JPH05303152A - Method for deciding photograph printing exposure - Google Patents

Abstract

PURPOSE:To obtain optimum exposure required for obtaining a precise photographic print by deciding the photograph printing exposure of individual original pictures based on a main parameter and a sub-parameter. CONSTITUTION:The image information of the individual original pictures obtained by photoelectrically converting the original pictures recorded on a color photographic film F after the color thereof is resolved is set as the main parameter. On the other hand, the identification code (generally, DX code) 14 of the film F is read and the quality class thereof is decided. Next, short-term accumulation information obtained by accumulating the image information extending over the plural sheets of original pictures in the identical film F and long-term accumulation information obtained by accumulating the short-term accumulation information or the image information for every quality class of the respective films F extending over the plural films F are produced. Then, at least two kinds of information among three kinds of information obtained by adding two kinds of accumulation information and film inherent information which is previously set for every quality class is set as the sub-parameter. Then, the photograph printing exposure of the individual original pictures is decided based on the main parameter and the sub-parameter.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for determining a photographic printing exposure amount when a photographic printing process is carried out. More specifically, each original image recorded on a color photographic film is color-separated and then photoelectrically converted. The present invention relates to a method for determining a photographic printing exposure amount based on obtained image information and accumulated information of image information obtained from a plurality of original images.

[0002]

2. Description of the Related Art In general photography, a subject's blue (B), green (G), red (R) (hereinafter simply referred to as B,
It is known as an empirical rule that the average reflectances of the three primary colors (described as G and R) are substantially constant. Therefore, in the conventional photographic printing apparatus, the average transmission density (L
ATD) is measured, and the exposure amount in photographic printing is determined based on the measured average transmission density, so that the exposure amount given to the B, G, and R photosensitive layers of the printing paper is controlled to be constant, and the color balance is adjusted. I am trying to make good photo prints.

This method has a drawback in that it is difficult to obtain a proper photographic print when the luminance distribution and the color distribution are uneven in the subject. These photographic original images are called subject ferria, and in particular, those caused by the uneven luminance distribution of the subject are called density ferria, and those caused by the uneven color distribution are called color ferria. As a publicly known technique for the purpose of density correction in which the exposure amount is automatically adjusted with respect to the density ferria, Japanese Patent Publication No. 56-2
The technology disclosed in Japanese Patent No. 691 can be mentioned.
That is, the original image on the photographic film is scanned, the characteristic value is obtained for each area of the image from the image density obtained by this scanning, and the classification is performed based on this characteristic value. The function adjusts the exposure amount for the original image.

Further, as a technique aiming at color correction for automatically adjusting the exposure amount for a color ferria,
Lowward collection is known which provides a relatively low exposure dose for a relatively high negative density component. In a normal photographic printing apparatus, it is not possible to automatically discriminate whether the density change of each color of B, G, and R of the photographic original image is due to the characteristics of the photographic film or due to the difference in each color distribution of the subject.
For this reason, a reference density for color correction is set in advance for each type of photographic film, and the set reference density is selected according to the type of photographic film to be printed.

On the other hand, as a method of automatically obtaining the reference density for this color correction, the following proposals have been conventionally made. In JP-A-55-46741, a photographic film is color-separated and scanned into three primary colors, and a density difference between two sets of two colors and a neutral density are obtained from the obtained image densities of the respective colors. A method for deriving a value unique to the original image film on which the original image is recorded from the functional relationship between the density difference and the neutral density and relating it to the exposure control is disclosed.

Japanese Unexamined Patent Publication No. 56-30121 discloses a method in which the average value is calculated from the screen average densities of a large number of photographic films and used as a successive reference density.
Japanese Unexamined Patent Publication No. 62-144158 discloses a method of normalizing photometric data by creating a conversion table from the screen characteristic values accumulated in a large number of original image films to reference values.

[0007]

The photographic image recorded on a color photographic film is not limited to the shooting conditions such as the subject, shooting illumination light and shooting exposure, but also various conditions such as film storage conditions and film development conditions, or the film. It greatly depends on the tone reproduction characteristics of. Further, it is generally known that many of the tone reproduction characteristics and the film characteristics with respect to the above-mentioned conditions differ depending on the film type.

Therefore, in the above-mentioned conventional techniques, a method of obtaining a reference density for color correction from image densities obtained from a large number of original images has been proposed, but all of them are only partially reflecting the characteristics of the film. No, many problems remain unsolved. In the method disclosed in Japanese Patent Application Laid-Open No. 55-46741 for obtaining a value peculiar to an original image film, this value greatly depends on a subject photographed on the original image film.
There is a problem that the development characteristics and tone reproduction characteristics of the film are not sufficiently reflected in this value, and in many cases, proper photographic printing cannot be obtained.

For example, when the number of original images recorded on a target original image film is small, not only the film characteristics cannot be sufficiently reflected in the above values, but also the reliability is extremely low due to lack of image density data. However, there is a problem in that the accuracy required for obtaining the exposure amount for photo printing cannot be ensured. In addition, when most of the original images are original images in which a specific color is dominant in the subject, that is, color ferria, a value peculiar to the original image film is obtained from the density corresponding to this specific color. However, there is a problem in that the color balance of the obtained photographic print is improper because the necessary correction is not performed on the color ferria.

On the other hand, a method disclosed in JP-A-56-30121 and JP-A-62-144158, in which the average value is calculated from screen average densities of a large number of photographic films and used as a successive reference density, , The method of normalizing the photometric data by creating a conversion table from the screen characteristic values accumulated in a large number of original film films to the reference value is only available when the above-mentioned average value or conversion table satisfies the predetermined conditions. Since it is required, there is a problem that the reference density for determining the exposure amount cannot be obtained until then. Further, even after the above conditions are satisfied, the average value and the conversion table once obtained are not corrected for a certain period of time, so that not only the characteristic change of the film cannot be dealt with, but also the reference density of the color correction before and after the correction is not supported. However, there is a problem that a photographic print with a constant color tone cannot be stably obtained.
In addition, since these methods are based on a single average value or conversion table, it is possible to deal with only a single characteristic change among various factors such as film storage conditions, film development conditions, and characteristic changes depending on the film type. Not too much.

The present invention has been made in view of these problems, and in order to perform appropriate photographic printing, not only the tone reproduction characteristics depending on the film type but also the change in the characteristics of the film with respect to the above conditions are comprehensively and dynamically changed. It is an object of the present invention to provide a method for determining a photographic printing exposure amount, which is applicable to the above and is capable of stably and efficiently producing a photographic print of a constant quality.

Another object of the present invention is to provide a method for determining a photographic printing exposure amount which is suitable for various forms of a photographic printing apparatus and which can obtain sufficient performance by a simple method.
A further object of the present invention is to provide a method for determining a photographic printing exposure amount, which can take appropriate measures even when the film type cannot be identified.

[0013]

In order to achieve the above-mentioned object, the method of determining the photographic printing exposure amount of the present invention is an individual image obtained by subjecting an original image recorded on a color photographic film to color separation and photoelectric conversion. The image information of the original image is used as a main parameter, and (1) the short-term accumulated information in which the image information is accumulated over a plurality of original images in the same film. (2) The image information of each film across a plurality of films. Long-term accumulated information accumulated for each product group (3) At least two types of film-specific information selected according to the film product group are used as sub-parameters, and individual original images are prepared based on the main parameters and sub-parameters. The amount of exposure for photographic printing is determined.

The product type group of the film is determined by reading an identification code attached to the film in advance. Also, the film type group is common to a plurality of identification codes. Also, if the film type group is not determined,
This is to select a predetermined product type group.

The short-term accumulated information, the long-term accumulated information,
The film-specific information is a function of the same format. In addition, the short-term accumulated information and the long-term accumulated information,
Each is normalized as a subparameter so as to correspond to a predetermined number of original strokes. When the number of original images to be stored in the long-term storage information does not reach a predetermined count value, the weight of the long-term storage information is reduced.

Further, when the number of accumulated original images of the long-term accumulated information exceeds a predetermined count value, the long-term accumulated information is normalized so that the number of accumulated original images corresponds to the predetermined number of original images.

[0017]

The image information of each original image obtained by photoelectrically converting the original image recorded on the color photographic film is used as the main parameter. On the other hand, the identification code of the film (usually the DX code) is read to determine the product group. Next, short-term accumulated information obtained by accumulating the image information over a plurality of original images in the same film, and the short-term accumulated information or the image information over a plurality of films for each product type group of each film. The accumulated long-term accumulated information is created, and at least two kinds of information among the three kinds of information including the two kinds of accumulated information and the film-specific information preset for each product type group are used as the sub-parameters.

In order to determine the photographic printing exposure amount of each original image based on the main parameter and the sub parameter,
The optimum exposure amount is determined while dynamically responding to various factors related to the change in film characteristics. If the identification code is unreadable, or if the product type group corresponding to the read identification code cannot be determined, a preset product type group is automatically selected and processing corresponding to an exceptional situation is performed.

Further, the short-term accumulated information, the long-term accumulated information, and the film-specific information are functions of the same format, so that the arithmetic processing is simplified. Further, the short-term accumulated information and the long-term accumulated information are each normalized so as to correspond to a predetermined number of original strokes, and the degree of influence of the information used is adjusted. If the number of stored original images of the long-term accumulated information does not reach the predetermined count value, the weight of the long-term accumulated information is reduced and the influence degree of the long-term accumulated information is adjusted according to the number of accumulated original images.

Further, when the number of stored original images of the long-term accumulated information exceeds a predetermined count value, the long-term accumulated information is normalized to a predetermined number of original images, and the latest information is given a higher weight, and at the same time, the data storage unit Prevent overflow.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the method for determining a photoprinting exposure amount of the present invention will be described below with reference to the drawings. (Regarding Structure of Photographic Film) FIG. 3 shows the structure of a 135 photographic film which has been subjected to development processing.

In the figure, a photographic film F on which an original image (group) I has been formed by development is joined by a splice portion 10 to form a plurality of rolls.
In the rolled photographic film F, a notch (group) 12 indicating the center position of the original image is arranged at the side edge portion in the notch step before the photographic printing step. Further, a well-known perforation (group) P is arranged in advance on this side edge portion. By detecting the notch 12, conveyance control such as positioning of the photographic film F in the subsequent steps is performed. As shown in the figure, the photographic film F is provided with an identification code (DX code) 14 indicating its type. The photographic film F in this example is not limited to 135 photographic film, but other photographic film (for example,
Of course, it may be 110 film).

The roll-shaped photographic film F thus treated is printed in a photographic printing apparatus. (Regarding Configuration of Photographic Printing Apparatus) In FIG. 4 showing the configuration of the photographic printing apparatus, the photographic film F is set on the spool 20 and wound on the spool 21 via a predetermined transport path. A scanning unit 22 is provided in the middle of the path, whereby the original image recorded on the photographic film F is
The colors are separated into B, G, and R colors and scanned. The scanning unit 2
The image signals of B, G, and R colors obtained in 2 are sent to the image processing unit 24, A / D converted and shaped into image density information of a predetermined format, and then sent to the information processing unit 26.

The image density information is subjected to a series of information processing, which will be described later, in the information processing section 26. As a result, the exposure amount for each original image is calculated, and the signal of this exposure amount is exposure-controlled through the communication line 28. It is transmitted to the unit 30. The photographic film F that has passed through the scanning unit 22 absorbs the difference in the transport speed of the photographic films F between the scanning unit 22 and the exposure unit 32, and simultaneously scans a plurality of original images prior to exposure. It is sent to the exposure unit 32 through the buffer unit 34 provided. The transport path between the scanning unit 22 and the exposure unit 32 has a length corresponding to a maximum of 24 sheets of 135 photographic film.
Image density information corresponding to almost all original images I recorded on one photographic film can be obtained prior to exposure.

Each original image formed on the photographic film F is positioned in the exposure section 32, and the light emitted from the light source 36 is illuminated by the diffusion section 38 as uniformized light.
Further, the lens 54 optically forms an image on the photographic printing paper 40 and exposes it. Here, the exposure amount is the exposure control unit 3
0, the yellow (Y), magenta (M), and cyan (C) subtractive cut filters 50a, 50b, and 50c disposed above the exposure unit 32 and the shutter 52 disposed below the exposure unit 32 Converted as operating time. Depending on this operating time, the cut filters 50a, 5
0b, 50c and the shutter 52 are inserted in the exposure light path to adjust the exposure given to the photosensitive layers of the respective colors of the photographic printing paper 40. After the completion of this exposure, the photographic printing paper 40 is transported by a predetermined distance in preparation for the next exposure, and the photographic film F is transported to position the original image I to be printed next in the exposure section 32. (Regarding Configuration of Scanning Section) In the internal configuration diagram of the scanning section in FIG. 5, in the scanning section 22, first, the light emitted from the light source 59 is formed into substantially parallel light by the lens 60. The parallel light passes through color separation filters 62a, 62b, and 62c arranged in parallel along the transport direction of the photographic film F, and is separated into B, G, and R colors.

The illumination light color-separated into B, G, and R colors in this way passes through the slit 64 and is applied to the photographic film F. The light transmitted through the photographic film F is B,
CCD arranged at a position corresponding to the illumination light of each of G and R
Photoelectric conversion is performed by the line sensors 68a, 68b, 68c. Here, the CCD line sensors 68a, 68b,
Each of the 68c has 2048 pixels, and uses a one-dimensional image sensor capable of scanning over a length of 32 mm in the width direction of the photographic film F.

By these, 3 in the width direction of the photographic film F is obtained.
Main scan was performed for 2 mm, and B, G, R obtained
The image signal of each color is supplied to the image processing unit 24. Also,
Notch 12 and splice part 1 attached to photographic film F
0 and the identification code 14 are the detectors 70a and 70, respectively.
b, 70c, and the detection signal is supplied to the conveyance control circuit 72. The conveyance control circuit 72 processes the detection signal into a notch signal, a splice signal, and an identification code signal, sends the signal to the image processing unit 24 and the information processing unit 26 via the system bus 74, and the pulse motor 75. To control the conveyance of the photographic film F.
Further, the carrier pulse at this time is supplied to the image processing unit 24 as a synchronization signal at the time of sampling the image signal.

The photographic film F is a pulse motor 75.
Thus, the sheet is conveyed at a conveying speed of 0.25 mm / pulse, and the sub-scanning is performed accordingly. (Structure of Image Processing Unit) Image processing unit 2 shown in FIG.
In the detailed configuration diagram of 4, the following signal processing is performed.

The image signal supplied from the scanning unit 22 is amplified by the amplifier circuit 80, sampled by the sample hold circuit 82, and converted into a digital signal by the A / D converter 84. Here, the timing control circuit 86 causes the scanning unit 22 to have the CCD line sensor 68a
A drive signal for driving 68b and 68c is sent, and the sampling timing is controlled. At this time, the sampling number is 128 times for one scan, and the A / D conversion is processed by 16 bits. The digitized image signal is an LUT composed of a ROM or the like.
It is converted into a density value via a (lookup table) 88 and stored in the image buffer 90.

The LUT 88 stores a conversion table represented by the following equation (1). D = a × log (S + b) (1) where S is an input to the LUT 88 and D is its output. Further, a is a constant relating to conversion into a printing density (scanning unit 2
2 is determined by the photometric density determined by the spectral characteristics of the imaging system and the spectral sensitivity of photographic printing paper), and b is a constant for removing the influence of dark current during imaging.

The LUT 88 is provided with a plurality of conversion tables obtained by substituting several kinds of numerical values into the constants a and b of the equation (1), and is selected by the CPU 92 (selected). The conversion table does not have to be the same for each color of B, G, and R). In this way, the 16-bit line image density information consisting of 128 pixels is stored in the image buffer 90 as the primary line image density information in the main scanning direction. The primary line image density information is rounded (smoothing or thinning taking an arithmetic mean) according to the format of the photographic film F, and shaped into an appropriate number of pixels. Further, the secondary line image density information thus obtained is shaped by the same rounding processing in the sub-scanning direction and stored in the memory 94.

By the above processing, two-dimensional image density information consisting of a predetermined number of pixels, here 16 × 16 pixels, is finally obtained regardless of the format of the photographic film F, and this information is obtained. Sent to 26. Therefore,
The information processing section 26 can perform common processing regardless of the format of the photographic film F. (Regarding Configuration of Information Processing Unit) In the detailed configuration diagram of the information processing unit in FIG. 7, two-dimensional image density information D _i (X, Y) of each color of B, G, and R sent from the image processing unit 24.
(I = B, G, R, and so on) is stored in the memory 102 via the system bus 74. The CPU 104 stores the two-dimensional image density information (hereinafter,
(Hereinafter simply referred to as image information) is read out and the exposure amount for each original image I formed on the photographic film F is calculated.

This exposure amount is transmitted to the exposure control unit 30 through the communication line 28. Further, the notch signal, the splice signal, and the identification code signal sent from the carriage control circuit 72 of the scanning unit via the system bus 74 are also stored in the memory 102 and processed by the CPU 104. The auxiliary storage unit 106 stores information to be saved, constants necessary for processing, and the like. The auxiliary storage unit 106 is composed of, for example, a magnetic disk, and the recorded information can be taken out as needed. With this, not only can information be stored for a long period of time, but it can be saved even when the power is cut off, and the information saved by an external independent device can be processed and constants can be initialized and changed. .. Long-term accumulated information and film-specific information, which will be described later, are stored in the auxiliary storage unit 106 and loaded into the memory 102 as needed.

Further, 108 is a keyboard for various operations, 112 is a display, and the interface circuit 110
Input and output can be performed via. (Regarding Internal Processing in Information Processing Unit) Hereinafter, the process of determining the exposure amount in the information processing unit 26 will be described in detail. First, a process in which all three types of short-term accumulated information, long-term accumulated information, and film-specific information are set as sub-parameters for determining the exposure amount will be described with reference to the flowchart of FIG.

In step S1, the identification code (DX code) 14 attached to the photographic film F is read, and in step S2, the product type group is determined. FIG. 1 shows an example of the correspondence between the identification code and the product group. As shown in the figure, a product type group is individually assigned to each identification code, but this product type group may be common to the identification codes. As a result, the number of product groups can be limited to a certain number, and the storage amount of long-term accumulated information or film-specific information can be adjusted according to the data storage area.

If the identification code 14 cannot be read or the product type group corresponding to the read identification code cannot be determined, the product type group predetermined in step S3 is automatically set. The default shown in FIG. 1 corresponds to such a case. As shown in this table, the method of assigning an exceptional product group (corresponding to 0 in FIG. 1) to the default, the method of assigning a standard product group (corresponding to 1 in FIG. 1), and all product groups (Corresponding to ALL in the table). As a result, it is possible to automatically deal with an exceptional situation in which the identification code cannot be read or the product type group corresponding to the read identification code cannot be determined.

At present, it is usual that the 135 film has a DX code as an identification code.
Some films, such as 110 film, do not have an identification code. In such a case, it is desirable that the default is set according to the film format. FIG. 2 shows an example thereof. This makes it possible to automatically cope with exceptional situations in which the identification code cannot be read or the product type group corresponding to the read identification code cannot be determined in correspondence with any film format. However, it goes without saying that in such a case, an alarm or the like may be issued to artificially specify the identification code or the product type group.

If no such standard setting is made,
In step S4, the weight W1 of the long-term accumulated information and the film-specific information is set to zero (as a result,
Only short-term accumulated information will be used as a sub-parameter). When the product type group is determined, the film F is frame-fed in step S5, and the original image I is color-separated and scanned in step S6 to read image information. The read image information is rounded or appropriately shaped in step S7, sent to the information processing unit 26, and stored in the memory 102 for each original image (step S10). This image information includes image characteristic information unique to the original image, such as information corresponding to the subject and shooting exposure.
Is set as a main parameter relating to exposure control.

On the other hand, the image information subjected to shaping such as rounding in step S7 is accumulated over a plurality of original images in the same film (step S8). The process from the frame feed step S5 of the film F to the original image storage step S9 in the same film forms a loop that is repeated until all the frames of the film are completed.

On the other hand, when the end of the film F is confirmed in step S9, first, in step S13, the film-specific information according to the product type group determined in step S2 is selected, and this is selected as one of the sub-parameters in step 14. Is set. The film-specific information includes information corresponding to the tone reproduction characteristics unique to the film.

The information accumulated over a plurality of original images in the same film in step S8 is stored in step S15.
Then, it is stored in the memory 102 as short-term accumulated information. Here, as the short-term accumulated information, a cumulative density function (Short Term Cumurative Distribution Funct) obtained from the frequency of image information D for a plurality of original images in the same film as the original image.
ion) and STCDF _i (D) are used. Here, i represents each color of B, G, and R, and the same applies to the following. This cumulative density function calculates the frequency (Short Term Image Frequency) of image information for multiple original images in the same film as the original image,
If STFRQ _i (D), it is calculated by the following equation (2).

[0042] Next, in step S17, the short-term storage information is combined with the short-term storage information obtained from the films of the same product group processed up to this point to form long-term storage information according to the film product group. Here, as the long-term accumulated information, the accumulated density function of the original film, which is the short-term accumulated information, is accumulated for each film type group over a plurality of films (Long Term Cumura).
tive distribution function), LTCDF _ij (D). This cumulative density function is obtained by the following equation.
Here, j is the film type group, k is the number of films, and so on.

[0043] In addition, the long-term accumulated information in advance, LTCDF _ijk-1 (D) Therefore, LTCDF _ij (D) = STCD _i (D) + LTCDF _ijk-1 (D) (5). Therefore, the long-term accumulated information is sequentially updated for each film by adding the short-term accumulated information to the previous long-term accumulated information.

On the other hand, the frequency (Long Term Image Frequency) of the image information accumulated based on the film type identification information of the original image information over a plurality of films is LTFRQ.
_ij (D), Is. Therefore, it is understood that the long-term accumulated information can be obtained even if the frequency of the image information of the original image is accumulated over a plurality of films. In this case, the long-term storage information may be sequentially updated for each frame by adding the frequency of image information to the previous long-term storage information.

Since the long-term storage information is stored over a plurality of films, it can be used as characteristic information of the film according to the developing conditions. However, when the number of accumulated original images is extremely small, the information does not always reflect the development conditions sufficiently. On the other hand, considering that the developing conditions change with time and seasonal factors, the accumulated information needs to be evaluated with greater weight for the latest information. Further, since the long-term storage of the image information of the original image is performed as long as the exposure process continues, the storage is unlimited, and there is a possibility that the memory overflow may occur beyond a certain maximum value.

Therefore, in step S18, the process of processing the long-term accumulated information is switched according to the number of accumulated original images. First, when it is determined in step S19 that the number of accumulated original images is less than the predetermined minimum value Nmin (for example, 40 frames), the weight W2 of the long-term accumulated information is set to 1 or less in step S20. As an example of the method of calculating the weight, W2 = number of accumulated original images / Nmin (7) can be given. In this way, the weight of the long-term storage information is adjusted according to the number of original storage images. In addition,
When W2 = 0, the long-term accumulated information is not adopted as a sub parameter for determining the exposure amount.

Next, in step S21, the number of accumulated original images is larger than a predetermined minimum value Nmin and a predetermined maximum value Nm.
If it is determined that it is smaller than ax (for example, 10,000 frames), no special processing is performed on the long-term accumulated information.
If it is determined in step S22 that the number of accumulated original images is larger than the predetermined maximum value Nmax, a normalization process for setting the maximum value of the cumulative density function to Nrm is performed in step S2.
Done in 3. Here, Nrm is larger than Nmin,
It is a constant smaller than Nmax. That is, if the maximum value of the image information is Dmax, then LTCDF _ij (D) = LTCDF _ij (D) × Nrm / LTCDF _ij (Dmax) (8).

In this way, each time normalization is performed,
The percentage of long-term information accumulated in the past is reduced. That is, the normalized long-term accumulated information has a greater weight as new accumulated information. The long-term storage information is stored in step S24 for each film type group. Then, in step S26, a normalization process for adjusting the balance with the number of frames of the short-term accumulated information (normally 24) is performed (converted into the same number of frames as the short-term accumulated information), and then set as a sub-parameter ( Step S14).

That is, the normalized long-term accumulated information (Normal
ized Long Term Cumurative Distribution Function)
And is denoted by NLTCDF _ij (D), if the maximum value of the image information Dmax, the normalized number with _{N, NLTCDF ij (D) =} LTCDF ij (D) × N / LTCDF ij (Dmax) ··· (9) Note that this process may be omitted depending on the method of determining the exposure amount described later.

Through the above process, the main parameter consisting of the image characteristic information for each original image and the sub-parameter consisting of the film specific information, the short-term accumulated information and the long-term accumulated information are set. Of course, it is desirable that all three types of sub-parameters be obtained,
It suffices that the process be such that at least two types can be selected. Based on the main parameter and the sub parameter, in step S27, an appropriate calculation process is performed to determine the optimum exposure amount for each original image.

In the above description, the case where normalization or the like is performed according to the number of frames of the original image to be accumulated has been described, but the same processing may be performed according to the number of pixels instead of the number of frames. (Regarding First Exposure Amount Determination Method) Next, a first method for determining the exposure amount by integrating the short-term and long-term accumulated information set in this way and the film-specific information will be described.

In the following, DAS _i = characteristic value obtained by referring to the cumulative density function of short-term accumulated information DAL _i = characteristic value obtained by referring to the cumulative density function of long-term accumulated information DAC _i = see film-specific information The characteristic value obtained by DAU _i = the characteristic value obtained by integrating the characteristic values obtained by referring to the accumulated information and the film-specific information A, B, C = coefficients, where A + B + C = 1 X = the pixel position in the main scanning direction Y = Pixel position in the sub-scanning direction D _i (X, Y) = Image information for each original image DA _i = Average value of image information for each original image CCDF _ij (D) = Preset preset cumulative density function for each product group (film Specific information) DA0 _i = average value of image information of reference original image P = cumulative density function (CDF) value with respect to average value of green image information of original image E _i = exposure amount E0 _i = exposure preset for reference original image Quantity α = Coefficient (<1)

First, according to the following equations (10), (11) and (12), the cumulative density function value corresponding to the average value of the green image information of the original image is obtained from each subparameter, and the cumulative density function for each color is further calculated. The characteristic value is obtained by referring to the opposite direction. P = STCDF _g (DA _g ) DAS _i = STCDF _i ^-1 (P) ... (10) P = LTCDF _g (DA _g ) DAL _i = LTCDF _i ^-1 (P) ... (11) P = CCDF _g (DA _g ) DAC _i = CCDF _i ^-1 (P) (12) FIG. 10 schematically shows such a method of referring to the cumulative density function. The cumulative density function is related to the tone reproduction characteristic of the film, and the characteristic value of each sub-parameter thus obtained corresponds to the neutral color image information according to the characteristic of the film.

The characteristic values of the subparameters thus obtained are integrated while appropriately weighted by the following equation (13), and DAU _i = A × DAS _i + B × W1 × W2 × DAL _i + C × W1 × DAC _i. -(13) is calculated. Here, W1 and W2 are the step S, respectively.
4, the weight set in S20. This DAU _i
It is a value corresponding to the reference density of the neutral color estimated in consideration of various factors affecting the tone reproduction characteristics of the film.
With this DAU _i , the final exposure amount E _i is calculated by the following equation (1
Obtain according to 4).

E _i = α × DA _i + (1-α) × DAU _i −DA0 _i + E0 _i (14) As a result, the photographic printing exposure is performed based on the short-term accumulated information, the long-term accumulated information, and the film-specific information. In order to determine the amount, the first determination method can obtain not only the tone reproduction characteristics depending on the film type, but also the exposure amount that is comprehensively adapted to the characteristic changes of the film with respect to the above conditions. (Second exposure amount determination method) Next, the exposure amount is determined by integrating the short-term and long-term accumulated information and the film-specific information.
The method of will be described.

CDF _i = expressed as a cumulative density function obtained by integrating accumulated information and film-specific information. The cumulative density function set as the sub-parameter is a common statistic regarding the image density information and can be simply added (overlaid), so that the information CDF _i that integrates the accumulated information and the film-specific information can be easily obtained. You can That is, CDF _i (D) = STCDF _i (D) + LTCDF _ij (D) + CCDF _ij (D) (15) FIG. 11 is used to find the cumulative density function that integrates the accumulated information and the film-specific information. The schematic diagram of a method is shown.

From this, P = CDF _g (DA _g ) DAU _i = CDF _i ^-1 (P) (16) can be easily obtained. Equation (14) is used to determine the final exposure amount.

As a result, not only the tone reproduction characteristics depending on the film type but also the exposure amount that is comprehensively adapted to the change in the film characteristics with respect to the above conditions can be obtained. Moreover, since the short-term accumulated information and the long-term accumulated information automatically change their relative weights according to the accumulated amount of image density,
The second determination method can dynamically adjust the exposure amount for each original image to the change in the characteristics of the photographic film and the reliability of the stored information. (Third exposure amount determination method) Next, the exposure amount is determined by integrating the short-term and long-term accumulated information and the film-specific information.
The method of will be described. This method normalizes the long-term accumulated information to have a predetermined weight when the accumulated amount of the long-term accumulated information is equal to or more than a predetermined count value (Nmin) (= NL
TCDF), and the contribution rate to the final exposure amount is fixed.

CDF _i (D) = STCDF _i (D) + W2 × NLTCDF _ij (D) + CCDF _ij (D) (17) The following process is the same as the second exposure amount determining method, and is expressed by the formula (16).
And the amount of exposure is determined by (14).

As a result, it is of course possible to obtain an exposure amount that is comprehensively adapted not only to the tone reproduction characteristics depending on the film type but also to the characteristic changes of the film with respect to the above conditions. Moreover, since the weight of the long-term accumulated information is constant, the weight of the short-term accumulated information is changed in accordance with the accumulated amount of the image information. Therefore, the third method uses the exposure amount for each original image as a photograph. There is a feature that can be dynamically responded to as the characteristics of the film change and the reliability of short-term accumulated information improves.

In step S28, it is determined whether or not all the frames to be exposed are finished, and the exposure amount for each image of the film is sequentially determined through the counter feeding in step S29. .. Step 30
Then, it is determined whether or not the exposure processing of all the films to be processed is completed, and the above-described film processing is repeated for the next film. (When not using short-term accumulated information) Next, the process when the control system is simplified without using the short-term accumulated information,
Description will be given according to the flowchart of FIG.

In step S51, the photographic film F
Read the identification code (DX code) 14 attached to
In step S52, work for determining the product type is performed.
If the identification code 14 cannot be read or the product type group corresponding to the read identification code cannot be determined, it is automatically set to the standard product type group in step S53.

When the product type group is determined, the film F is frame-fed in step S54, and in step S55.
The original image I is color-separated and scanned, and the image is read. The read image information is rounded or appropriately shaped in step S56. This image information includes characteristic information unique to the original image, such as information corresponding to the subject and shooting exposure, and is set as a main parameter related to exposure control in step S69.

On the other hand, the image information that has undergone shaping such as rounding in step S56 is stored in step 58 over a plurality of original images for each product type group to form long-term storage information. Since the long-term storage information is stored over a plurality of films, it can be used as film characteristic information according to the developing conditions. However, when the number of accumulated original images is extremely small, the information does not always reflect the development conditions sufficiently. On the other hand, considering that the developing conditions change with time and seasonal factors, the accumulated information needs to be evaluated with greater weight for the latest information. Further, since the long-term storage of the image information of the original image is performed as long as the exposure process continues, the storage is unlimited, and there is a possibility that the memory overflow may occur beyond a certain maximum value.

Therefore, in step S58, the process of processing the long-term accumulated information is switched according to the number of accumulated original images. First, when it is determined in step S59 that the number of accumulated original images is less than the predetermined minimum value Nmin (for example, 40 frames), the weight W2 of the long-term accumulated information is set to 1 or less in step S20. In this way, the weight of the long-term storage information is adjusted according to the number of original storage images. When W2 = 0, the long-term accumulated information is not adopted as a sub parameter for determining the exposure amount.

Next, in step S61, the number of accumulated original images is larger than a predetermined minimum value Nmin and a predetermined maximum value Nm.
If it is determined that it is smaller than ax (for example, 10,000 frames), no special processing is performed on the long-term accumulated information.
If it is determined in step S62 that the number of accumulated original images is larger than the predetermined maximum value Nmax, a normalization process for setting the maximum value of the cumulative density function to Nrm is performed in step S2.
Done in 3. Here, Nrm is larger than Nmin,
It is a constant smaller than Nmax.

In this way, each time normalization is performed,
The percentage of long-term information accumulated in the past is reduced. That is, the normalized long-term accumulated information has a greater weight as new accumulated information. The long-term accumulated information is stored in step S64 for each film type group. Then, in step S65, a normalization process for adjusting the balance with the number of frames of the film-specific information (converted into the number of frames similar to that of the film-specific information) is performed, and then set as a sub-parameter (step S66).

In steps 67 and 68, the film-specific information is selected by the product type group, and in step 66, it is set as a sub parameter. In this way, the photographic printing exposure amount for each original image is determined based on the image information of the original image I, the long-term storage information, and the film-specific information, and the printing process is sequentially performed. (In the case of using the total area transmission density) In the above embodiment, 2 obtained by scanning as the image information from the original image.
Although the case of using the three-dimensional image information has been described, the present invention is not limited to this case, and the whole area average transmission density may be used as the image information from the original image.

In the structure of the photo printing apparatus shown in FIG. 4, B,
The average transmitted light of B, G and R colors of the original image is received by the photodiodes 44a, 44b and 44c through the photometric filters 42a, 42b and 42c of G and R colors. The B, G, and R photometric signals obtained by photoelectrically converting the received light amount are supplied to the exposure control unit 30 and further A / D converted, and the total area average transmission density obtained as a result is sent to the information processing unit 26. The exposure amount is calculated according to the processing procedure. In this case, the total area average transmission density is calculated as the image density D _i.
It may be used instead of (X, Y) and the like.

In this case, since it is structurally difficult to obtain the short-term accumulated information from a plurality of original images in the original image film, a method not using this information may be considered.
The short-term accumulated information may be obtained by reciprocally transporting the photographic film via 2. That is, first, the photographic film is transported in one direction to perform photometry, short-term accumulated information is obtained from the total area transmission density for a predetermined number of original images, and then the film is transported in the reverse direction to expose each original image. Good.

In the above description, the cumulative density function is used for all three types of short-term accumulated information, long-term accumulated information, and film-specific information. This is because they are closely related, and because they are monotonically increasing functions, they are easy to perform arithmetic processing, can be simply added, and their weights can be arbitrarily manipulated. Therefore, common processing can be applied to the three types of information, that is, the short-term accumulated information, the long-term accumulated information, and the film-specific information, and at the same time, these information can be easily combined.

In the above description, the case where the long-term accumulated information and the film-specific information are separated has been described in detail. However, the film-specific information may be treated as the initial data of the long-term accumulated information and may be treated as the long-term accumulated information thereafter. Also,
When the development conditions of the film are changed significantly, the long-term accumulated information can be reinitialized or the normalization conditions can be changed. In this case, the weight of the accumulated information obtained from the film developed under the new developing condition becomes larger, and the influence of the past developing condition can be minimized.

[0073]

As described above, the photographic printing exposure amount determining method of the present invention uses the image information of each original image obtained by photoelectrically converting the original image recorded on the color photographic film as the main parameter. And (1) short-term accumulated information in which the image information is accumulated over a plurality of original images in the same film. (2) long-term accumulated information in which the image information is accumulated over a plurality of films for each film type group. Accumulated information (3) At least two types of three types of information unique to the film selected according to the film type group are used as sub-parameters, and photographs of individual original images are obtained based on the main parameters and sub-parameters. Since it is characterized by determining the printing exposure amount, for example, there is a bias in the subject photographed on the original film, or the number of recorded original images is small, Even if the development characteristics and tone reproduction characteristics of the system are not sufficiently reflected in the short-term accumulated information, by combining with the long-term accumulated information and film-specific information, the effect is eliminated and the optimum exposure required to obtain an appropriate photographic print. The amount can be calculated.

Further, the weights of the short-term accumulated information and the long-term accumulated information are individually and dynamically adjusted according to the size of the accumulated original images, and therefore, depending on the reliability of each information.
It is possible to ensure the accuracy required for determining the photoprinting exposure amount comprehensively and appropriately. The long-term accumulated information is updated on a film-by-film basis or original-image basis, and is formed so that the latest accumulated information has a greater weight, so it is possible to cope not only with changes over time in development conditions but also with seasonal factors. , It is possible to always obtain the optimum exposure amount necessary to obtain an appropriate photographic print, and at the same time, since a large change does not occur before and after updating, it is possible to stably obtain a photographic print with a constant color tone. it can.

Further, even in the initial state, since the short-term accumulated information and the film-specific information can be used, the accuracy required for determining the photographic printing exposure amount can be stably secured from beginning to end. As described above, according to the photographic printing exposure amount determining method of the present invention, not only the tone reproduction characteristics depending on the film type but also the characteristic changes of the film with respect to the above conditions are comprehensively and dynamically adapted, so that a constant quality is obtained. Provide a stable and efficient production of photographic prints.

According to the photographic printing exposure amount determining method of the present invention, sufficient performance can be obtained by a simple method that is suitable for various forms of the photographic printing apparatus. Furthermore, even in exceptional cases where the film type cannot be identified, appropriate measures can be taken automatically.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a correspondence relationship between identification codes and product groups.

FIG. 2 is a diagram showing an example of a correspondence relationship between a negative size and a default product type group.

FIG. 3 is a block diagram of a 135 photographic film used for explaining a method for determining a photographic printing exposure amount of the present invention.

FIG. 4 is a schematic diagram showing a schematic configuration of a photographic printing apparatus to which the photographic printing exposure amount determination method of the present invention is applied.

FIG. 5 is a configuration diagram showing a scanning unit in detail.

FIG. 6 is a block diagram showing in detail an image processing unit.

FIG. 7 is a block diagram showing in detail an information processing unit.

FIG. 8 is a flow chart of an exposure amount determination method using short-term and long-term accumulated information.

FIG. 9 is a flowchart of an exposure amount determination method that does not use short-term accumulated information.

FIG. 10 is a schematic explanatory diagram of a method of referring to a cumulative density function.

FIG. 11 is a schematic diagram of a method for obtaining a cumulative density function that integrates accumulated information and film-specific information.

[Explanation of symbols]

 10 splice part 12 notch 14 identification code 20 spool 22 scanning part 24 image processing part 26 information processing part 28 communication line 30 exposure control part 32 exposure part 34 buffer part 38 diffusion part 40 photographic printing paper 74 system bus 102 memory 104 CPU 106 auxiliary Storage unit 108 Keyboard 110 Interface circuit 112 Display device 114 Communication circuit P Perforation F Photographic film I Original image

Claims (8)

[Claims] 1. A main parameter is image information of an individual original image obtained by photoelectrically converting an original image recorded on a color photographic film, and at least two of the following three types of information are used. A method for determining a photographic printing exposure amount, wherein the photographic printing exposure amount of each original image is determined as a sub parameter, based on the main parameter and the sub parameter. (1) Short-term storage information in which the image information is stored over a plurality of original images in the same film (2) Long-term storage information in which the image information is stored for each film type group over a plurality of films ( 3) Film-specific information selected according to the film type group 2. The photographic printing exposure amount determining method according to claim 1, wherein the film type group is determined by reading an identification code attached to the film in advance. 3. The photographic printing exposure amount determining method according to claim 2, wherein the film type group is common to a plurality of identification codes. 4. A predetermined type group is selected when the type group of the film is not determined.
The method for determining the exposure amount for photographic printing according to. 5. The photographic printing exposure amount determining method according to claim 1, wherein the short-term accumulated information, the long-term accumulated information, and the film-specific information are functions of the same format. 6. The method according to claim 1, wherein the short-term accumulated information and the long-term accumulated information are normalized as sub-parameters so as to correspond to a predetermined number of original images, respectively. 7. The method according to claim 1, wherein the weight of the long-term accumulated information is reduced when the number of stored original images of the long-term accumulated information does not reach a predetermined count value. 8. The long-term storage information is normalized so that when the number of stored original images of the long-term storage information exceeds a predetermined count value, the number of stored original images corresponds to the predetermined number of original images. Method for determining exposure amount for photo printing.