JP3712489B2 - Image forming apparatus and image forming method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image forming apparatus for photoelectrically reading a film original, performing digital signal processing, exposing a photosensitive material with a light source such as a laser, and obtaining a print of a desired size.
[0002]
[Prior art]
Currently, printing of images taken on photographic film originals such as negative films and reversal films (hereinafter referred to as film originals or simply films) onto photographic materials such as photographic paper is performed by projecting the image of the film original onto the photosensitive material. This is performed by so-called direct exposure in which the photosensitive material is subjected to surface exposure.
[0003]
In contrast, in recent years, a printing system using digital exposure, that is, image information recorded on a film is photoelectrically read, the read image is converted into a digital signal, and then subjected to various image processing for recording. A digital print system has been proposed in which a photosensitive material is scanned and exposed by recording light modulated in accordance with this image information, an image (latent image) is recorded, and developed to be printed. The development of digital photo printers is underway.
[0004]
In the digital printer system, editing layout of print images such as composition of multiple images and image division, editing of characters and images, and various image processing such as color / density adjustment, scaling, and edge enhancement are also free. It is possible to output a finished print that has been freely edited and processed according to the application. Also, conventional direct exposure printing systems cannot reproduce all image density information recorded on film etc. in terms of density resolution, spatial resolution, color / density reproducibility, etc. According to this, it is possible to output a print reproducing almost 100% of the image density information recorded on the film.
Furthermore, according to the digital printer system, it is possible to store (save) the image information of the image recorded on each film and the image processing conditions for the image information in an external memory such as a memory or a floppy disk of the apparatus. Therefore, when performing reprinting or the like, the film as the original image is not necessary, and it is not necessary to set the processing conditions again, so that operations such as reprinting can be performed quickly and efficiently.
[0005]
Such a digital photo print system or digital photo printer basically has an image input device that photoelectrically reads an image recorded on a document such as a film by an image sensor, a display device that displays the read image, and a read device. The image processing apparatus includes an image processing apparatus that performs image processing to determine an exposure condition for image recording, and an image recording apparatus that obtains a print on which a photosensitive material is scanned and exposed in accordance with the determined exposure condition to perform development processing. The present applicant has proposed an apparatus and method for realizing such a digital printing system in Japanese Patent Application Laid-Open Nos. 6-217091, 6-233052, and 6-245062. The gazette discloses an outline of a digital photo printer apparatus.
[0006]
[Problems to be solved by the invention]
Incidentally, even in such a digital print system, generally, as the print size increases, the read image is required to have a high resolution and a high SN ratio (signal / noise ratio). Therefore, in a scanner (image input device) of a digital printing apparatus, in order to read an original image such as a photographic film or a reflected original image at a high resolution, these original pixels are divided into a large number of fine pixels and a large amount of pixels are divided. It is necessary to read the image signal, and in order to obtain a read image with a high S / N ratio, these image signals are processed temporally or spatially. Become.
[0007]
When such image reading is performed, the reading time of one original image by the scanner of the digital printing apparatus becomes long regardless of the print size, which causes a problem that productivity is lowered. Furthermore, since it is necessary to process such a large amount of image signal in order to output it as a high-resolution image print having a high resolution and a high S / N ratio, it is not only for image reading but also for image processing in an image processing apparatus. There is also a problem that it takes time and further reduces productivity.
[0008]
The object of the present invention is to solve the above-mentioned problems of the prior art, and can print a plurality of sizes on a plurality of film originals having different film sizes. An image reading method control (scanning) mode that can read the supported image at a resolution and SN ratio according to the print size (or the number of main sub-pixels of the output image signal) is automatically selected according to the print size and image reading is performed. Accordingly, it is an object of the present invention to provide an image forming apparatus that can perform both the image quality of printed images and the productivity.
[0009]
[Means for Solving the Problems]
  To achieve the above object, according to a first aspect of the present invention, there is provided image reading means for obtaining a digital image signal from image information on a film or a reflection original by photoelectrically reading an image of a photographic film or a reflection original. ,
  Image processing means for generating an output image signal from the digital image signal;
  Image recording means for recording the output image signal on a recording medium;
  In order to control the resolution and signal / noise ratio when the image reading means reads image informationIn addition, the pixel shift that increases the number of read pixels by reading the pixels from the reference pixel and the spatial averaging or temporal averaging of the image signals of the read pixels are set in combination.Registration means for registering several reading method control modes and the number of main sub-pixels or print size of the output image signal in association with each other;
  By selecting the number of main sub-pixels or the print size of the output image signal, the corresponding reading method control mode is automatically determined from the several reading method control modes, and the determined reading method control is performed. And reading method control means for performing image reading control using the mode,
In one of the several reading mode control modes, the pixel is read out from the reference pixel, and the image signal of the read pixel is spatially averaged.An image forming apparatus characterized by this is provided.
  The second aspect of the present invention is a method for photoelectrically reading an image of a photographic film or a reflection original to read a digital image signal from image information on the film or the reflection original.
  To control resolution and signal / noise ratio when reading image informationIn addition, the pixel shift that increases the number of read pixels by reading the pixels from the reference pixel and the spatial averaging or temporal averaging of the image signals of the read pixels are set in combination.Register several reading method control modes in association with the number of main sub-pixels or print size of the output image signal,
  By selecting the number of main sub-pixels or the print size of the output image signal, the corresponding reading method control mode is automatically determined from the several reading method control modes, and the determined reading method control is performed. Perform image reading control using the mode,
  Generating an output image signal from the digital image signal;
  The present invention provides an image forming method, wherein the output image signal is recorded on a recording medium.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
An image forming apparatus according to the present invention will be described below in detail based on a preferred embodiment shown in the accompanying drawings.
[0011]
FIG. 1 is a schematic diagram showing a block diagram of an embodiment of a digital printing apparatus to which the image forming apparatus of the present invention is applied.
A digital printing apparatus 10 shown in FIG. 1 includes an image input device 12 that constitutes an image reading unit of the present invention, which photoelectrically reads a loaded image of a film document having a different film size, and reading conditions and modes in the image input device 12. (Reading method control mode) setting and control of the image input device 12 based on the setting, in particular, a reading method control mode (hereinafter, referred to as the number of main sub-pixels or print size of the output image signal for print production in the present invention). A control device 14 including a reading method control unit and an image processing unit of the present invention, which performs setting of a scan mode), image processing of the read image signal, automatic setting of image processing conditions (auto setup), and the like; The photosensitive material is subjected to image exposure based on the image signal processed by the apparatus 14 and developed to carry a reproduced image. The image output device 16 that constitutes the image recording means of the present invention that outputs a print, and the original image read by the image input device 12 are displayed and reproduced according to the print size output by the image output device 16. Image area (finished print area) and image display device (monitor) 18 for displaying a trimming area, and an image signal of a document image read by the image input device 12, or processed by the control device 14 or an image Server or HD that stores image signals used in the output device 16, as well as image processing conditions, exposure conditions, and photosensitive material processing conditions, or magnetic recording such as MO (magneto-optical recording medium), magnetic tape, and FD. The external storage device 20 composed of a medium and its driver, and information such as various condition settings, processing selections, and corrections are input. And a data input device 22 such as a keyboard 22a and a mouse 22b for.
[0012]
  An image input device (hereinafter referred to as an input device) 12 shown in FIG. 2 is a long negative film or a reversal film, and strips on which a large number of images are taken, or a single reversal film is usually a frame. An apparatus for photoelectrically reading an image photographed on a film original using films of different types and sizes, such as slides fixed on a (mount), as a film original. Unit 24, carrier base 26, imaging unit 28 incorporating a zoom lens, image sensor 30 serving as an area sensor, and film carrier 32 and slide carrier 34 (see FIG. 3) that are interchangeably mounted on carrier base 26. Have a career.
  In the input device 12, the film carrier 32 or the slide carrier 34 mounted on the carrier base 26 conveys the strips A or the slide B in the direction of the arrow x in the drawing and stops at the reading position Z. Is irradiated onto the film original image to obtain projection light that carries the image photographed on the film original, and the projection light is imaged on the image sensor 30 in the imaging unit 28, and photoelectrically converted in the image sensor 30. By obtaining an image signal, an image photographed on a film original is read two-dimensionally as an image signal. Such control of the input device 12 is performed by an input control unit of the control device 14 described later.(Hereafter referred to as the control unit)70 (see FIGS. 5 and 6).
[0013]
The light source unit 24 is used to irradiate the film original (strips A or slide B) so that the image original 30 can be separated into the three primary colors R, G, and B by the image sensor 30 and read with high accuracy. Each color light having a sufficient amount of diffused light is generated. In the input device 12 shown in the figure, the strips A are irradiated from below to obtain projection light, which is below the carrier base 26 of the optical frame 13. Located, has a light source 35, a reflector 35a, an aperture 36, a color filter 38, and a diffusion box 40. In addition to this, the light source unit 24 is provided with a cooling fan or the like for cooling various members such as the light source 35, and further, a shutter for shielding light emitted from the light source 35 as necessary. May be provided.
As the light source 35, various known light sources capable of emitting reading light having a sufficient amount of light for image reading by the image sensor 30 can be used, and examples thereof include a halogen lamp, a xenon lamp, and a mercury lamp.
[0014]
The diaphragm 36 adjusts the amount of light from the light source 35. In the illustrated example, two ND filters having a logarithmic curve drawn at the light shielding portion and having different amounts of passing light in the direction orthogonal to the optical axis L are used. The amount of light from the light source 35 to the film is adjusted by moving them closer to each other in the direction perpendicular to the optical axis L.
The color filter 38 has three color filters, an R (red) filter, a G (green) filter, and a B (blue) filter, in a disk-shaped member. By rotating, the color of the filter acting on the optical axis L is switched, and an R filter, a G filter, and a B filter are sequentially inserted into the optical path L, and an image photographed on the film original is changed to the three primary colors R, G, and B. Decompose and read.
The diffusion box 40 is emitted from the light source 35, the amount of light is adjusted by the diaphragm 36, diffuses the reading light passing through the color filter, and the surface of the reading light incident on the film is orthogonal to the optical axis L. In the example shown in the figure, the diffuser plate is arranged on the upper and lower surfaces of a square prism whose inner surface is a mirror surface. Is available.
[0015]
A carrier base 26 is disposed above the light source unit 24. The carrier base 26 is a part that holds a film carrier 32 or a slide carrier 34 described later on the upper surface thereof and holds it at a predetermined position, and is fixed perpendicularly to the optical frame 13. The carrier base 26 is formed with an opening (not shown) for allowing the light from the light source unit 24 to pass therethrough at a portion corresponding to the optical axis L. Note that this opening corresponds to the maximum screen size so that light from the light source unit 24 in the input device 12 is sufficiently irradiated to the entire surface of the maximum image plane size (size) of the film document that can be read by the image sensor 30. Is set.
[0016]
On the upper surface of the carrier base 26, guide rails 42 and 42 are formed in a direction from the front side in the figure toward the optical frame 13, that is, in an arrow y direction orthogonal to the arrow x direction serving as the transport direction, while the film carrier Grooves 44, 44 that fit the guide rails 42, 42 are formed on the bottom surfaces of the 32 and the slide carrier 34. In both the film carrier 32 and the slide carrier 34, the grooves 44, 44 are fitted into the guide rails 42, 42 of the carrier base 26, and the end surface on the back side in the figure contacts the optical frame 13 in the arrow y direction. By pushing and fixing until contact, the positions in the directions of the arrows x and y are defined, and are positioned and placed at predetermined positions on the carrier base 26.
These carriers 32 and 34 can be removed from the carrier base 26 and exchanged with each other very easily by pulling them in the front direction in the figure and removing the grooves 44 and 44 from the guide rails 42 and 42. The means for mounting the film carrier 32, the slide carrier 34, etc. at predetermined positions on the carrier base 26 is not limited to the method using such a guide rail and a groove fitted to the guide rail. It is also possible to use holes that fit or engage with each other, contact members that engage with each other, various clamping members, adsorption by a magnet, and the like.
[0017]
The film carrier 32 conveys a long negative film or reversal film on which a large number of images have been photographed, so-called strips (sleeves) A, in the longitudinal direction thereof, and each image photographed on the strips A is an optical axis L. The paper is sequentially conveyed to a predetermined position above, that is, a reading position Z corresponding to the opening of the carrier base 26 (not shown) and used for reading. A guide groove 46 is formed on the upper surface of the film carrier 32 so as to extend from one end to the other at a position that intersects the optical axis L in the transport direction indicated by the arrow x. The guide groove 46 is a groove having substantially the same width as the strips A, and the strips A are conveyed while the longitudinal direction thereof coincides with the x direction in a state of being inserted into the guide grooves 46. , And conveyed to a reading position Z on the optical axis L. Accordingly, the depth of the guide groove 46 is set so that the image surface (that is, the emulsion surface) of the strips A is at a predetermined position in the optical axis L direction (focal depth direction).
[0018]
Further, an opening through which light from the light source unit 24 passes is formed at the reading position Z of the film carrier 32. This opening functions as a mask for determining the size of the image of the film original read by the image sensor 30 in the input device 12, and the shape and size (size) of the opening, that is, the size of the opening area of the mask is determined by the film. In accordance with the screen size (size) of a film document placed on the carrier 32, for example, 135-size strips A, the screen size is set so as to be inscribed at the very minimum so that the image is minimized. Note that the opening at the reading position Z of the film carrier 32 occupies a different predetermined position on the same optical axis L as the opening of the carrier base 26 described above, and is emitted from the light source unit 24 to open the opening of the carrier base 26. Of course, the light passing therethrough can sufficiently irradiate the entire opening regardless of the film carrier 32 on which a film document of any screen size is placed. Therefore, the light emitted from the light source unit 24 and defined by the mask can sufficiently irradiate the entire screen size of the original image that can be read by the input device 12. The opening formed in the film carrier 32 may be a size corresponding to the opening of the carrier base 26, and the mask corresponding to various size films may be exchanged to be mounted on the film carrier 32.
[0019]
In the guide groove 46, the transport means 48 of the strips A, the film crimping unit 50, and the screen detection sensor 52 are arranged from the upstream in the x direction to the downstream.
The transport means 48 is composed of a motor 48a and a transport roller 48b, and intermittently transports the strips A in the direction of the arrow x. The strips are detected by a screen detection sensor 52 for detecting a photographed image or DX code. When it is detected that the image of A has come to the reading position Z, it stops, and when the reading end signal is received from the control device 14, the conveyance of the strips A is started again, and the next image is conveyed to the reading position Z.
The film crimping unit 50 rotates a crimping member 50b having an opening for allowing the projection light of the strips A to pass around the pivot shaft 50a in the direction opposite to the arrow b, so that the reading position Z is read at the time of image reading. By pressing the strips A disposed in the guide groove 46 into the guide groove 46, the curls of the strips A are corrected to hold the entire surface of the image at a predetermined position in the direction of the optical axis L, that is, the original placement position.
The transport of the strips A in the film carrier 32 and the operation of the film crimping unit 50 are not limited to those that are automatically controlled using the screen detection sensor 52 or the like as in the above example, but semi-automatically or by the operator The crimping member 50b may be manually rotated and / or the conveyance unit 48 may be stopped and driven.
[0020]
The slide carrier 34 shown in FIG. 3 is mounted on the carrier base 26 in exchange for the film carrier 32 shown in FIG. 2, and a so-called slide B formed by holding a film on which an image is taken with a frame body in the direction of the arrow x. The slide B is conveyed, stopped at the photographing position Z, used for image reading, and the slide B that has been read is collected. A guide groove 54 that guides the slide B is formed on the upper surface of the slide carrier 34 so as to extend from one end to the other at a position that intersects the optical axis L in the conveyance direction of the slide B indicated by the arrow x. . The depth of the guide groove 54 is set so that the image plane of the slide B is substantially at a predetermined position in the optical axis L direction (focal depth direction). Further, in the slide carrier 34, similarly to the film carrier 22, an opening functioning as a mask for allowing light from the light source unit 24 to pass through is formed at the reading position Z. As in the case of the film carrier 22, the mask may be separated and configured to be replaceable according to the size of the slide B.
[0021]
A cover 56 is disposed in the vicinity of the reading position Z on the upper surface of the slide carrier 34. The cover 56 is formed with a passage hole 56a through which the projection light of the slide B passes on the upper surface, and covers the slide B at the reading position Z during normal reading, but can be rotated in the direction of arrow c in the figure, and if necessary The reading position Z can be opened. Although not shown below the cover 56, it has a guide groove 54 that is slightly wider. In the vicinity of the entrance and the reading position Z, the slide B automatically fed by the operator and the conveying means are automatically provided. A sensor for detecting the tip of the slide B conveyed to the guide groove 54 is disposed, and a plurality of, for example, six rollers for conveying the slide B are disposed on both sides of the wide portion of the guide groove 54, respectively. This roller is a transport roller for slide B that is rotated at a predetermined speed by a drive source (not shown), and the lower roller is a driven roller that can bias slide B upward by biasing means such as a spring. At the reading position Z, if necessary, a slide presser that presses the slide B against the guide groove 54 at the leading end thereof and corrects the distortion or lifting of the slide B (the frame body) is arranged at the time of reading. May be.
[0022]
A slide collection box 58 for collecting the slide B that has been read is disposed downstream of the cover 56 (in the direction of the arrow x). The slide collection box 58 in the illustrated example is configured to be inserted under the slide B that has already been collected and accommodate the slide B. The slide B that has been read is sequentially stacked and collected from below. The In addition, the slide collection box 58 may be a box that accommodates the slide B that has been dropped by the pushing of the slide B that is transported later.
[0023]
In the present invention, the carrier for placing the film original at the reading position is preferably a replaceable carrier corresponding to one to one every time the type and size of the film original are different. In addition to the above-described film carrier 32 and slide carrier 34 that automatically or semi-automatically convey the slide B to the reading position Z, an opening for allowing light from the light source unit 24 to pass therethrough is formed at the reading position Z, and guide rails 42 and 42 are provided. Any carrier can be used as long as it has a groove that fits in, and even if the operator is a manual carrier that fixes the strip or slide in place, the operator can place the film or slide in any position. It may be a trimming carrier or the like that is arranged and read.
Each of these carriers is given an ID code, and when each carrier is attached to the carrier base 26 of the optical frame 13 and is electrically connected, the corresponding carrier ID code is transmitted to the control device 14. Composed.
[0024]
In the apparatus of the present invention, the structure of the carrier base 26 for mounting the carrier, for example, the structure of the guide rail, the carrier lock mechanism, etc., and the connection method of the electrical system such as the power supply and signal connector are common to the conventional analog printing apparatus. It is assumed that the carrier used in the conventional analog printing apparatus, particularly the film carrier, and the carrier such as the film carrier 32 and the slide carrier 34 used in the digital printing apparatus 10 of the present invention are compatible. It is preferable to leave. Of course, the carrier for the analog printing apparatus and the carrier for the digital printing apparatus 10 may not have the same function. However, among the functions of the carrier for the analog printing apparatus in the related art, the carrier for the digital printing apparatus is used. It is preferable that the functions that can be used in the analog printing apparatus among the functions that can be used or the carrier functions for the digital printing apparatus be used as much as possible.
[0025]
  On the upper part of the optical frame 13, an imaging unit 28 that images the projection light of the strips A and the slide B on the image sensor 30 is disposed. The imaging unit 28 is a zoom lens unit that is suspended from a surface plate 60 fixed to the optical frame 13.(Lens unit)62, a magnification adjustment motor 63 and a focus adjustment motor 64. The lens unit 62 changes the optical magnification according to the size of the strips A and the slide B and the trimming size, and the maximum size (that is, the necessary image area is the image sensor that can receive the projection light size by the image sensor 30). A zoom lens group 66 in which a known zoom lens is incorporated to adjust the image to the image sensor 30 by adjusting the size to be inscribed on or close to the light receiving surface 30, and above (in the optical axis L direction). And a focus lens group 68 incorporating a known focus adjustment lens for adjusting the focus of the projection light on the light receiving surface of the image sensor 30, which is located on the downstream side.
[0026]
  The adjustment gear 68a of the focus lens group 68 meshes with a gear 64a rotated by the focus adjustment motor 64, and the focus lens group 68 is adjusted in focus by the focus adjustment motor 64, that is, moved and adjusted to the in-focus position. Is done. Further, in the zoom lens group 66, the adjustment gear 66a meshes with a gear 63a rotated by a magnification adjustment motor 63 which is a zoom motor.Magnification adjustmentIt is moved and adjusted in the direction of the optical axis L so that the image size on the image sensor 30 corresponding to the optical magnification set by the motor 63 is obtained. The driving of the focus adjustment motor 64 is controlled by the automatic focus adjustment means 80 of the control device 14, and the input device 12 in the illustrated example uses an TTL (Through The Lens) method to read an image read by the image sensor 30 and its image. Automatic focus adjustment (autofocus: AF) is performed using the contrast. Note that a temperature sensor such as a thermistor may be attached to the imaging unit 28 in order to correct the variation in the focal position of the lens unit 62 due to the variation in the lens temperature.
[0027]
The projection light of the strips A and the slide B is imaged on the image sensor 30 by the lens unit 62 and is read photoelectrically. A known shutter used for dark current correction or the like may be disposed between the lens unit 62 and the image sensor 30.
In the input device 12 that performs two-dimensional image reading, the image sensor 30 is an area sensor, for example, a CCD sensor of 1380 × 920 pixels.
Here, in the apparatus of the present invention, the image sensor 30 is configured to be movable in the x direction and the y direction by an amount corresponding to a half pixel by the movement control circuit 30a in the xy direction. The number of read pixels is apparently increased up to four times, and the resolution can be increased.
The reading method control of the present invention using pixel shift will be described later.
The image input device 12 is basically configured as described above.
[0028]
Note that multiplication of the number of read pixels of the image sensor 30 by pixel shifting used in the present invention is performed as follows, but the present invention is not limited to this.
In the present invention, the image sensor 30 includes a CCD element, an xy stage that supports the CCD element so as to be movable in the xy direction, and a piezo driver that includes a piezo element that drives the xy stage in the xy direction. It has a CCD pixel shifting unit. The image sensor 30 drives a piezo driver with a predetermined period and a predetermined amplitude by an xy movement control circuit 30a, thereby causing the CCD element itself to vibrate with a predetermined amplitude and a predetermined amplitude independently in the xy direction. Multiplication, here quadrupling can be performed.
[0029]
  Specifically, for example, as shown in FIG. 4, when A is the reference reading position, the half pixel of the CCD is set as the amplitude, and the driving frequency in the x (main scanning pixel address) direction is made to coincide with the reading frequency of the CCD. The driving frequency in the y (sub-scanning pixel address) direction is set to half (1/2) of the reading frequency of the CCD, whereby A → B → C → D from the reference position A for one pixel of the image sensor (CCD) 30. The number of pixels to be read can be quadrupled. Of course, the four pixels A, B, C, and D are read in the same CCD readout field (one line in the main scanning direction).EvenThe main scanning lines are sequentially moved in the sub-scanning direction and scanned one after another to read pixel data. Further, the reading order of the four pixels A, B, C, and D can be set as appropriate.
[0030]
  A signal from the image sensor 30 is output to the control device 14.
  As shown in FIG. 1, the control device 14 controls each part and the whole of the image input device 12 and the digital printing device 10, and controls the control unit 70 that constitutes the reading method control means of the present invention, and the input device 12. A signal processing device 72 that receives an output signal from the image sensor 30 and performs predetermined signal processing to obtain an input image signal, and outputs the obtained image signal to the image output device 16 as required or desired. And an image processing device 74 constituting the image processing means of the present invention, which outputs as an image signal.
  The control unit 70 not only controls the signal processing operation of the signal processing device 72 but also controls each unit and the whole of the input device 12, and according to the number of main and sub pixels of the output image signal or the print size in the present invention. Read mode control mode, that is, automatic setting of the scan mode and control of reading by the image sensor 30 according to the set scan mode, control of the xy movement control circuit 30a of the image sensor 30, and calculation processing of the read signal CPU 76 constituting reading method control means to be implemented, reading optical magnification information, zoom lens movement amount information, image sensor information, carrier information, output pixel density, print size, magazine information, output margin, input / output pixel loss Read by the memory 78 storing the image and the image sensor 30GetAn automatic focus adjustment unit 80 for performing automatic focus adjustment using the obtained image, an image rotation unit 82, a negative / positive conversion unit 84, and the like. Further, the control unit 70 is configured to operate the input device 12, read conditions such as reading optical magnification, scan mode settings, print size (output image size) and main subject settings, operation instructions such as color / density correction, A keyboard 22a and a mouse 22b for inputting and a monitor 20 for displaying an image read by the image sensor 30 are connected.
[0031]
FIG. 5 shows a detailed block diagram of an embodiment of the control unit 70 and the signal processing device 72. In the control unit 70, the image sensor (CCD) 30 is connected to the CPU bus via the movement control circuit 30a in the xy direction for performing pixel shifting that apparently increases the number of read pixels according to the set scan mode. Connected. Image information read by the image sensor 30 is input to the signal processing device 72. In the signal processing device 72, the analog image data read by the image sensor 30 is converted into digital image data by the A / D converter 86, the DC offset is corrected by the offset correction circuit 87, and then the dark correction circuit 88. Dark correction is applied. Thereafter, the LOG conversion circuit 89 performs LOG conversion, and after the shading correction circuit 90 performs shading correction, a required calculation process is performed in accordance with the scan mode to obtain an input image signal, which is then stored in the frame memory 91. And output to the image processing device 74.
[0032]
  The image data corrected in the dark by the dark correction circuit 88 is input to the automatic focus adjustment means 80. First, the automatic focus adjustment unit 80 controls the focus adjustment motor 64 to move the lens unit 62 to each point at a predetermined interval in a predetermined search area to obtain dark-corrected image data at each point. By repeatedly obtaining the image contrast integrated value, the position where this is the maximum is determined as the focus position (focus position), and this focus position is determined via the CPU bus.Focus adjustmentThe motor 64 is controlled and the lens unit 62 is set.
  On the other hand, the carrier ID code loaded from the film ID 32 for the strips A or the slide carrier 34 for the slide B is input and selected from the keyboard 22a and the mouse 22b. Information such as added or modified registered print size, reading conditions such as reading optical magnification, recording conditions such as color and / or density correction, dodging correction, gradation correction, and the like is transmitted via the CPU bus to the CPU 76 and the memory 78. Are input to the automatic focus adjustment means 80.
  Note that the light source 35, the diaphragm (iris diaphragm) 36, and the color filter 38 of the light source unit 44 are respectively transmitted by the light source control circuit 35b, the diaphragm control circuit 36a, and the color filter control circuit 38a that are connected to the CPU 76 via the CPU bus. The intensity, opening, and color filter type are controlled.
[0033]
The CPU 76 has a reading method control means that is a feature of the present invention. This reading method control means controls the print size and output pixel size (output image signal) in order to control the resolution and signal / noise ratio (SN ratio) of the read image (signal) read by the image sensor 30 in the image input device 12. The scan mode set in accordance with the number of main sub-pixels) is selected, and the film original image projected onto the image sensor 30 is automatically read in the selected scan mode.
Detailed functions of each reading method control (scan) mode and reading method control means will be described later.
[0034]
  In the memory 78, reading optical magnification information such as each zoom position of the zoom lens 62 corresponding to the reading optical magnification and its fine adjustment value, the size (dimension information in the main / sub scanning direction), the pixel density, and the effective pixel of the image sensor 30 are stored. Image sensor information such as area (number), reading method information corresponding to the scan mode, ID code of the carrier mounted on the carrier base 26, mask size of this carrier (dimension information in the main / sub scanning direction) and set in this carrier Carrier information such as the type and size of the film to be printed, the output pixel density of the image output device 16, the registered print size (dimension information of long and short sides (vertical and horizontal)), and the number of main sub-pixels of the output image signal corresponding thereto The ID code of the magazine 114 (see FIG. 7) loaded in the image output device 16 and the size (width) of the photosensitive material stored in the magazine Magazine information broadcast) and type, etc., meandering and the light beam scanning apparatus of the photosensitive material in the conveying apparatus 100 of the image output machine 16 102 (see FIG. 7) by the main scanning length error, etc.TheOutput output allowance in consideration, input pixel loss (number of pixels) due to image processing such as LPF (low pass filter) and electronic zooming in image processing device 74 and output pixel loss due to image processing such as USM (unsharpness mask) ( Various information such as information necessary for operation control of the digital printing apparatus 10 of the present invention is stored, including information such as the number of pixels).
[0035]
Also, the image rotation control means 82 provided in the control unit 70 transmits information on the photosensitive material loaded from the image output machine 16, in particular, width information. It is necessary to determine whether the recording direction of the output image, that is, the main scanning direction, is the vertical or horizontal direction of the read image from the printed print size information, and to convert the vertical or horizontal direction of the read image, that is, to rotate it by 90 ° When the rotation is necessary, the image is rotated.
By the way, in the image output device 16, a long photosensitive material wound in a roll shape is used, and the photosensitive material conveyed in the sub-scanning direction is one-dimensional direction substantially orthogonal to the sub-scanning conveying direction, that is, the main scanning direction. The photosensitive material is two-dimensionally exposed by scanning exposure (printing) with a light beam deflected in the direction. For this reason, depending on the width of the photosensitive material, it is uniquely determined whether the main scanning direction of exposure is the longitudinal direction of the set print size or the lateral direction.
[0036]
  On the other hand, in the input device 12, the directions of the strips A set on the film carrier 32 and the slide B set on the slide carrier 34 are fixed, and the original image area read by the image sensor 30 is to be made as large as possible. For example, the direction of the film document, that is, the shape of the document image, and hence the shape of the carrier mask (for example, particularly the aspect ratio) is uniquely determined. For this reason, one line of the document image read by the input device 12 may not match one line in the main scanning direction of the image output device 16. As a result, the image rotation control means 82 processes the image signal and rotates the image (image area) by 90 ° before the image signal stored in the frame memory 91 is exposed at least by the image output device 16. In other words, the line direction of the output image can be changed by rearranging the pixels or changing the access order of the frame memory addresses based on the conversion formula.WhenLine direction of exposureWhenMust be matched.
[0037]
Further, the control unit 70 is provided with a positive / negative conversion circuit 84 that performs positive / negative inversion on the image data subjected to predetermined signal processing by the signal processing device 72. In the case where the strip A or the slide B is a reversal film, the image information subjected to predetermined image processing is converted before being output to the image output device 16 and is output as a negative image (or vice versa). It is. The method of positive-to-negative conversion or negative-to-positive conversion is not particularly limited, and a known conversion method (image processing method) may be used.
In the present invention, whether the strip A or the slide B is a negative film or a reversal film is stored in the memory 78 by the carrier ID code transmitted from the carrier ID determination means 31 when the carrier is loaded. However, the present invention is not limited to this, and may be input by an operator.
[0038]
  By the way, as is well known, in various conventional printers, accurate reading (typically for image output) is usually performed.finePrior to (main) scanning, pre-scanning is performed to roughly read a document image in order to set image processing conditions. Therefore, as shown in FIG. 6, the frame memory 91 of the signal processing device 72 shown in FIG. 5 includes a pre-scan frame memory 91a and a main-scan frame memory 91b configured as a toggle memory. . The image processing apparatus 74 used in the present invention converts the image signal of the film original stored in the frame memories 91a and 91b, for example, the image signals of the three primary colors R, G, and B of one image. Necessary image processing is performed.
[0039]
As shown in FIG. 6, the image processing apparatus 74 performs image processing on a prescan image signal stored in the prescan frame memory 91 a for display on the monitor 18, for example, a G color image signal. Cut out image signals of pixels in the cut-out pixel area (number of pixels) determined by the method of the present invention from the main scan image signal stored in the main scan frame memory 91b for output to the processing circuit 92 and the image output device 16. Then, image processing for appropriate printing is performed, LPF (low-pass filter) processing for dodging processing is performed, and the cut-out image area (number of pixels) is enlarged / reduced (enlarged / reduced) according to the electronic magnification determined in the present invention ) Processing, and further, USM (unsharpness mask) processing for sharpening the image to produce an output image signal The image processing conditions of the main scan image signal in the recording image processing circuit 94 are set from the image processing circuit 94, the prescan image signal, the main subject set as necessary, and desired processing conditions input by the operator. And a CPU 98 constituting the image processing condition setting means 96 and the like.
[0040]
In the illustrated example, an image is read by the input device 12 and processed by the control device 14, but the present invention can also store a storage device 20, such as a server, HD, MO, and FD. The image signal stored in the medium may be read into the frame memory 91 of the control device 14 and the same processing as described above may be performed. Conversely, the image signal stored in the frame memory 91 is stored in the storage device 20. And may be used for later use.
The control device 14 of the present invention is basically configured as described above.
[0041]
Next, the image output device 16 receives an image signal from the control device 14 and outputs a print on which a document image is reproduced. FIG. 7 shows a schematic diagram thereof.
As shown in the figure, the image output device 16 basically includes a transport device 100, a light beam scanning device 102, a printing transport device 106 having an electrical component 104 in which a control board, a power supply unit, and the like are housed, and a developing device. The apparatus 108, the drying apparatus 110, and the discharge apparatus 112 are integrated and configured as one apparatus, and the long photosensitive material P wound in a roll shape is pulled out and conveyed in the sub-scanning direction. Meanwhile, two-dimensional scanning exposure is performed with a light beam deflected in the main scanning direction orthogonal to the sub-scanning direction, the exposed photosensitive material P is developed, dried and cut, and output as a print.
[0042]
The transfer device 100 of the printing transfer device 106 includes a photosensitive material supply unit 116 in which a magazine 114 that stores the photosensitive material P wound in a roll shape is loaded, and the extracted photosensitive material P while conveying the drawn photosensitive material P along a predetermined path. An image position information forming unit 118 that records image position information such as a frame punch and a sort punch, an exposure unit 120 that performs image exposure (printing) by the light beam scanning device 102, a back print unit 122 that performs back printing, and a reservoir 124, a photosensitive material discharge portion 126, and a conveying means for conveying the photosensitive material P through a predetermined path passing through them.
In the photosensitive material supply unit 116, when the magazine 114 is loaded, the ID code of the loaded magazine 114 is automatically read by a microswitch or the like attached in advance. The code is transmitted to the control device 14, and the CPU 76 can detect the width information (size) of the photosensitive material registered in the memory 78.
Note that the method for detecting the size of the photosensitive material P is not limited to this, and a method using a bar code or a method in which an operator inputs data to the control device 14 with the keyboard 22a or the mouse 22b may be used.
[0043]
  The light beam scanning device 102 includes a light source that emits a light beam corresponding to red (R) exposure, green (G) exposure, and blue (B) exposure, modulation means such as an AOM (acousto-optic modulator), a polygon mirror, and the like. A well-known light beam scanning device that includes an optical deflector, an fθ lens, and the like can be used.
  On the other hand, the sub-scanning conveying means of the exposure unit 120 conveys the photosensitive material P in the sub-scanning direction (arrow d direction) substantially orthogonal to the main scanning direction (direction perpendicular to the paper surface) while holding the photosensitive material P at a predetermined exposure position. It comprises an exposure drum 128 and two nip rollers 130 and 130 that press the exposure drum 128 with an exposure position (scanning line) sandwiched in the sub-scanning direction.DoYou may have. Note that before and after the exposure unit 120, punch hole punching of the image position information forming unit 118 and the influence of the back print of the back print unit 122 on the sub scanning conveyance unit, that is, fluctuation of the sub scanning conveyance speed of the photosensitive material P. In order to eliminate the occurrence of the above, a loop of the photosensitive material P is provided.
[0044]
The reservoir 124 is a place where the exposed photosensitive material P is temporarily stored by placing a loop in order to absorb a difference in processing speed between the printing conveyance apparatus 106 and the developing apparatus 108 having a relatively low processing speed. The photosensitive material discharge unit 126 is a part for sending the exposed photosensitive material P to the developing device 108. In order to prevent unnecessary pulling and damage of the photosensitive material P by the developing device 108, a loop is provided. In addition, when trouble or the like occurs in the developing device 108, a cutter (not shown) for urgently cutting the exposed photosensitive material P in order to rescue the undeveloped photosensitive material P in the transport device 100, particularly the reservoir 124, is provided. Be placed.
[0045]
The developing device 108 is a wet development processing device according to the type of the photosensitive material P to be used, and includes a color developing tank 132, a bleach-fixing tank 134, and a water washing tank 136. The exposed photosensitive material P is transported by a transport roller or the like and sequentially immersed in each processing tank, subjected to predetermined processing in each processing tank and developed, and a latent image is visualized. The developed photosensitive material P is then dried by a known method in the drying device 110 and conveyed to the discharge device 112.
[0046]
The discharge device 112 includes a cutting unit 138 and a sorter 140. The cutting unit 138 detects a frame punch and cuts the photosensitive material P accordingly to obtain a finished print. The sorter 140 is a normal sorter having a large number of shelves. The sorter 140 rotates or slides according to the detection result of the sort information by the cutting unit 138, and switches the shelves for storing the finished prints. A predetermined number of finished prints are sorted and stored.
Note that the image output device 16 in the illustrated example is formed by integrating the printing / conveying device 106 and the photosensitive material processing device including the developing device 108, the drying device 110, and the discharge device 112, but is not limited thereto. Alternatively, the photosensitive material processing apparatus may not be provided, and the undeveloped exposed photosensitive material may be taken up and subjected to development processing in another dedicated developing machine.
[0047]
Incidentally, the digital printing apparatus 10 of the present invention shown in FIG. 1 can set a plurality of sizes of film originals to be subjects (processing objects) and output print sizes, that is, in the memory 78 of the control apparatus 14 shown in FIG. A plurality of settings can be set via the CPU 76 and can be arbitrarily combined.
The film document has a dedicated carrier (see the film carrier 32 in FIG. 2 and the slide carrier 34 in FIG. 3) for each size and type, and is detachable from the carrier base 26 of the image input apparatus 12 shown in FIG. It has become. When a carrier, for example, a film carrier 32 is mounted on the carrier base 26 as shown in FIG. 2, the carrier ID code of the film carrier 32 is transmitted to the CPU 76 and recognized. At the same time, the magazine ID code of the magazine loaded in the transport device is transmitted from the image output machine 16 to the CPU 76 and recognized. The memory 78 of the control device 14 stores mask dimension information of the film document, width information of the photosensitive material, and the like, but these information cannot be rewritten by the user.
[0048]
On the other hand, a plurality of print sizes to be output are set in the memory 78 at the time of shipment from the factory. The print sizes registered in the memory 78 are displayed as a list of print sizes on the screen of the monitor 18 via the CPU 76. The user selects a desired print size displayed on the screen of the monitor 18 using a data input device such as a keyboard 22a or a mouse 22b. If the desired print size is not registered, the user can newly register or modify the print size using the keyboard 22a or the like, and can rewrite the contents of the memory 78. In the digital printing apparatus 10 shown in the drawing, the standard optical magnification that is uniquely determined only by the carrier ID code is stored in the memory 78 at the time of shipment from the factory.
[0049]
In the present invention, in order to control the resolution and S / N ratio of the image read by the image sensor 30, the reading method control means of the CPU 76 uses the print size or the number of main and sub pixels of the output image signal (hereinafter collectively referred to as output print). At least three scan modes selected according to size) are set in the CPU 76.
Here, in the present invention, the number of pixels of the image sensor 30 is 1380 × 920 pixels. However, by performing pixel shifting using the xy movement control circuit 30a, the reading image sensor 30 of 2760 × 1840 pixels. The number of read pixels is quadrupled to enable high resolution. On the other hand, in the present invention, the S / N ratio of the read image (image signal) can be increased by spatially averaging or temporally averaging the image signals of the pixels read by the image sensor 30.
[0050]
In the present invention, by combining the pixel shift for increasing the resolution and the space or time average of the read pixels for increasing the S / N ratio, for example, the following three scans are performed according to the output print size. The mode is set. Here, the image sensor (CCD) 30 uses an area sensor having an effective reading pixel number of 1380 pixels × 920 pixels.
(I) When the output print size is less than the king size (102 × 152 mm), the scan 1 mode is set. In the scan 1 mode, the number of read pixels of the image sensor 30 is quadrupled by pixel shifting. However, since the output print size is not large if it is less than the king size, a high SN ratio is required rather than a high resolution. The image data of the four times read pixel number (2760 × 1840 pixels) is averaged by adding four pixels for four pixels, thereby returning the number of generated pixels to the original number of read pixels (1380 × 920 pixels). By doing so, spatial averaging is performed.
[0051]
(Ii) When the output print size is equal to or larger than the king size and smaller than 2L size (127 × 178 mm), the scan 2 mode is set. In the scan 2 mode, since the output print size is relatively large, priority is given to high resolution over high SN ratio, and only four times the number of read pixels of the image sensor 30 by pixel shifting is performed. Therefore, the number of generated pixels is 2760 × 1840 pixels.
 (iii) When the output print size is 2L or larger, the scan 3 mode is set. In this scan 3 mode, since the output print size is large, both high resolution and a high S / N ratio are required. Therefore, the number of read pixels is increased by four times by pixel shifting to increase the resolution. Reading the doubled pixel count is repeated four times, and the time average of the image data of the quadrupled read pixel count is performed by adding and averaging four times for each quadrupled pixel. The signal-to-noise ratio is high.
[0052]
By the way, in the example described above, an example in which three scan modes are set according to the print size has been described. However, the present invention is not limited to this, and an output print size that is smaller than the king size, such as index printing or solid printing, etc. In other cases and in other special cases, scan 0 with all pixels (1390 × 920 pixels) of the image sensor 30 as the number of generated pixels is performed without increasing the resolution by pixel shifting or increasing the SN ratio by averaging. A mode may be provided. Of course, in the present invention, it is possible to provide a scan mode other than this, including the contents of the scan mode, that is, the multiplication of the read pixel by pixel shift or the like, and the combination of space and time average, for example, both. Various changes may be made.
[0053]
In the above example, the scan mode is set according to the print size. However, in the present invention, these are registered in the CPU 76 as default values so that the user can set the default values from the outside. By doing so, the relationship between the print size and the scan mode can be changed, and can be arbitrarily set and registered.
FIG. 8 shows an example of the display screen of the monitor 18 regarding the scan mode registration that can be performed in the present invention, that is, the scan mode registration screen.
[0054]
The user activates “scan mode registration” by the CPU 76 of the control unit 70 using the input device 22, and displays a scan mode registration screen 18 a as shown in FIG. 8 on the monitor 18. Here, a scan mode corresponding to the print size can be registered for each type of document. This screen 18a shows a state in which “135 transparent negative film” is selected in the display column D1 as a document. By clicking the arrow in the display column D1 with the mouse 22b or the like, the document in the display column D1 is displayed. You can switch the display and make settings from among the registered documents.
[0055]
  An appropriate value set as a default value according to the selected document is displayed on the scan mode registration screen 18a. On this screen 18a, it is possible to set the boundary print size (long side) of the scan mode, the scan mode less than the boundary value, and the scan mode greater than or equal to the boundary value for each document. The display column D2 displays the boundary print size (long side) of the scan mode for each document, and indicates that 152 mm is set. This border print size can be set by numerical input using the keyboard 22a or by the mouse.22bBy clicking the up / down arrow in the display field D2 in accordance with the above, it can be set by increasing / decreasing in the minimum unit (for example, mm). In the display columns D3 and D4, the scan mode less than the boundary value and the scan mode above the border value are displayed, respectively, indicating that the “scan 1” mode and the “scan 2” mode are set, respectively. These modes can be changed by changing the display of the mode added to the list by clicking each arrow in each display column D3, D4. In the display column D5, a registration list for each print size indicating the print size corresponding to the value set in the boundary size of the display column D2 on this screen 18a and the corresponding scan mode is displayed. This indicates that the “scan 2” mode corresponds to the HV size of × 158.0 (mm).
[0056]
When the “Register by Size” button (GUI) is instructed, the “Individual Registration by Print Size” window (dialog) 18b shown in FIG. 9 is displayed on the display screen 18a of the monitor 18, and the scan mode is selected according to each print size. Setting is possible. When this dialog 18b is displayed, the list of “print size to be registered” displayed in the display field D6 is not selected, and the “scan mode” displayed in the display field D7 is the last set mode. All the currently registered scan modes for each print size are displayed in the list of the display column D8.
[0057]
  Here, first, a list of print sizes to be registered in the display field D6 is selected, a scan mode corresponding to the selected print size is selected in the display field D7, and an “add” button is designated to display the display field D8. Added to the end of the list. It should be noted that one item can be deleted from the list in the display column D8 by an instruction of the “delete” button and all items can be deleted by an instruction of the “delete all” button. The instruction of the “Cancel” button deletes the dialog 18b, and the setting result in the dialog 18b is not reflected. "FinishedWhen the “Solution” button is designated, the items displayed in the list in the display column D8 are registered, the dialog 18b is deleted, the screen returns to the “scan mode registration” screen 18a, and the registration list for each print size in the display column D5 is registered. Update to results.
  When the “Register” button is instructed here, the set value is updated and the registration is completed. Note that the instruction of the “Cancel” button on this screen 18a ends the registration without reflecting the change result of the setting value.
  As described above, the relationship between the print size and the scan mode can be arbitrarily set according to the document type.
[0058]
When the carrier ID code and the magazine ID code are acquired and the output print size is selected in the digital printing apparatus 10 initially set as described above, the output print size is read by the reading method control means of the CPU 76, which is a feature of the present invention. In response to this, the previously registered scan mode is set, and the CPU 76 automatically calculates the magnification, and sets the zoom lens setting optical magnification and the electronic enlargement / reduction magnification. That is, first, the standard optical magnification specific to the carrier ID code is automatically set from the memory 78 as the zoom lens setting optical magnification.
In the illustrated example of the digital printing apparatus 10, during pre-scanning, image signals captured from all the pixels in the effective pixel area (for example, 1380 pixels × 920 pixels) of the image sensor 30 onto which the image carried on the film document is projected. Is taken into the frame memory 91 (pre-scan frame memory 91a) of the signal processing device 72 of the control device 14, thinned out, and displayed on the monitor 18 (for example, 345 pixels × 230 pixels).
[0059]
On the other hand, in the case of the main (fine) scan, the image signals of all the pixels in the effective pixel area of the image sensor 30 are left as they are or are shifted in accordance with the scan mode set according to the output print size. It is read with 4 times the number of pixels (2760 × 1840 pixels). By the way, there are a plurality of film document sizes, and therefore there are a plurality of mask sizes, which are different from each other. Therefore, the projection images of the mask images of all film documents (document images in the opening area of the mask) are the It is not projected onto the entire effective pixel area, but is generally projected inside. Therefore, regardless of whether or not pixel shifting is performed, the image signal of the input pixel area used for reproduction is printed from the image signal of the entire pixel area of the read effective pixel area. It is necessary to extract the image signal of only the pixel. Therefore, in the present invention, the image signals of the pixels on the edges of the film original and the mask can be surely removed even in consideration of the deviation of the optical axis, the magnification error, and the stop position error of the film original. The image signal of as many pixels as possible in the opening area can be surely taken out and can be taken into the frame memory 91 (91b) as the image signal of the pixel in the input pixel area. The size (number of pixels) of the input pixel area is set with respect to the size (number of pixels). Note that the main scan frame memory 91b may be configured to take in the image signals of all the pixel areas of the effective pixel area of the image sensor 30 and read out only the image signals of the pixels in the input pixel area.
[0060]
On the other hand, also in the optical system of the input device 12, the projected image of the mask image of the film original has a sufficient margin so that the standard optical magnification sufficiently satisfies the above relationship. It is set to enter inside. Therefore, the standard optical magnification is such that when the mask image of the film original is reliably projected onto the effective pixel area of the image sensor 30 and output as a print of a desired print size, the edge of the film original appears, the edge of the mask, etc. Is an optical magnification that ensures that the effective pixel area of the image sensor 30 is highly utilized and a high-definition image quality can be ensured. By the way, when the zoom lens unit 62 is actually set to this standard optical magnification, the CPU 76 sets the zoom lens unit 62 from the magnification-pulse table stored in the memory 78 to the position where the set optical magnification is obtained. In order to obtain the amount of movement from the home position (origin) necessary for moving the zoom lens group 66, the number of pulses from the origin applied to the magnification adjustment motor 63 is read out, and the magnification adjustment motor 63 corresponds to the number of pulses. When driven, the zoom lens group 66 is moved and stopped at a position where the standard optical magnification is obtained.
[0061]
Next, the CPU 76 uses various setting values set in advance at the time of shipment from the factory, for example, depending on the output print size, the margin of output image such as the meandering of the photosensitive material of the image output machine 16 and the recording length error. Taking into account the amount and pixel deficiency (deletion) in the image processing device 74, the number of input pixels (for example, 2680 pixels × 1840 pixels) obtained by shifting the pixels and averaging the time four times is obtained. The number of output pixels (for example, 2132 pixels × 1530 pixels) necessary to output a print of a desired print size (for example, 2L size 178 mm × 127 mm) at a predetermined output pixel density (for example, 300 dpi) from the image signal Calculation of an electronic scaling factor (for example, 85%) for creating a pixel image signal is performed, and the pixel image signal is sent to the signal processing device 72 in consideration of injury. The number of pixels (for example, 2530 pixels × 1822 pixels) to be cut out from the effective pixel area of the image sensor 30 captured in the frame memory 91 (91a, 91b as necessary) is determined, and the monitor (for example, 345 pixels × 230 pixels) 18 and the finished print area is displayed as a reference line.
[0062]
In the illustrated digital printing apparatus 10, the image of the finished print area within the reference line displayed on the monitor 18 in this way is output from the image output device 16 as it is. However, trimming can be performed when it is desired to adjust the original image reproduction area on the print, that is, the amount of the original image in the print reproduction image. This trimming operation may be performed by the user specifying the optical magnification directly or by specifying the start and stop of zooming by the magnification adjustment motor 63. In this case, the actually set magnification is displayed on the monitor 18. It is good to be done. After the designation, the user confirms the image in the predetermined trimming area by using the image of the image sensor 30 displayed on the monitor 18 that has returned to the print screen and the reference line indicating the finished print area, that is, the trimming area. When the desired trimmed image is not obtained, the user can repeat the trimming work by adjusting the optical magnification until the desired trimmed image is obtained.
In the present invention, the reference line displayed on the monitor 18 sufficiently considers the image shift that occurs until the original image read by the image sensor 30 is reproduced on the print. Since there is almost no deviation from the printed reproduced image, it is sufficient to check the trimmed image on the monitor 18, but it is needless to say that the trimming operation may be performed while actually outputting the print.
[0063]
The digital printing apparatus to which the image forming apparatus of the present invention is applied is basically configured as described above. The operation of the digital printing apparatus of the present invention will be described below.
First, when the digital printing apparatus 10 is turned on, the CPU of the control apparatus 14 automatically acquires information on the carrier and the photosensitive material. Here, the operator visually confirms or checks the carrier information and the photosensitive material information displayed on the screen of the monitor 18 and replaces the carrier and the magazine 114 if necessary. After the replacement, the CPU 76 obtains a new carrier or magazine ID code and changes the monitor display. Further, the operator inputs the print size, and the initial setting of the method of the present invention is completed. Subsequently, in the digital printing apparatus 10, the scan mode corresponding to the print size is set as described above. Here, when the scan mode is not set for the print size or when it is desired to change the scan mode, the operator can set a desired scan mode by registering the scan mode shown in FIGS. . Further, here, a cutout pixel area (number of pixels) and a transmission output pixel area (number of pixels) are determined.
[0064]
Next, when it is confirmed that the digital printing apparatus is in a predetermined rising state such as the amount of light from the light source unit 24 of the input device 12, the operator reads the first image photographed on the strips A at the reading position. The strips A are loaded into the film carrier 28 so as to be Z. Here, when an instruction to start reading is issued, the input device 12 first starts pre-scanning.
When the pre-scan is started, the light, which is inserted into the optical path L by the light source unit 24 and adjusted by the G filter of the color filter 38, for example, passes through the strips A and is projected as a projected image of the original image by the lens unit 62. The image is imaged substantially inscribed in the effective pixel area of the image sensor 30, the G original image is read, sent to the control device 14, subjected to predetermined signal processing by the signal processing device 72, and then stored in the prescan frame memory 91 a. Stored. Next, in the same manner, for example, a B image and then an R image are read and sequentially stored in the frame memory 91a, and the prescan ends.
[0065]
At the same time, in the control device 14, the prescan G image is read from the frame memory 91 b by the image processing device 74, processed by the display image processing circuit 92, and displayed on the monitor 18 together with the reference line indicating the finished print area. The The original image displayed on the monitor 18 is used to set the main subject, and the image processing condition setting means 96 sets the image processing conditions according to the obtained image information, the main subject, etc. In the unit 70, the diaphragm 36 is adjusted.
In the control unit 70, the automatic focus adjustment of the zoom lens unit 62 by the automatic focus adjustment unit 80 is performed using the pre-scanned image signal processed by the signal processing device 72.
Thereafter, when the main scan is started, the G image, the B image, and the R image of the film document are processed in the same procedure as the pre-scan, with or without pixel shifting by the image sensor 30 according to the set scan mode. The images are sequentially read and sent to the control device 14, and the signal processing device 72 averages the space or time according to the set scan mode, and after the required signal processing, the main scan frame memory 91b. Stored in Subsequently, in the image processing device 74, the image signal of the pixel in the cut-out pixel area determined in advance is read from the frame memory 91b, and the recording image processing circuit 94 performs LPF, enlargement / reduction (electronic scaling), USM, etc. The output output pixel area determined by the method of the present invention is subjected to image processing, and if necessary, the image rotation control means 82 rotates the image 90 degrees and the negative / positive conversion means 84 performs negative / positive inversion. An image signal of (number of pixels) is transmitted to the image output device 16.
[0066]
On the other hand, in the image output device 16, the photosensitive material P drawn from the magazine 114 is conveyed to the image position information forming unit 118, and after frame information is formed, it is conveyed to the exposure unit 120. In the exposure unit 120, the light beam scanning device 102 modulates the light beam with the image signal transferred from the control device 14, deflects the modulated light beam in the main scanning direction, and scans the photosensitive material P transported in the sub-scanning direction. A latent image is formed by exposure.
The photosensitive material P on which the latent image is formed is conveyed to the back print unit 122, information such as the film photographing date is back printed, is stored in the reservoir 124, and is conveyed from the discharge unit 126 to the developing device 108.
The photosensitive material P conveyed to the developing device 108 is developed by being sequentially subjected to color development, bleach-fixing, and water washing in each tank while being conveyed at a predetermined speed, and dried by the drying device 110. The cutting unit 138 of the discharge device 112 cuts each print in accordance with the frame information to obtain a finished print, and stores the print in the sorter 140 according to the sort information.
[0067]
The image forming apparatus of the present invention has been described in detail above. However, the present invention is not limited to the above-described embodiments, and various improvements and modifications may be made without departing from the scope of the present invention. It is.
[0068]
【The invention's effect】
As described above in detail, according to the present invention, even if the number of main sub-pixels or the print size (output print size) of the output image signal is various, the film has the required resolution and SN ratio according to these. An image reading method control (scan) mode for reading an original image can be set, registered or stored, and when the output print size is selected or set, the corresponding scan mode is automatically set. A film original image can be read.
Therefore, according to the present invention, an appropriate scan mode is set according to the output print size. For example, if the output print size is increased, the scan time is increased and the productivity of the original image is reduced. Reading can be performed at a high resolution and a high SN ratio required for a large print size, and when the output print size is small, even if the resolution and the SN ratio are slightly reduced, the pixel shift and the time average of the read pixels The scanning time can be shortened without performing any one, two, or all of the spatial averaging, etc., and highly productive document images can be read, regardless of the output print size. According to the output print size, it is possible to perform image reading with a good balance between image quality and productivity.
[Brief description of the drawings]
FIG. 1 is a block diagram of an embodiment of a digital printing apparatus to which an image forming apparatus according to the present invention is applied.
2 is a schematic perspective view of an embodiment of an image input device of the digital printing apparatus shown in FIG.
3 is a schematic perspective view of an embodiment of a slide carrier used in the image input device shown in FIG.
4 is an explanatory diagram for explaining pixel shift performed in the image input apparatus shown in FIG. 2; FIG.
FIG. 5 is a block diagram of an embodiment of a control device of the digital printing apparatus shown in FIG.
6 is a block diagram of an embodiment of an image processing device of the control device shown in FIG. 5;
7 is a schematic cross-sectional view of an embodiment of an image output machine of the digital printing apparatus shown in FIG.
FIG. 8 is an explanatory diagram showing an example of a monitor display screen for explaining image scan mode registration performed in a reading method control unit used in the present invention.
FIG. 9 is an explanatory diagram showing another example of a monitor display screen for explaining image scan mode registration performed in the reading method control means used in the present invention.
[Explanation of symbols]
  10 Digital printing device
  12 Image input device
  14 Control device
  16 Image output machine
  18 Display device (monitor)
  20 storage devices
  22 Data input device
  24 Light source
  26 Calibase
  28 Imaging unit
  30 Image sensor (CCD)
  30a xy movement control circuit
  32 Film carrier
  34 Slide carrier
  62 Zoom lens unit
  70 Control unit
  72 Signal processor
  74 Image processing device
  76 CPU
  78 memory
  91, 91a, 91b Frame memory
  92 Image processing for displaycircuit
  94 Image processing for recordingcircuit
  100 Conveying device
  102 Light beam scanning device
  108 Developing device
  110 Drying equipment
  112 Discharge device

Claims (2)

Image reading means for obtaining a digital image signal from image information on a film or a reflective original by photoelectrically reading an image of a photographic film or a reflective original;
Image processing means for generating an output image signal from the digital image signal;
Image recording means for recording the output image signal on a recording medium;
In order to control the resolution and the signal / noise ratio when the image reading unit reads image information, the pixel shift that increases the number of read pixels by reading the pixels from the reference pixel and the image signal of the read pixel Registration means for registering a number of reading method control modes set in combination with spatial averaging or temporal averaging in association with the number of main sub-pixels or print size of the output image signal;
By selecting the number of main sub-pixels or the print size of the output image signal, the corresponding reading method control mode is automatically determined from the several reading method control modes, and the determined reading method control is performed. A reading method control means for performing image reading control using a mode ,
In one of the several reading method control modes, the pixel is read out from the reference pixel, and the image signal of the read pixel is spatially averaged . When reading an image to obtain a digital image signal from image information on a film or a reflective original by photoelectrically reading an image of a photographic film or a reflective original,
In order to control the resolution and signal / noise ratio when reading image information , the pixel shift is performed by shifting the pixel from the reference pixel to increase the number of read pixels, and the spatial averaging or time of the image signal of the read pixel A number of reading method control modes set in combination with averaging are registered in association with the number of main sub-pixels or print size of the output image signal, and the number of main sub-pixels or print size of the output image signal is registered. By selecting, the corresponding reading method control mode is automatically determined from among the several reading method control modes, image reading control is performed using the determined reading method control mode, and the digital image An image forming method comprising: generating an output image signal from a signal; and recording the output image signal on a recording medium.

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