 is stretched between a plurality of rollers such as a driving roller 214 and a driven roller 215. The paper is configured to be electrostatically attracted and conveyed.

Further, a fixing device 217 for fixing the toner image transferred and formed on the sheet to the sheet is disposed downstream of the transfer / conveying belt 213. The fixing device 217 passes between the fixing roller nips of the fixing device 217. The discharged sheet is discharged by a discharge roller 219 through a transfer direction switching gate 218 onto a discharge tray 220 attached to an outer wall of the apparatus.

The transfer direction switching gate 218 discharges the sheet after fixing to the outside of the copying machine, and switches the sheet transfer path selectively again to supply the sheet to the image forming unit 210 again. The switching gate 21
The sheet whose conveyance direction has been switched again toward the image forming unit 210 by 8 is turned over again via the switchback conveyance path 221 and then supplied to the image forming unit 210 again.

The driving roller 214 and the driven roller 21
5, the first, second, third, and fourth image forming stations Pa are arranged on the upper side of the transfer conveyance belt 216 that is stretched substantially parallel to the transfer conveyance belt 216 in order from the upstream side of the conveyance path in the proximity of the transfer conveyance belt 216. , Pb, Pc, and Pd are arranged side by side.

The transfer conveyance belt 216 is frictionally driven by the drive roller 214 in the direction indicated by the arrow Z in FIG. 1, and carries the paper fed through the paper feed mechanism 211 as described above. The sheets are sequentially conveyed to the above-described image forming stations Pa, Pb, Pc, and Pd.

Each image forming station Pa, Pb, P
c and Pd have substantially the same structure, and are driven to rotate in the direction of arrow F shown in FIG.
b, 222c, 222d, each photosensitive drum 222
Around the photosensitive drums 222a, 222b, 222
Chargers 223a and 223 for uniformly charging c and 222d
b, 223c, 223d and developing devices 224a, 224 for developing the electrostatic latent image formed on the photosensitive drum 222.
b, 224c, 224d, and transfer dischargers 225a, 225b, 225 for transferring the developed toner image to paper.
c, 225d and cleaning means 226a, 226b, 2 for removing toner remaining on the photosensitive drum 222.
26 c and 226 d are sequentially arranged along the rotation direction of the photosensitive drum 222.

Each photosensitive drum 222a, 222
Above b, 222c, and 222d, a semiconductor laser device that emits dot light modulated in accordance with image data, a deflecting device 240 for deflecting light from the semiconductor laser device in the main scanning direction, and a deflecting device 240 Lens 241 for forming an image of the laser beam deflected by the laser beam on the surface of the photosensitive drum 222, and laser beam scanner units 227a,
27b, 227c and 227d are provided respectively.

The laser beam scanner unit 227a receives a pixel signal corresponding to the yellow component image of the color original image, the laser beam scanner unit 227b receives a pixel signal corresponding to the magenta component image of the color original image, and the laser beam scanner unit 227c. The pixel signal corresponding to the cyan component image of the color original image is input to the laser beam scanner unit 227d, and the pixel signal corresponding to the black component image of the color original image is input to the laser beam scanner unit 227d.

As a result, an electrostatic latent image corresponding to the color-converted original image information is formed on each photosensitive drum 222, and a yellow toner is applied to the developing device 227a and a magenta toner is applied to the developing device 227b. Developing device 22
7a contains cyan toner, and the developing device 227b contains black toner. Therefore, original image information color-converted at each of the image forming stations Pa, Pb, Pc, Pd is converted into a toner image of each color. Is reproduced as

A paper-suction (brush) charger 228 is provided between the first image forming station Pa and the paper feeding mechanism 211.
Charges the surface of the transfer conveyance belt 216, and feeds the paper
The first image forming station Pa in a state in which the sheet supplied from
And the fourth image forming station Pd.

On the other hand, a static eliminator (not shown) is provided almost directly above the driving roller 214 between the fourth image forming station Pd and the fixing device 217. An alternating current is applied to the sheet 216 to separate the electrostatically attracted sheet.

In the digital color copying machine having the above configuration, a cut sheet is used as a sheet, and when the sheet is fed out of the sheet cassette and fed into the guide of the sheet feeding path of the sheet feeding mechanism 211. The leading edge of the sheet is detected by the above-described sensor, and the sheet is temporarily stopped by the registration roller pair 212 according to the detection signal output from the sensor. Then, the sheet is sent to the transfer / conveying belt 216 rotating in the direction of arrow Z in FIG. 1 at the timing of each of the image forming stations Pa, Pb, Pc, and Pd. At this time, the paper suction charger 228 described above is used.
As a result, the transfer / conveying belt 216 is charged in a predetermined manner, so that the transfer / conveying belt 216 is stably conveyed and supplied while passing through the image forming stations Pa, Pb, Pc and Pd.

Each image forming station Pa, Pb, P
In c and Pd, the toner images of the respective colors are respectively formed by the above-described configuration, are superimposed on the support surface of the sheet electrostatically conveyed and conveyed by the transfer conveyance belt 216, and the image transfer by the fourth image forming station Pd is performed. When the transfer is completed, the leading edge of the sheet is guided by the static eliminator to the fixing device 217 peeled off from the transfer / conveying belt 216. And
Finally, the sheet on which the toner image has been fixed is discharged onto the sheet discharge tray 220 from the sheet discharge port.

(Explanation of Configuration of Network System Including Digital Color Copier) FIG. 2 is not a digital color copier 1 (copier main body 1) as a stand-alone system, but a network system configuration using the digital color copier 1 as a core. FIG.

The image information input method includes not only the input of document information from the document reading section 110 of the digital color copying machine 1 but also the connection of a personal computer 2, a digital camera 3, a digital video camera 4, a communication portable terminal connected to a network. 5 and the like. Further, image information can be input from a remote place through the Internet, an intranet, or a rapidly growing communication infrastructure.

Accordingly, the digital color copying machine 1 for outputting these image information plays an important role as a multifunction printer or a network printer, and has an additional function in addition to the functions of the digital as viewed from the user. It has a system configuration that can give value.

(Circuit Description of Image Processing Unit) Next, the configuration and functions of a color image information image processing unit mounted on a digital color copying machine will be described. FIG. 3 is a block diagram of the image processing unit included in the digital color copying machine.

The image processing section included in the digital color copying machine includes an image data input section 40, an image processing section 4
1, an image data output unit 42, an image memory 43 including a hard disk device or a RAM (random access memory), a central processing unit (CPU) 44, an image editing unit 45, and external interface units 46 and 47.
It is composed of

The image data input section 40 is a three-line color CCD 40a capable of reading a black-and-white original or a color original image and outputting line data separated into RGB color components. A shading correction circuit 40b for correcting the line image level, a line matching unit 40c such as a line buffer for correcting a shift of image line data read by the three-line color CCD 40a, and lines of each color output from the three-line color CCD 40a. A sensor color correction unit 40d for correcting the color data of the data, an MTF correction unit 40e for correcting the change in the signal of each pixel so as to have a sharpness, and a gamma correction unit 40f for correcting the brightness of the image to correct the visibility. Etc.

The image processing unit 41 includes an image data input unit 40
Data generation unit 41a that generates monochrome data from RGB signals as color original signals input from
(Black and white original), an input processing unit 41b that converts RGB signals into YMC signals corresponding to the respective recording units of the recording apparatus, and also performs clock conversion, and a photographic paper photograph whether the inputted image data is a character part or a halftone picture. An area separation unit 41c that separates each of them, a YMC output from the input processing unit 41b
A black generation unit 41d that performs under color removal processing based on a signal to generate black, a color correction circuit 41e that adjusts each color of a color image signal based on each color conversion table, and image information that is input based on a set magnification , A zoom processing circuit 41f for converting the magnification, a spatial filter 41g, and a halftone processing section 41h for expressing gradation such as multi-level error diffusion and multi-level dither.

Each color image data that has been subjected to the halftone processing is temporarily stored in the image memory unit 43. The image memory unit 42 stores 8 bits and 4 colors (32 bits) serially output from the image processing unit 41.
4) hard disk (rotary storage medium) 43a that sequentially receives image data of each bit, temporarily stores the data in a buffer, converts the 32-bit data into 8-bit 4-color image data, and stores the image data for each color. , 43
b, 43c and 43d.

Further, since the positions of the respective image stations are different, the image memory (semiconductor memory) of the image memory section 43 is provided.
The color image data is temporarily stored in the storage unit 43e and the time is shifted, so that the color shift is prevented in accordance with the timing at which the image data is sent to each laser scanner unit. Further, the image memory unit 43 includes an image synthesis memory (image memory 43e) for synthesizing a plurality of images.

The image data output section 42 is a halftone processing section 41
h) a laser control unit (LSU) 42a that performs pulse width modulation based on image data of each color from h, and each color that performs laser recording based on a pulse width modulation signal corresponding to an image signal of each color output from the laser control unit 42a. Laser scanner units 42a, 42b,
42c and 42d.

The central processing unit (CPU) 44 includes an image data input unit 40, an image processing unit 41, an image data output unit 42, an image memory 43, and an image editing unit 4 described later.
5. It controls the external interface units 46 and 47 and the DMA controller 48 based on a predetermined sequence.

The image editing unit 45 performs a predetermined image editing on the image data once stored in the image memory 43 via the image data input unit 40, the image processing unit 41, or the external interface unit 46 described later. It is for.

Further, the external interface unit 46
This is a communication interface unit for receiving image data from an external image input processing device (communication portable terminal, digital camera, digital video camera, etc.) provided separately from the digital color copying machine.

The image data input from the external interface unit 46 is also input to the image processing unit 41 and subjected to color space correction and the like, so that the image data can be handled by the image recording unit 210 of the digital color copying machine. Converted to a level and the hard disks 43a, 43b, 43c,
43d.

Further, an external interface 47 is a printer interface for inputting image data created by the personal computer 2,
A color black or color FAX interface for receiving the received image data. The image data input from the external interface 47 is already YMC
This is a K signal, which is once subjected to halftone processing by a halftone processing unit 41h, and
3b, 43c and 43d. The images input from both interfaces become original images, and also become specific images (for example, advertisement images) through the specific image information management unit 48.

(Explanation of Control Structure of Entire Digital Color Copier) FIG. 4 is a block diagram of a control circuit including a central processing unit (CPU) 44 for controlling each part of the entire digital color copier. The image data input unit 40, the image processing unit 41, the image data output unit 42, the image memory 43, and the central processing unit (CPU) 44 are the same as those in FIG. Central processing unit (CPU)
Numeral 44 manages, by sequence control, the respective drive mechanisms constituting the digital color copying machine such as the RADF 2-1, the scanner unit and the laser printer unit, and outputs a control signal to each unit.

Further, a central processing unit (CPU) 4
An operation board unit 49 composed of an operation panel is connected to the control unit 4 in a mutually communicable state, and a control signal indicating copy mode contents set and input by the operator in accordance with an operation of the operation panel 75 is transmitted to the central processing unit (4). CPU 44 to control the digital color copying machine to operate in accordance with the mode.

A control signal indicating the operation state of the digital color copying machine is transferred from the central processing unit (CPU) 44 to the operation board unit 49. The operating state is displayed on a display unit or the like so as to indicate to the operator whether the state is such.

(Explanation of Operation Panel) FIG. 5 is a plan view showing an operation panel in the digital color copying machine.
A touch panel liquid crystal display device 6 is arranged at the center of the operation panel, and various mode setting keys are arranged around the touch panel liquid crystal display device 6.

On the screen of the touch panel liquid crystal display device 6, there is a screen switching instruction area for constantly switching to a screen for selecting an image editing function. By directly pressing this area with a finger, various image editing functions are selected. A list of various editing functions is displayed on the liquid crystal screen so that it can be performed. From among the displayed various editing functions, the operator sets the editing function by touching the area where the desired function is displayed with a finger.

The group of various setting keys arranged on the operation panel will be briefly described. Reference numeral 7 denotes a dial for adjusting the brightness of the screen of the touch panel liquid crystal display device 6.
Reference numeral 8 denotes an automatic magnification setting key for setting a mode for automatically selecting a magnification, reference numeral 9 denotes a zoom key for setting a copy magnification in increments of 1%, reference numerals 10 and 11 denote fixed magnification keys for reading and selecting a fixed magnification, Reference numeral 12 denotes an equal-magnification key for returning the copy magnification to a standard magnification (actual magnification).

Reference numeral 13 denotes a density switching key for switching the copy density adjustment from automatic to manual or photo mode.
Reference numeral 14 denotes a density adjustment key for finely setting the density level in the manual mode or the photograph mode. Reference numeral 15 denotes a tray selection for selecting a desired paper size from paper sizes set in a paper feeding unit of the copying machine. Is the key.

Reference numeral 16 denotes a copy number setting key for setting the number of copies, 17 denotes a clear key operated when clearing the number of copies or stopping continuous copying in the middle, 18 denotes a start key for instructing the start of copying, Reference numeral 19 denotes an all release key for releasing all of the currently set modes and returning to the normal state, reference numeral 20 denotes an interrupt key operated when a copy of another document is desired during continuous copying, and reference numeral 21 denotes a copy machine. An operation guide key for displaying a message about the operation method of the copier by operating it when you do not understand the operation,
Reference numeral 22 denotes a message forward key for displaying a continuation of the message displayed by operating the operation guide key 21.

Reference numeral 23 denotes a double-sided mode setting key for setting a double-sided copying mode, and reference numeral 24 denotes a post-processing mode setting key for setting an operation mode of a post-processing apparatus for sorting copies discharged from a copying machine. . 25 to 27 are setting keys related to the printer mode and the facsimile mode, 25 is a memory transmission mode key for temporarily storing a transmission original in a memory and then transmitting the same, and 26 is a mode for copying and faxing the mode of the digital copier between the printer and the printer. Copy / fax / printer mode switching key for switching,
Reference numeral 27 denotes a one-touch dial key for storing a destination telephone number in advance and transmitting a call to the destination by a one-touch operation at the time of transmission.

The operation panel presented this time and the various keys arranged on the operation panel are only examples, and the keys provided on the operation panel differ depending on various functions mounted on the digital color copier. Needless to say.

An embodiment of an image processing method for arranging and recording a plurality of images in a digital color copying machine according to the present invention will be described with reference to FIG.

First, the document image a read by the document reading section 110 is subjected to image processing by the image processing section 41 and stored in the image memory 43e. Then, the image memory 43
Images a ′ and a ″ are created in the main scanning direction on e.

In this state, the image forming unit 210 is started, and
The image data of the image a, image a ', and image a''on the image memory 43e is transferred to the laser control 42, and the laser beam scanners 227a to 227d are driven to write the photosensitive drums 222a to 222d to form an image on paper. ,
Further, the image is fixed by the fixing device 217 and the sheet is output, and the image group is printed on the sheet.

When a document image is read by the document reading unit 110, the document size in the main scanning direction of the document image a detected by the conventional document size detection is stored in the paper feeding mechanism 211. The number of times the original image a can be expanded in the main scanning direction of the paper is calculated based on the size of the existing paper in the main scanning direction, and an image a that fits in the main scanning direction of the paper is calculated based on the calculation result [FIG. )] (Development number), and the obtained number image a is developed and formed.

Here, as a method of creating a plurality of image groups in the main scanning direction, the image reading unit 110 is driven a plurality of times to read the document images a plurality of times, so that the image groups a, a ',. a '' can be created. As another method, the image group a, a ′, and a ″ can be created on the image memory 43e by expanding the image a read from the document reading unit 110 on the image memory 43e. .

Here, when storing image data in the image memory 43e, a memory width (data amount) in the main scanning direction is obtained in advance according to the size of the paper mounted on the paper feeding mechanism 211 in the main scanning direction. To secure.

Next, the width of the original image a detected in the original size detection in the main scanning direction and the length in the sub-scanning direction and the memory width obtained from the paper are designated, and the DMA ( direct memory ac
ESS) The image data is transferred by the DMA method by the controller 48, and the image a is recorded on the image memory 43e. Similarly, the images a ′ and a ″ are also stored in the image memory 43e (FIG. 6B),
The image group data is read from the image memory 43e and printed on a sheet (FIG. 6C).

As described above, on the image memory 43e, the group of images developed in the main scanning direction is transferred by the DMA controller 48 connected to the image data bus to the width of the image memory 43e in the main scanning direction and the width in the sub-scanning direction. The length and the recording length of the paper in the sub-scanning direction are designated, and the image data is transferred to the laser control 42 by the DMA method. At this time, when the DMA controller 48 finishes sending the image group data (image a, image a ', image a'') in the image memory 43e, if the recording length is shorter than the previously set recording length, the DMA controller 48 automatically sets the image memory. 43e has a function of returning to the beginning of the image group data (image a, image a ', and image a'') and transferring the image group data once. The image group b ′ obtained by the third reading is printed, and the image group b ″ obtained by the third reading (FIG. 7C) is printed.

Here, as shown in FIG. 7, when a document image is read by the document reading section 110, the document size in the sub-scanning direction of the document image detected by the conventional document size detection is determined. By performing an operation based on the size of the paper accommodated in the mechanism 211 in the sub-scanning direction, the number of images a that fit in the paper in the sub-scanning direction (the image memory 43)
e) (the number of times data transfer is repeated).

Further, the number setting key 1 on the operation panel 75
6 and the like, the number of desired output images (the number of additional prints) is calculated from the document size and the paper size, and as a result of this calculation, the maximum number of developments in the main scanning direction and the maximum repetition in the sub-scanning direction are obtained. The numbers are compared with each other to determine the optimum number of developments in the main scanning direction and the number of repetitions in the sub-scanning direction, and printing is performed on paper (FIG. 7).

The maximum number of developments in the main scanning direction and the maximum number of repetitions in the sub-scanning direction of each sheet that can be fed by the sheet feeding mechanism 211 are obtained from the original image, and are input from the number setting key 16 on the operation panel 75 or the like. It is also possible to compare the number of desired output images (the number of additional prints) and select an optimum sheet.

First, the width in the main scanning direction and the length in the sub-scanning direction are obtained from the document image data read by the document reading unit 110. Next, the maximum number of developments in the main scanning direction and the maximum number of repetitions in the sub-scanning direction are obtained by calculation from the width of the sheet in the main scanning direction and the length in the sub-scanning direction. Further, the maximum number of developments in the main scanning direction and the maximum number of repetitions in the sub-scanning direction on the paper when the read original image data is rotated by 90 ° are obtained, and the maximum image that can be recorded on one sheet at this time is obtained. The number (n2) is calculated. Here, if n2 is larger than the previously calculated maximum number of images, more images can be recorded on one sheet of paper by rotating the original image data by 90 ° on the image memory 43e [FIG. ), FIG.
(D)].

When an original image is read by the original reading unit 110, the original size in the main scanning direction of the original image detected by the original size detection and the size of the paper accommodated in the paper feeding mechanism 211 in the main scanning direction are determined. By performing the calculation, the number (the number of developments m) of the images a that fit in the main scanning direction on the sheet is obtained. Here, the development in the main scanning direction is performed such that the m-1 image is arranged at the left end and one image is arranged at the right end of the memory width secured for the paper.

Next, by performing an operation based on the size of the original image (FIG. 6) in the sub-scanning direction and the size of the paper in the sub-scanning direction, the number of images that can be accommodated in the paper in the sub-scanning direction (data in the image memory). The transfer repeat count k) is obtained. Here, the image data in the image memory is stored in the laser control 4
2 is repeatedly transferred k-1 times, and the sheet is conveyed by a length obtained by subtracting the length of the image a in the sub-scanning direction × k from the length of the sheet in the sub-scanning direction. Fig. 9
To obtain the output image.

According to the above embodiment, at least one original image is developed in the main scanning direction on the image memory,
Since at least one image on the image memory developed in the main scanning direction is sequentially read out and recorded and reproduced, the capacity of the image memory is sufficient for one image in the sub-scanning direction, and there is no need to have one page. That is, since the amount of data to be developed is reduced accordingly, the processing time can be reduced. Therefore,
By efficiently processing image information from input to output without requiring more processing time than necessary to prepare for recording of image data at the time of image output, the resulting image information can be recorded and reproduced in a desired form. Becomes possible.

Here, when image data for one image is placed on the image memory in the main scanning direction and read out repeatedly, the data transfer to the image forming unit is performed by a transfer setting process for each line of one image. Required. Then, only by forming one image group (image a, image a ′, and image a ″), the transfer setting processing is required several times in the main scanning direction × the number of sub-scanning lines of one image. However, if the image data is developed in the main scanning direction to form an image group (image a, image a ′, image a ″), the image data in the main scanning direction can be prepared for one line of the paper. Can be transferred by one transfer setting for this one image group, greatly reducing CPU control, and performing high-speed and efficient processing.

Further, only by adding a simple processing step (image development) in consideration of the image output before the recording output,
It is possible to sufficiently cope with high-speed image output processing.

[0080]

According to the image processing apparatus of the first aspect,
At least one original image is developed in the main scanning direction on the image information storage management means, and the images on the image information storage management means developed in this main scanning direction are sequentially read out and recorded and reproduced. The capacity of the storage management means is sufficient for one image in the sub-scanning direction, and it is not necessary to have one page. In other words, the amount of data to be developed is reduced accordingly, so that the processing time can be reduced. Therefore, it is possible to efficiently process the image information from input to output without requiring an unnecessarily long processing time for recording the image information at the time of image output.

According to the image processing apparatus of the present invention, the number of developments to be developed in the main scanning direction is determined from the determined type of the photographic image information, and the input photographic image is stored on the image information storage management means. Therefore, it is possible to copy the number of images of a photograph having various sizes on a sheet according to the size. In addition, since an appropriate sheet size and the number of images to be recorded are determined and recorded and reproduced, it is possible to suppress unnecessary consumption of recording agent due to formation of unnecessary sheets and unnecessary images.

According to the image processing apparatus of the third aspect, the same original image input a plurality of times is developed in the main scanning direction on the image information storage management means and stored as one image information. Since the image information on the image information storage management means developed as one image information in the direction is sequentially read out and recorded and reproduced, the image processing can be performed without requiring more processing time than necessary to prepare the recording of the image information at the time of image output. It is possible to efficiently process information from input to output. In addition, by inputting the required number of images from the input unit, the load on the image processing unit such as image processing and image transfer can be reduced, and the processing capacity of the image processing unit can be used for other processing. Becomes

According to the image processing apparatus of the present invention, at least one input document image is developed in the main scanning direction on the image information storage management means and stored as one piece of image information. Since the image information on the image information storage management means developed as one piece of image information is sequentially read out and recorded and reproduced, it is possible to prepare the image information at the time of image output without requiring more processing time than necessary. It is possible to efficiently process information from input to output. Further, by expanding the input image information on the image information storage management means by the required number of images, it is possible to reduce the load on the image input unit and to cope with new image information input processing. Become.

According to the image processing apparatus of the fifth aspect, D
An image information storage management configuration based on the MA method is provided, and a storage area determined from the number of images to be expanded on the image information storage management means is first secured, and then the required number of images are sequentially expanded in the main scanning direction. Therefore, in the image information storage management configuration by the DMA method, image information storage management for realizing high-speed output of image information and simplification of image information output control can be performed. Also, for example, even in an environment where image information from a plurality of devices connected to a network is input, a recording area is secured in consideration of image output first, so that newly interrupted image information is ideal. It is possible to prevent the image information storage management environment from being affected.

According to the image processing apparatus of the sixth aspect, D
An image information storage management structure for image information by the MA method is provided, and at least one image information developed in the main scanning direction is sequentially transferred to the output destination on the image information storage management means, so that output processing at the time of image output can be performed. It is performed efficiently, and the speed of image output processing can be increased. In addition, since processing for other images can be performed in parallel with the transfer of image information, large image information can be efficiently processed as a system.

According to the image processing apparatus of the present invention, the number of document images which can be recorded in the main scanning direction and the sub-scanning direction on a predetermined recording medium is obtained, and the number of original images which can be recorded in the obtained main scanning direction is obtained. A number of original images are developed in the main scanning direction on the image information storage management means, and the number of images developed on the image information storage management means are read out and recorded by the number recordable in the sub-scanning direction. When reproducing, the number of records that can be recorded and reproducible as a recording device is read and recorded, so when recording and reproducing as an image, the number of records that can be reproducible as a recording device can be grasped and then efficiently recorded and reproduced as multiple images it can.

According to the image processing apparatus of the present invention, the direction of the image information and the number of developments in the main scanning direction are determined according to the size and the direction of the designated recording medium, so that the image is recorded and reproduced. At this time, it is possible to efficiently record and reproduce a plurality of images after grasping an appropriate direction of the image to be recorded and reproduced on the recording medium and the number of reproducible images.

According to the image processing apparatus of the ninth aspect, the number recordable in the main scanning direction and the sub-scanning direction is determined according to the number of input desired number of output images. The image group is expanded in the main scanning direction on the image information storage management means by the number of images that can be recorded in the image information storage management means, and the number of images recorded and reproduced in the sub-scanning direction on the image expanded on the image information storage management means After the number of main scanning directions and sub-scanning directions that can be recorded and reproduced can be ascertained, recording and reproduction can be efficiently performed as a plurality of images.

According to the image processing apparatus of the tenth aspect,
Since the size of the recording medium on which the developed image is recorded is determined according to the number of desired output images input, the number of images to be recorded and reproduced is determined based on the number of images to be recorded and reproduced when recording and reproducing the image. It is possible to efficiently reproduce and reproduce a plurality of images after ascertaining the recording medium size and the number of main scanning directions and sub-scanning directions that can be recorded and reproduced.

According to the image processing apparatus of the eleventh aspect,
Since the image reproduced on the recording medium is recorded and reproduced so that at least one side of the image is parallel to and close to at least one side of the recording medium, the image is recorded and reproduced on the recording medium as a plurality of image groups. When the user wants to further cut out the image portion, it becomes a reference for cutting out.

[Brief description of the drawings]

FIG. 1 is a front sectional view showing the entire structure of an embodiment of a digital color copying machine which is an image processing apparatus of the present invention.

FIG. 2 is an explanatory diagram showing a configuration of a network system centering on the digital color copying machine of FIG. 1;

FIG. 3 is a block diagram of an image processing unit included in the digital color copying machine of the present invention.

FIG. 4 is a block diagram of a control circuit including a central processing circuit for controlling each unit of the entire digital color copying machine of the present invention.

FIG. 5 is a plan view showing an operation panel in the digital color copying machine of the present invention.

FIG. 6 is an explanatory diagram showing development of image data read from a document in an image memory in the digital color copying machine of the present invention.

FIG. 7 is an explanatory diagram showing recording from image data in an image memory to a sheet in a digital color copying machine of the present invention.

FIG. 8 is an explanatory diagram showing a rotation state of image data on an image memory in the digital color copying machine of the present invention.

FIG. 9 is an explanatory diagram showing an arrangement of image data in an image memory and an arrangement of an image group on paper in the digital color copying machine of the present invention.

[Explanation of symbols]

 40 image data input unit 41 image processing unit 42 image data output unit 43 image memory 44 central processing unit (CPU) 45 image editing unit 46, 47 external interface unit 48 DMA controller

Claims (11)

[Claims] 1. An image information input means for inputting image information, an image information storage management means for storing and managing image information input by the image information input means, and an image processing for the image information An image processing unit for performing the image processing, a recording medium on which the image information is recorded and reproduced, a conveyance unit for conveying the recording medium in the sub-scanning direction, and the image information storage management unit stored on the recording medium. An image information recording / reproducing unit including a main scanning recording / reproducing unit for sequentially performing image recording in the main scanning direction based on the managed image information; and an image information stored / managed by the image information storage / managing unit. An image recording / reproduction control unit for controlling image recording / reproduction by the image information recording / reproduction unit based on the image information input / output unit. The image information,
An image processing apparatus, characterized in that said image information storage management means includes input image information expansion means for expanding and storing a predetermined number in the main scanning direction by said main scanning recording and reproducing means for storage management. 2. A photographic image information detecting means for detecting that the image information input from the image information input means is photographic image information, and a photographic image information size specifying means for specifying the size of the photographic image information The input image information developing means determines the number of developed pieces of photographic image information to be developed in the main scanning direction on the image information storage management means based on the size information specified by the photographic image information size specifying means. 2. The method according to claim 1, wherein
The image processing apparatus according to any one of the preceding claims. 3. The input image information expanding means causes the image information input means to input image information a predetermined number of times, and displays the image information input from the image information input means on the image information storage management means. 2. An image processing apparatus according to claim 1, wherein said main scanning recording and reproducing means stores and manages the data in a main scanning direction. 4. The input image information developing means copies a predetermined number of image information input by the image information input means on the image information storage management means in a main scanning direction by the main scanning record reproducing means. 2. The image processing apparatus according to claim 1, wherein the image processing is performed and stored. 5. A DMA control means for controlling management from input to storage and output of image information by a DMA method, wherein said input image information expanding means stores said image information according to the number of input images to be expanded. In addition to securing a storage area in the management means, in the secured storage area,
2. The image processing apparatus according to claim 1, wherein a predetermined number of pieces of image information are developed and stored and managed in the main scanning direction. 6. A system according to claim 1, further comprising a DMA control means for controlling management from input to storage and output of the image information by a DMA method, wherein said image recording / reproduction control means is provided on said image information storage management means by said input image information expanding means. 2. The image processing apparatus according to claim 1, wherein the image information developed in the main scanning direction is repeatedly transferred a predetermined number of times and recorded and reproduced as one image group. 7. The image recording / reproducing control means determines the number of images recordable in the main scanning direction and the number to be reproduced in the sub-scanning direction by the image information recording / reproducing means, The input image information expanding means expands the input image information in the image information storage management means in the main scanning direction based on the number of images recordable in the main scanning direction determined by the image recording and reproduction controlling means. 2. The image processing apparatus according to claim 1, wherein the image processing is performed. 8. The image recording / reproducing control means, based on the size and orientation of a recording medium conveyed by the image information recording / reproducing means, an image recordable in the direction of an image to be reproduced and in the main scanning direction. And the number that can be recorded and reproduced in the sub-scanning direction, and the direction of the image determined by the input image information developing unit and the image recording and reproducing control unit, and recording in the main scanning direction. Based on the number of possible images, the direction of the input image information developed in the image information storage management means, and the image information storage management means based on the number of images recordable in the main scanning direction. Input image information orientation,
2. The image processing apparatus according to claim 1, wherein expansion in the main scanning direction is controlled. 9. A recording image number setting means for setting the number of images to be recorded / reproduced, wherein the image recording / reproduction control means is configured to execute the image recording / reproduction control means based on the number of images set by the recording image number setting means. The image information recording and reproducing means determines the number of images to be recorded and reproduced in the main scanning direction and the number of images to be recorded and reproduced in the sub-scanning direction. 2. The image information storage and management unit according to claim 1, wherein the input image information is expanded in the main scanning direction and stored and managed based on the number of images recordable in the main scanning direction determined by the unit. Image processing device. 10. An image recording / reproducing control unit for setting the number of images to be recorded / reproduced, wherein the image recording / reproducing control unit sets the number of images based on the number of images set by the recorded image number setting unit. The size of the recording medium of the image reproduced by the image information recording / reproducing means,
And the number of images to be recorded and reproduced in the main scanning direction,
Along with determining the number to be recorded and reproduced in the sub-scanning direction, the input image information developing unit is based on the number of images recordable in the main scanning direction determined by the image recording and reproduction control unit. 2. The image processing apparatus according to claim 1, wherein the input image information in the image information storage management means is developed and stored in the main scanning direction. 11. The image information recording / reproducing means includes means for recording / reproducing such that at least one side of the image information to be recorded / reproduced is parallel to and near at least one side of a recording medium on which the image information is recorded. 2. The method according to claim 1, wherein
The image processing apparatus according to any one of the preceding claims.