JP2697951B2 - Exposure condition setting method - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a method for setting exposure conditions of a photographic printing apparatus.

[Conventional technology]

At a general photo lab, a negative film is processed by a film processor, the obtained negative film image is printed on paper by a color printer, and the printed paper is developed by a paper processor to obtain a print from the photographed film. ing. In recent years, printer processors in which a printer and a paper processor are combined have become widespread, and are performed in the same manner as described above. As the developing solution is used for a long period of time, normal performance cannot be maintained due to the influence of excess or deficiency of the replenishing solution, air oxidation, evaporation of the solution, mixing of the solution in the previous step, and the like. For this reason, it is necessary to always control the developer of the film processor and the developer of the paper processor in order to always improve the print quality. For this reason, conventionally, a control strip for film development prepared by previously exposing the film under a plurality of conditions is passed through a film processor, and a control strip for evaluation of paper development prepared by pre-exposing the film under a plurality of conditions is also applied to the paper. The density of the developed film or print is measured through a processor, and processing conditions such as development are managed so that the deviation between the measured density value and the reference density value is within an allowable range.

In addition, in order to always achieve good quality of color print by the printer and the processor, it is necessary to manage the developing solution and perform the developing process correctly, and to properly set the standard exposure conditions of the printer in the device. . For this reason, standard exposure conditions are set when the printer is installed.However, when using color paper with a different emulsion number, replacing the exposure lamp in the exposure unit, replacing the developing solution, changing seasons, etc. When the content of the photograph changes from one having more colors to one having less colors, or vice versa, the printing conditions change, so it is necessary to correct and reset the standard exposure conditions. In addition, since the printing conditions change due to dirt or deterioration of the light source system including the light control filter, the halogen lamp, the reflector, and the like, or replacement for the same, it is necessary to correct and reset the standard exposure conditions as described above. . In correcting the standard exposure conditions, a latent image is recorded by exposing under a predetermined condition, and the latent image is developed by developing under a standard development condition to use the latent image. The image of the reference negative film is
A portion corresponding to the average subject color is provided around a portion corresponding to the negative of the gray subject. The standard exposure conditions are corrected by comparing the density of a test print printed and developed from the reference negative film with the density (target density) of a reference print previously printed and developed.

When printing an image of a developed negative film, the image is measured and the standard exposure condition is corrected based on the photometric value to determine the exposure condition, and the image is printed.

[Problems to be solved by the invention]

However, as described above, in the film processor or the like, the development conditions are managed such that the deviation between the density value of the control strip and the reference density value is within an allowable range. For this reason, even if it is determined that the development conditions are normal, the density balance of each color of the film processor,
Development processing characteristics such as gradation balance may be slightly different from development processing characteristics under standard development conditions. Therefore, when printing an image of a negative film developed by a film processor or the like, even if the printing process is performed under the exposure condition obtained by correcting the standard exposure condition based on the photometric value of the negative film, a high quality image can be obtained. Prints were not always obtained.

Further, when the degree of dispersion of the density value for each color of the control strip with respect to the reference density value is different, for example, the B (blue) density is higher than the reference density value, and
It has been confirmed by the inventors that the effect on print quality is particularly large when the (green) density is lower than the reference density value and when the gradation balance is different from the reference.

The present invention has been made in view of the above facts, and has as its object to provide an exposure condition setting method capable of obtaining an appropriate print when the development conditions of a processor for developing a negative film are within an allowable range. is there.

[Means for solving the problem]

In order to achieve the above object, an exposure condition setting method according to the present invention is characterized in that, when setting an exposure condition of a printer using a negative film developed by a processor, a predetermined value is used as data representing development processing characteristics of the processor. The low-density visualized by developing a negative development condition management film on which a latent image has been recorded under predetermined conditions so that a plurality of density regions including a low-density region and a high-density region can be obtained by a processor. The values of the area and the high-density area are input to the printer, and the input values of the low-density area and the high-density area, and the reference values of the low-density area and the high-density area, are used for developing processing characteristics. It is characterized in that an exposure condition in which the variation is corrected is set.

Further, a value obtained by dividing the difference between the values of the input low-density area and the value of the high-density area by the difference between the reference value of the low-density area and the reference value of the high-density area, and It is preferable to set the exposure conditions by correcting the difference between the value of the low density area and the reference value of the low density area.

[Action]

In the present invention, when setting the exposure conditions, a negative development condition management film (processor) in which a latent image is recorded under predetermined conditions so that a plurality of density regions including a predetermined low density region and a high density region is obtained. The low-density area and the high-density area visualized by developing the negative development condition management film with a processor as data representing the development processing characteristics of the processor. Is entered into the printer.

Note that the input of data representing the development processing characteristics of the processor to the printer may be manually input.
Alternatively, the data may be input by transferring data from a device having data representing the development processing characteristics to a printer online or the like. Further, in the present invention, since the data representing the development processing characteristics of the processor is obtained using the negative development condition management film, the development processing characteristics are represented based on an average value such as the integrated density of a large number of exposure negative films. Compared with the case where data is obtained, data representing the development processing characteristics of the processor can be obtained more accurately, and the data can be obtained in a short time.

In the present invention, the variation of the development processing characteristics is corrected using the values of the low-density area and the high-density area and the reference values of the low-density area and the high-density area input as data representing the development processing characteristics of the processor. Exposure conditions are set. Since the reference values of the low-density area and the high-density area represent the development processing characteristics that are the reference of the processor, the input values of the low-density area and the high-density area, the reference values of the low-density area and the high-density area, By using, even if the development conditions of the processor fluctuate within the allowable range and the development characteristics of the processor fluctuate, the fluctuation of the development characteristics of the processor with respect to the reference development characteristics can be accurately grasped. Thus, it is possible to obtain an exposure condition in which the influence of the variation in the development processing characteristics of the processor is accurately eliminated.

Therefore, when the developing conditions of the processor that develops the negative film are within the allowable range, the print is always appropriate regardless of the fluctuation of the developing processing characteristics of the processor (the same printing as when developing with the reference developing characteristics). Can be obtained.

The values of the low-density area and the high-density area of the negative development condition management film can be obtained by photometry of each density area, and if each density area is decomposed into each color component and photometry is performed. The development processing characteristics such as density balance and gradation balance can be determined from the values obtained by photometry.

A value obtained by dividing the difference between the input value of the low-density area and the value of the high-density area by the difference between the reference value of the low-density area and the reference value of the high-density area according to claim (2), and The difference between the value in the low-density area and the reference value in the low-density area corresponds to a variation in the development processing characteristics of the processor. Therefore, the variation in the development processing characteristics of the processor is, for example, the difference between the input value of the low density area and the value of the high density area, as described in claim (2). The correction can be made by a value divided by the difference between the reference value and the reference value of the high-density area, and the difference between the input value of the low-density area and the reference value of the low-density area.

〔Example〕

Next, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows a photographic processing system 10 to which the exposure condition setting method of the present invention can be applied. This photo processing system
At 10, the negative film 14 exposed by a camera or the like and the latent image is recorded is developed by the film processor 11,
The latent image is revealed. The developed negative film 14 is sent to the printer processor 64, and the visualized image is printed on the color paper 74 under predetermined exposure conditions. The color paper 74 on which the image is printed is developed by the printer processor 64, cut into image frames, and shipped as a color print 20.

FIG. 2 shows an example of the film processor 11. The film processor 11 includes a film loading unit 12. The film loading section 12 is exposed by opening a lid (not shown), and is loaded with an exposed negative film 14 including a control strip for negative development.

As shown in FIG. 2, the control strip 16 for negative development includes a plurality of density measurement areas, for example, a minimum density D _min (for example, a base density) and a low density LD (for example, D
_min + 0.3 density value), high density HD (for example, 1.6 higher than LD)
A latent image 1 exposed so as to obtain an image having a large density value), a color management degree _Dmax , and a desilvering density Y-patch.
8A, 18B, 18C, 18D and 18E are recorded.

The negative film 14 loaded in the film loading unit 12 is transported into the processor unit 22. Inside the processor section 22, there are a developing tank 24, a bleaching tank 26, a bleach-fixing tank 28, a fixing tank 30, and a rinsing tank 3.
The processing tanks 2, 34 and the stabilizing tank 36 are sequentially arranged. Each processing tank stores a processing solution of a developing solution, a bleaching solution, a bleach-fixing solution, a fixing solution, a rinsing solution, and a stabilizing solution. A crossover rack 38 is provided above each processing tank. The crossover rack 38 is a partition plate that separates each processing tank.
It has a roller 42 corresponding to 40. The negative film 14 is wound around the roller 42, and constitutes a transfer path between the processing tanks. Thus, the negative film 14 is sequentially transported into each processing tank by a transport system (not shown), immersed in each processing solution, and processed.

Further, a drying unit 44 is disposed adjacent to the processor unit 22. A roller 46 is provided in the drying unit 44, and the negative film 14 discharged from the processor unit 22 is guided to the drying unit 44 by the transport system, wound around the roller 46, and dried. Density measuring unit 48 adjacent to drying unit 44
Transported to

The density measuring unit 48 includes an optical system 50 having a light source and filters for C, M, and Y, and a densitometer 52 for measuring the density of an image recorded on the negative film 14. The optical system 50 and the densitometer 52 are connected to a control circuit 54. Control circuit 54
Controls the optical system 50 and the densitometer 52 to measure the density of the image recorded on the film after the drying process for each of C, M, and Y, and manages conditions such as development. The control circuit 54
Transfers the density value data of the image to a control circuit 86 (described later) of the printer processor 64 as data representing the development processing characteristics.

The negative film 14 that has passed through the density measuring section 48 is discharged out of the film processor 11 by the film stocker 58.

Next, the printer processor 64 will be described with reference to FIG. The printer processor 64 includes a light control filter 66 composed of C, M, and Y filters, a light source unit 72 having a light diffusion box 68 and a halogen lamp 70, and a paper magazine unit 76 containing unexposed color paper 74. Have. The light control filter 66 of the light source unit 72 and the light diffusion box
68 and a neutral density filter 11 that can be inserted into the exposure light path.
0 is arranged. In the vicinity of the printing position of the negative carrier 80, a photometer 84 composed of a two-dimensional image sensor or the like for measuring the average density or the like of the image positioned at the printing position.
Is arranged. The photometer 84 determines an exposure amount according to the density of the image based on the standard exposure condition and the photometric value, controls the dimming filter 66 of the light source unit 72 to control the exposure condition, and print quality. Are connected to a control circuit 86 that evaluates development performance and performs processing such as condition management.

Color paper 74 drawn from paper magazine section 76
In the exposure unit 88, the image of the negative film 14 is printed, and the color development unit of the processor unit 92 is connected via the reservoir unit 90.
Supplied to 94. The color paper 74 developed in the color developing unit 94 is subjected to fixing processing in a bleach-fixing unit 96, and then washed with water in a rinsing unit 98 to produce a color print. The water-washed color print is dried in the drying unit 100 and then the cutter unit 102.
Is cut into image core units. This cutter unit 102 includes
A densitometer 104 connected to the control circuit 86 is arranged so as to sandwich the conveyed color print.

On the opposite side of the color paper 74 conveyance path from the densitometer 104, a reference density plate 116 is arranged to face the densitometer 104. The densitometer 104 measures the density of the reference density plate 116 and the density of the image recorded on the color paper 74.

The control circuit 86 has a CRT 106 for displaying data and the like.
A keyboard 108 for inputting data and the like is connected. Further, as described above, the data representing the development processing characteristics of the film development transferred from the control circuit 54 of the film processor 11 is input to the control circuit 86.

Next, the operation of the present embodiment will be described. First, as a function of the film processor 11, a process of evaluating development performance using the control strip 16 for negative development and performing condition management will be described with reference to a fifth flowchart.

When performing the condition management of the development processing, the control strip 16 is loaded in the film loading unit 12. The loaded control strip 16 is transported into the processor section 22, and is sequentially transported in the developing tank 24, the bleaching tank 26, the bleach-fixing tank 28, the fixing tank 30, the rinsing tanks 32 and 34, and the stabilizing tank 36, where And treated. Thereby, the latent images 18A, 18B, 18
C, 18D and 18E are developed to form an image. The control strip 16 discharged from the processor unit 22 is dried in a drying unit 44 to remove the moisture adhering to the surface, and sent to the concentration measuring unit 48. Thus, the flowchart of FIG. 5 is executed.

In step 120, the density of each image formed on the control strip 16 is measured for each of C, M, and Y colors by a photometric system. In step 122, a deviation between the density value measured in step 120 and a reference density value obtained by measuring the density of a reference film or the like in advance is calculated. The deviation calculated here corresponds to the difference between the development condition of the film processor 11 and the standard development condition.

In step 124, it is determined whether or not this deviation is within the control limit value. If the determination in step 124 is denied, the developing condition of the film processor 11 is out of the allowable range, and a message meaning "NG" is displayed on the liquid crystal display or the like in step 126. Thus, the administrator checks each processing solution of the film processor 11, takes measures such as replenishment or replacement, and then reloads the control strip 16 into the film loading unit 12, and the processing of steps 120 to 126 is repeated. It is.

If the determination in step 124 is affirmative, it is determined that the development condition of the film processor 11 is within the allowable range. In step 128, a message indicating “OK” is displayed on a liquid crystal display or the like, and the process proceeds to step 130. Step 130
The low density LD of the density values measured in step 120 is used as data representing the development processing characteristics of the film processor 11.
Then, the density value of the high density HD is transferred to a predetermined storage area on the memory of the control circuit 86 of the printer processor 64, and the process is terminated. Therefore, the contents of the storage area are:
The data is updated each time the development condition is managed in the film processor 11 and data representing the latest development processing characteristics of the film processor 11 is always stored.

Next, the operation of the printer processor 64 will be described. The control circuit 86 performs the printing process by controlling the light control filter 66 based on the exposure control value Ej shown in the following equation.

logEj = Sj · {Aj (dDj−dwj) + dwj} + Cj (1) where J: a number from 1 to 3 representing any of R, G, B Dj: image density of a film image frame to be printed (for example, average density over the entire screen) DNj: standard negative film or multiple films Average image density of frame (for example, full screen average density) Sj: Slope control value Aj: Color correction value Cj: Color balance value depending on printer, film, and color paper characteristics Here, the variation in negative development processing characteristics is considered. , Low density LD and high density HD transferred from the film processor 11
By transforming the above equation (1) using the density value of the following equation, logEj = αj · Gj · Sj · ｛Aj (dD′j−dw′j) + dw′j} + Cj + βj · ΔLDj (2) When the density values of the low-density LD and high-density HD of the negative development control strip 16 developed under the standard development conditions are set to reference values LD ₀ and HD ₀ , respectively, Αj, βj: coefficients specific to the printer Slope control value of the above equation (1) using a reference negative film (for example, a negative for printer control)
By obtaining standard values of Sj and the color balance value Cj, and substituting them into the equation (1), standard exposure conditions can be obtained. This slope control value Sj and color balance value Cj and the low density LD and the high density
By substituting the HD density value into the equation (2), it is possible to obtain an exposure condition in which a change in the density balance of each color due to a change in the negative development characteristics is corrected.

Hereinafter, the exposure condition setting and print creation processing will be described with reference to the flowchart of FIG. Standard values are preset for the average image density DNj, the slope control value Sj, and the color balance value Cj as standard exposure conditions. Control circuit for standard exposure conditions, target density PD _BASE, etc.
It is stored in 86 memories. In addition, as data representing the reference development processing characteristics, the low density LD and the high density HD of the negative development control strip 16 developed under the standard development conditions are used.
The reference values LD ₀ and HD ₀ of the density value are also stored. It should be noted that the reference values LD ₀ and HD ₀ may be density values at the time of photometry of the reference print. When the negative film 14 developed by the film processor 11 is set on the negative carrier 80 and the exposure condition correcting switch is turned on, the processing shown in FIG. 6 is executed, and at step 150, the lamp of the densitometer 104 is turned on. The density measurement of the densitometer 104 becomes possible several tens of seconds after the lamp is turned on.

In step 152, the neutral density filter 110 is inserted into the exposure light path. In step 154, the halogen lamp 70 of the light source section 72 is turned on, and the photometer 84 measures the integrated transmission density of the light transmitted through the neutral density filter 110. The metering value when metering is Dj
Is stored in the memory. It reads the average image density DNj stored in the next memory at step 156, compares the absolute value with a predetermined value D ₀ of the difference between the photometric values Dj and the average image density DNj at step 158. | Dj-DNJ | For ≧ D _0, determines that the light source system is varied, such as by dust adhering or halogen lamp 70 to the light source unit 72 is deteriorated, and corrects an average image density DNJ in step 160 , And stores the corrected DNj. | Dj-DNJ | For <D _0, it is determined that there is no change in the light source system proceeds to step 162.

In step 162, the color correction value Aj is set to a value equal to or greater than 1.0 or a value less than 1.0 and close to 1.0. As a result, the color correction becomes a high correction or a full correction, and when determining the exposure amount of the three primary colors, one of the three primary colors has no or little effect on the other two primary colors. It can be.

In the next step 164, data representing the development processing characteristics of the film processor 11 transferred from the film processor 11 and stored in the storage area, that is, the low density LD and the high density
Read the density value data of HD. As described above, the data stored in the storage area is updated each time the condition management of the development processing of the film processor 11 is performed, so that data representing the latest development processing characteristics of the film processor 11 can be obtained. In step 166, the exposure control value Ej is calculated based on the above equation (2) using the read density value data and the corrected DNj. As a result, an exposure control value Ej obtained by correcting a variation in the density balance of each color due to a variation in the development processing characteristics of the fill processor 11 is obtained.

The coefficient Gj in the above equation (2) is a value obtained by dividing data representing the development processing characteristics of the film processor 11 by data representing the reference development processing characteristics, as shown in the equation (3). Similarly, the coefficient ΔLDj is a difference between the data representing the development processing characteristics of the film processor 11 and the data representing the reference development processing characteristics, as shown in Expression (4). For this reason, Gj and ΔLDj correspond to fluctuations with respect to the development processing characteristics that are the reference of the development processing characteristics of the film processor 11. Therefore, in the above equation (2), the exposure condition is corrected according to the variation, and when the exposure is performed under the exposure condition obtained by the equation (2), the same as when the negative film 14 is developed under the standard exposure condition. A print result can be obtained.

In the next step 168, exposure is performed by controlling the light control filter 66 based on the exposure control value Ej, and the exposed color paper 74 is subjected to development, fixing, washing, and drying processes.

In step 170, it is determined whether or not a predetermined time has elapsed from the exposure, and the like, thereby determining whether or not the print has reached the photometry position. When it is determined that the print has reached the photometric position, the print density is measured by the densitometer 104 in step 172, and the measured value is stored in the memory as PDj. In step 174, the target density value PDj _BASE is read out, and in step 176, the photometric value PDj and the target density value PDj of the print are read.
the absolute value of the difference between j _BASE to determine whether or not a predetermined value PD ₀ or more. | PDj-PDj _BASE | because when the ≧ PD _0, a case where no target density despite corrected variation of the light source system is obtained at step 160, paper and paper processing system (especially developer) it is determined that there is a change in at least one measurement value PDj at step 178 performs a correction and correction of color balance value Cj of the slope control value Sj so that the target density value PDj _BASE, and stores the result in memory. Thereby, the slope control value Sj and the color balance value Cj are corrected so that the print density becomes the target density.

In the above description, the variation of the density balance of each color due to the variation of the negative development processing characteristic is corrected using the equation (2). However, the gradation balance of each color can be corrected. For example, the control strip 16 for negative development has a medium density ND
, A low concentration LD, a medium concentration ND, and a high concentration HD
Each concentration values, LD ≒ 0.3, ND ≒ 0.8 , HD ≒ 1.6, determine the exposure condition by the equation shown by the following in case of ΔND = ND-ND _0.

logEj = αj · Gj · Sj · ｛Aj (dD′j−dw′j) + dw′j｝ + Cj + βj · ΔND (5) where dD′j = Dj− (DNj−ΔNDj), and ΔND ₀ : Reference value of medium density ND In the above equation (5), the slope control value Sj and the color balance value Cj and the density values of the low density LD, the medium density ND, and the high density HD obtained by the condition management of the negative development are used. By substituting, it is possible to obtain an exposure condition in which the variation in the gradation balance of each color due to the variation in the negative development processing characteristics is corrected. Further, the exposure condition may be obtained by performing both the correction of the density balance of each color and the correction of the gradation balance of each color.

Further, the density values LD and HD measured last time may be used as the reference values LD ₀ and HD ₀ of the density values measured on the control strip 16. In this case, the exposure condition is obtained using the following equation (6).

logEj = αj · G ″ j · S′j · ｛Aj (dD ″ j−dw ″ j) + dwj｝ + C′j + βj · ΔLD ″ j (6) where S′j = αj · Gj · Si C'j = Cj + Bj · ΔLDj DN "j = DNj-ΔLDj G" j = (HD "j-LD" j) / (HD 0 -LD 0) dD "j = Dj- (DNj-ΔLD" j) above ( Exposure conditions in which the density balance of each color has been corrected can be obtained by equation (6). Further, similarly, the gradation balance of each color can be corrected.

The target concentration value PDj _BASE In this embodiment may be changed to values by negative development processing characteristics be constant. Further, in the present embodiment, first, standard exposure conditions are determined so as to match the target density value PDj _BASE assuming that there is no change in the negative development processing characteristics, and then Gj, Δ
The correction of LDj may be added. That is, step 164 may be performed last in FIG. 6 to correct the obtained standard exposure condition. In the present embodiment, the image density of the control strip 16 for negative development is measured by the film processor 11, but the control strip 16 is set on the negative carrier 80 of the printer processor 64 and measured by the photometer 84. You may. Further, the measurement may be performed by a densitometer or the like provided separately from the film processor 11 and the printer processor 64.

In this embodiment, the control circuit of the film processor 11 is
Although the data representing the development processing characteristics are transferred and input from the 54 to the control circuit 86 of the printer processor 64 using so-called online, the data may be input via the keyboard 108, for example, or the floppy disk Alternatively, the data may be recorded in a storage medium such as, read out, and input to the printer processor 64.

In the present embodiment, an example is shown in which the present invention is applied to a photographic processing system 10 in which a film processor 11 for performing negative development and a printer processor 64 for performing print and paper development are provided separately. However, the present invention is not limited to this, and the present invention can be applied to a single photographic processing apparatus provided with a negative developing section, a printer section, and a paper developing section.

〔The invention's effect〕

As described above, according to the present invention, a latent image is recorded under predetermined conditions so that a plurality of density regions including a predetermined low-density region and a high-density region are obtained as data representing the development processing characteristics of the processor. The values of the low-density area and the high-density area visualized by processing the negative development condition management film with a processor are input to the printer, and the input values of the low-density area and the high-density area are input to the printer. Since the exposure condition is corrected by using the reference value of the high-density area and the variation in the development processing characteristics, if the development condition of the processor for developing the negative film is within the allowable range, the An excellent effect that an appropriate print can be obtained irrespective of the fluctuation of the development processing characteristics is obtained.

[Brief description of the drawings]

FIG. 1 is a schematic block diagram showing a photographic processing system according to the present embodiment, FIG. 2 is a schematic configuration diagram showing a film processor, FIG. 3 is a plan view showing a control strip for negative development, and FIG. FIG. 5 and FIG. 6 are flowcharts for explaining the operation of the present embodiment. 10: Photo processing system, 11: Film processor, 16: Control strip film for negative development, 54, 86: Control circuit, 64: Printer processor.

Claims (2)

(57) [Claims] When setting exposure conditions for a printer using a negative film developed by a processor, a plurality of densities including predetermined low-density areas and high-density areas are used as data representing development processing characteristics of the processor. Input the values of the low-density area and the high-density area visualized by developing a negative development condition management film on which a latent image is recorded under predetermined conditions so that an area can be obtained by a processor. Setting an exposure condition in which the variation in the development processing characteristics is corrected using the input values of the low-density area and the high-density area and the reference values of the low-density area and the high-density area. A characteristic exposure condition setting method. 2. The method according to claim 1, wherein a difference between the input value of the low density area and a value of the high density area is divided by a difference between a reference value of the low density area and a reference value of the high density area. 2. The exposure condition setting method according to claim 1, wherein the exposure condition is set by correcting the exposure condition based on the difference between the input value of the low density region and the reference value of the low density region.