JPH10221791A - Printing exposure deciding method for photograph - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a printed photograph whose brightness and color balance are excellent by deciding printing exposure based on an image characteristic value when the information of conditions for printing a print is recorded at a photographing time and correcting it by using the information of exposure correction quantity showing the correction quantity of photographing exposure when the information of the exposure correction quantity is recorded. SOLUTION: A photographic film F is positioned at an exposure part on an exposure table 21 and the original image of the film F is illuminated with light emitted from a light source 22. The signals of respective colors B, G and R obtained by photoelectrically converting this received light quantity are outputted to an image processing part 40 and transmitted to an exposure control part 20 so as to decide the reference printing exposure of the respective colors B, G and R. Besides, the table 21 is provided with the read device of film information magnetically recorded on the film F. Then, the information is inputted in a film information processing part 50. By the processing part 50, the correction quantity of the reference printing exposure is arithmetically operated and transmitted to the control part 20 as a correction signal. Then, the reference printing exposure is corrected based on the correction signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a method for determining a printing exposure amount or an exposure correction amount when processing printing of a photograph.

[0002]

2. Description of the Related Art In a conventional photographic printing apparatus, when printing on photographic paper or the like, the entire area of a frame (original image) recorded on a photographic film is represented by blue (B), green (G), and red (R). (Less than,
(Hereinafter simply referred to as B, G, and R), and an image characteristic value is calculated from the average transmission density (LATD) of each of the obtained primary colors, and the exposure amount in photographic printing is calculated based on the image characteristic value. Is determined.

In addition, a new type of APS (Advanced)
When a photographic film used in Photo System is printed on photographic paper or the like, printing is performed using a printing exposure amount determined based on print printing condition information recorded on the photographic film at the time of shooting with a camera. For example, for a frame shot with an appropriate exposure amount, a predetermined exposure amount is corrected according to a film type to determine a printing exposure amount, and printing is performed (Japanese Patent Laid-Open No. 5-127271).
For a plurality of frames of the same or similar image scene, printing is performed by determining a printing exposure amount under the same or similar printing conditions (Japanese Patent Laid-Open No. 6-16).
No. 0996).

[0004]

By the way, the photographer sometimes intentionally corrects the exposure to take a picture. In this case, in the above-mentioned conventional method, all the pictures or a plurality of pictures are taken. Since the control is performed based on the printing exposure amount determined based on the average density, even for the frame on which the exposure correction has been performed, printing is performed at the exposure amount based on the average density. The reflected image will not be printed.

For example, when an image is shot with a correction to open the exposure, the exposure is controlled by an automatic exposure control (AE) performed without correction, and the density of the frame shot by the exposure aperture correction is increased. Since the average density increases and the printing exposure amount is determined by correcting the increase, the printed image is corrected to be brighter. If the image was taken with the exposure reduced, the average density would decrease,
The result is a darkened corrected print.

In particular, when a plurality of images of the same or similar scenes are photographed with the same exposure correction being performed, if the printing exposure amount is determined based on the average density of the plurality of images, almost all exposure corrections are made. Exposure amount correction that cancels out is performed, and the exposure correction photographing has a meaningless result. In addition, even for frames for which exposure correction is not performed, the printing exposure amount is affected by the frames for which exposure correction has been performed, and image quality is degraded.

In the photographic printing method described in Japanese Patent Application Laid-Open No. Hei 3-91733, if the photographer performs exposure correction, the original image itself is corrected. I have. However, as a practical matter, it is impossible to faithfully reproduce a printed image by such a method. The cause may be the influence of the narrowness of the reproduction range of the printing paper on the development characteristics of the film, the storage state of the film, and the reproduction range of the film.

Therefore, the printer needs some kind of exposure correction at the time of printing. The present invention has been made in view of such a conventional problem, and photographic printing in which the exposure compensation is sufficiently reflected is performed on an original image photographed by performing the exposure compensation, and the exposure compensation is performed. It is an object of the present invention to provide a photographic printing exposure amount determining method in which good photographic printing is performed on an original image photographed without performing the above without affecting exposure correction.

[0009]

For this reason, the invention according to claim 1 is a method for printing an original picture on a photographic light-sensitive material, wherein a plurality of continuous original pictures on the photographic light-sensitive material including the original picture are printed. When valid print printing condition information is recorded at the time of photographing, the printing exposure amount for the original is determined based on the image characteristic values obtained from the continuous originals, and the print exposures for the continuous originals are determined. If the exposure correction amount information indicating the amount of the exposure correction performed at the time of the photographing is recorded for a part or all of the image, the exposure correction amount is corrected using the exposure correction amount information. It is characterized by.

In this way, when effective print printing condition information is recorded for a plurality of continuous original images, the characteristics of the captured image are matched based on the image characteristic values of the plurality of original images. The printing exposure amount can be determined, and if exposure correction amount information indicating the amount of shooting exposure correction performed at the time of the photographing is recorded for some or all of the continuous original images, Since the printing exposure amount determined as described above is corrected based on the exposure correction amount information at the time of shooting, the intention of the exposure correction is appropriately reflected on the original image obtained by performing the exposure correction. Is obtained, and the original image taken without exposure compensation is
A printed image free from the effects of exposure compensation can be obtained.

Further, the invention according to claim 2 is characterized in that the image characteristic value is an average density or an average transmittance of the plurality of original images. The average brightness of these original images can be obtained from the average density or average transmittance of a plurality of original images. If the basic printing exposure amount is determined based on this, a printed image with appropriate brightness can be obtained. be able to.

Further, the invention according to claim 3 is characterized in that the image characteristic value is an average value of density or transmittance for each of the color components (B, G, R) of the plurality of original images. As described above, if the basic printing exposure amount is determined based on the average value of each color component of a plurality of original images, the printing exposure amount can be determined for each color component and printing can be performed. A printed image with good color balance can be obtained.

The invention according to claim 4 is characterized in that the image characteristic value is a color component weighted average of the density or transmittance of the plurality of original images calculated by the following equation. 3. The method for determining the exposure amount of photographic printing according to item 1. NTli = (c · NTl Bi + d · NTl Gi + e · N
Tl Ri) NTl: Color component weighted average density or transmittance of each original image i: Target frame number c, d, e: c + d + e = 1, c> 0, d> 0, e> 0
In this way, by using the weighted average value weighted for each color component of density or transmittance,
For example, even when the color characteristics of the original image and the color characteristics of the printing photographic paper are different, by setting the weights in consideration of the difference in the color characteristics, the appropriate printing exposure amount and the exposure correction amount are determined and printing is performed. And a printed image with good brightness and color balance can be obtained.

[0014] Further, for example, by setting information for increasing the weight of a specific color component, for example, the R component, as film information, a photographer can obtain a desired reddish printed photograph, for example, by the photographer. Is also possible.
The invention according to claim 5 is characterized in that a common photographic printing exposure amount is determined for all the original images to be printed on the photographic material.

In the case where the performance of automatic exposure control on the camera side is high and the optimal exposure control intended by the photographer is performed for each original image, based on the image characteristic value and the exposure correction amount. A good printed image can be obtained even when printing is performed by using the determined and corrected printing exposure amount as a printing exposure amount common to all original images. The invention according to claim 6 is characterized in that the print printing condition information is information for instructing printing of all original images on the photographic material under the same printing condition.

As described above, when optimal exposure control is performed for each original image, all the original images are printed using the same printing conditions, that is, the printing exposure amount calculated for each original image in the same manner. By printing, a good printed image can be obtained while adjusting the exposure amount for each image characteristic. Further, the invention according to claim 7 is characterized in that the print burning condition information is information indicating that it is an original image of a related scene.

A plurality of original pictures of related scenes are
Since they have the same or similar image characteristics, by printing them together under the same printing conditions, a good printed image can be obtained. The invention according to claim 8 is characterized in that, when correcting the printing exposure amount using the exposure correction amount, the printing exposure amount is corrected by a formula including a term shown in the following (1).

[0018]

(Equation 4)

N: total number of target frames i: target frame number EX: exposure amount based on exposure correction amount information EX = 0: no exposure correction amount information EX 情報 0: exposure correction amount information exists The value given in (1) above. Represents the amount of influence of each exposure on the target original image due to the exposure correction. By correcting the printing exposure using this value, it is possible to correct the printing exposure by removing the effect of the exposure correction. It becomes possible.

The invention according to claim 9 is characterized in that the printing exposure amount of each original image is calculated by the following equation.

[0021]

(Equation 5)

ETl: Exposure exposure amount ET0: Reference exposure amount for exposure CT0: Reference density or transmittance CTl: Average density or transmittance for each color component of each original image EX: Exposure amount based on exposure correction amount information EX = 0: Exposure No correction amount information EX # 0: Exposure correction amount information exists x: Color component (B, G, R) n: Total number of target frames i: Target frame number α: Collection coefficient (-1 ≦ α ≦ 0) β: Weighting Coefficient (βB + βG + βR = 1 _, βB> 0,
βG> 0 _, βR> 0) In this way, when determining the printing exposure amount for a plurality of original images to be printed under the same printing conditions, if an original image subjected to exposure correction is included, the original image Since the exposure value EX corresponding to the exposure correction is calculated by subtracting the exposure value EX corresponding to the exposure correction from the average density or transmittance of the image, the basic printing exposure amount is determined by comparing the average density excluding the influence of the exposure correction with the reference value. Can be.

Therefore, an appropriate printing exposure amount can be determined for an original image that is not subjected to exposure correction without being affected by the exposure correction. It is possible to determine a printing exposure amount that can obtain the effect of exposure correction. Also, by calculating the average density or transmittance for each color component, and using the reference density for each color component,
Since the printing exposure amount is determined for each color component, a printing photograph having good brightness and color balance can be obtained.

Further, the invention according to claim 10 is characterized in that the printing exposure amount of each original image is calculated by the following equation.

[0025]

(Equation 6)

ETl: Exposure exposure for printing ET0: Exposure exposure for reference CT0: Reference density or transmittance NTl: Weighted average density or transmittance of each original color component, ie, NT1 = c.NT1B + d.NT1G + e.NT1c, d , E are c + d + e = 1, c> 0, d> 0, e>
EX: exposure amount based on exposure correction amount information EX = 0: no exposure correction amount information EX ≠ 0: exposure correction amount information exists x: color component (B, G, R) n: total number of target frames i: target frame number α: collection coefficient (−1 ≦ α ≦ 0) β: weighting coefficient (βB + βG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0) By doing so, the same operation and effect as the invention according to claim 9 can be obtained.
In addition to the effect, the same operation and effect as the invention according to claim 4 can be obtained. That is, by setting a weight in consideration of the difference between the color characteristics of the original image and the color characteristics of the printing photographic paper, an appropriate printing exposure amount can be determined to obtain a printing photograph having good brightness and color balance, or By setting the weighting information of the color components according to the photographer's request as the film information, it is possible to obtain a printed photograph having the color balance desired by the photographer.

[0027]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the photographic printing exposure determining method of the present invention will be described below with reference to the drawings. FIG.
1 shows a schematic configuration of a photographic printing apparatus, and the outline of the photographic printing process will be described with reference to FIG.

The photographic film F is set on a pair of spools (not shown) at both ends in the longitudinal direction, and is wound up one frame at a time. The case where the photographic film F of the present embodiment is a photographic film of APS specification in which shooting information is recorded will be described. The photographic film F is positioned at an exposure portion on an exposure table 21 and mixed by light emitted from a light source 22 passing through a mirror tunnel 23, and the original image of the photographic film F set on a negative mask 24 as uniform surface light Is illuminated. At this time, the average transmitted light of the B, G, and R colors of the original image is received by the two-dimensional image sensor 29 constituting the image pickup unit through the photometric filters 28 of the B, G, and R colors arranged in a stripe on the upper surface. The signals of the B, G, and R colors obtained by photoelectrically converting the amount of received light are output to an image processing unit 40, shaped into image density information in a predetermined format, and then sent to an exposure control unit 20. The exposure control unit 20 determines the reference printing exposure amount for each of the B, G, and R colors based on the image density data.

The exposure table 21 is provided with a device for reading film information magnetically recorded on the photographic film F, and the read film information is input to the film information processing unit 50. Here, the film information includes not only information on the entire film such as instruction information for printing all the frames of the film under the same printing conditions, but also information on each frame, for example, information indicating that a similar scene has been shot continuously or shooting The information includes exposure correction information by the user, and backlight shooting information and the like. The film information processing unit 50 performs a process described below in accordance with the film information including the various types of information, and as a result, calculates a correction amount of the reference printing exposure amount, and sends it to the exposure control unit 20 as a correction signal.

The exposure control unit 20 corrects the reference printing exposure amount by the correction signal, and outputs the finally obtained printing exposure amount for each color component (B, G, R) to the light source 22 and the mirror tunnel 23. Yellow (Y), magenta (M),
Cyan (C) subtractive color cut filters 32a, 32b, 32c
And a dark shutter 33 disposed below the zoom lens 25.
Is converted as the operating time of A drive signal corresponding to the operation time is output to the filter drive unit 30 and the shutter drive unit 31, and under the drive control of the filter drive unit 30 and the shutter drive unit 31, the cut filters 32a, 32b, 32
c and the dark shutter 33 are inserted into the exposure light path, and the exposure amount given to each color photosensitive layer of the photographic printing paper 27 is adjusted. The transmitted light of the photographic film F is appropriately enlarged by a zoom lens 25 whose desired magnification has been adjusted, optically focused on a photographic paper 27 set in a photographic paper holder 26, and exposed. After the end of the exposure, the photographic printing paper 27 is transported by a predetermined distance in preparation for the next exposure, and the photographic film F is transported to position the next original to be printed in the exposure section. As described above, the original images formed on the photographic film F are sequentially printed.

In the present embodiment, the photographic film F is conveyed while the photographic film F is being conveyed and the image of each frame is read and the film information is read while the photographic film F is being conveyed before the exposure printing. After determining the final printing exposure amount, it is transported to the exposure unit again for each frame and exposure printing is performed while opening the dark shutter 33, and the exposure unit obtains data necessary for exposure of the original image And the size and cost of the device can be reduced. However, an imaging unit and a film information reading unit may be separately provided in front of the transport path of the printing exposure unit to determine the exposure amount of each frame, and then transported to the printing exposure unit to perform printing exposure. Larger and more expensive, but more efficient.

Next, a routine for calculating the amount of printing exposure based on exposure correction amount information according to the present invention will be described with reference to the flowchart shown in FIG. In step 1, the average density CTli for each of B, G, and R of each frame i (i = 1 to n) is calculated. In step 2, it is determined whether or not exposure correction amount information by the photographer has been recorded at the time of shooting from the film information for each frame i.
The exposure correction amount EXi corresponding to the exposure correction amount is read,
For frames not recorded, the exposure correction amount EXi = 0 is set.

In step 3, from the film information,
Instruction information for printing all frames n of the photographic film under the same printing condition is output, or a plurality of i (= 1 to m <n) of the same or similar scenes (related scenes)
Then, it is determined whether or not instruction information for printing the frame under the same printing condition has been issued. If all the frames have the same printing condition instruction information, the flow advances to step 4 to calculate the printing exposure amount for each of B, G, and R for each frame according to the following equation.

[0034]

(Equation 7)

ETl: Printing exposure amount ET0: Reference printing exposure amount CT0: Reference density or transmittance CTl: Average density or transmittance for each color component of each original image EX: Exposure amount based on exposure correction amount information EX = 0: Exposure No correction amount information EX # 0: Exposure correction amount information exists x: Color component (B, G, R) n: Total number of target frames i: Target frame number α: Collection coefficient (-1 ≦ α ≦ 0) β: Weighting Coefficient (βB + βG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0) Here, the exposure amount EX based on the exposure correction amount information increases the density of the original image (negative) when overexposure correction is performed during shooting. The value is set to a positive value according to the exposure correction amount so that the density is corrected to reduce the influence of the exposure correction, and is set to a negative value according to the correction amount for the exposure aperture correction. Is done.

If the same burning condition instruction information of the same or similar scene has been output in step 1, the process proceeds to step 5, and the B, G, and R of each frame targeted for these instructions are output. Is calculated according to the following equation.

[0037]

(Equation 8)

ETl: Printing exposure amount ET0: Reference printing exposure amount CT0: Reference density or transmittance CTl: Average density or transmittance for each color component of each original image EX: Exposure amount based on exposure correction amount information EX = 0: Exposure No correction amount information EX # 0: Exposure correction amount information exists x: Color component (B, G, R) m: Total number of target frames j: Target frame number α: Collection coefficient (-1 ≦ α ≦ 0) β: Weighting Coefficient (βB + βG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0) In this way, if there is a frame shot by performing exposure correction among a plurality of frames for which the same printing condition is specified, the exposure correction is performed on the frame. Since the average density of the image obtained when the image density is not obtained is corrected, the average density of a plurality of frames is obtained by correction, and the basic exposure correction according to the deviation from the reference density CT0x is performed.
For frames that have not been subjected to exposure correction, it is possible to determine the appropriate exposure amount for exposure, and for frames that have been exposure-corrected, it is possible to determine the exposure amount at which exposure correction effects can be obtained. it can.

The average density or transmittance CT for each color component
1x, and using the reference density EX0x for each color component,
Since the printing exposure amount ETlx is determined for each color component, a printing photograph having good brightness and color balance can be obtained. Also,
In step 6, for each of the remaining frames k (= 1 to nm) other than the same or similar scene, the printing exposure amount for each of B, G, and R is calculated according to the following equation.

ETlx = (CTlxk · CT0x) + α
・ (CTlxk ・ CT0x + Nx) + ET0x where Nx = βx ・ ｛(CTlBk + CTlGk + CTlR
k)-(CT0B + CT0G + CT0R)｝ ETl: Printing exposure amount ET0: Reference printing exposure amount CTl: Average density or average transmittance for each color component of each original CT0: Reference density or transmittance x: Color component (B, G) , R) k: Target frame number α: Collection coefficient β: Weighting coefficient (βB + βG + βR = 1, βB> 0,
βG> 0, βR> 0) As described above, in the present embodiment, for the remaining frames other than the frames of the same or similar scene, the printing exposure amount is determined based on the average density of each frame. The printing exposure amount may be determined from the average density and the printing exposure correction amount obtained by the scanner.

The printing exposure amount or exposure correction amount under the same printing conditions for all frames in step 4 and the printing exposure amount under similar scenes in the same printing condition in step 5 are calculated and determined according to the following equations. You may make it. (Same printing conditions for all frames)

[0042]

(Equation 9)

ETl: Printing exposure amount ET0: Reference printing exposure amount CT0: Reference density or transmittance NTl: Color component weighted average density or transmittance of each original image, ie, NTl = c ・ NT1B + d ・ NT1G + e ・ NT1R c, d , E are c + d + e = 1, c> 0, d> 0, e>
EX: exposure amount based on exposure correction amount information EX = 0: no exposure correction amount information EX ≠ 0: exposure correction amount information exists x: color component (B, G, R) n: total number of target frames i: target frame number α: collection coefficient (−1 ≦ α ≦ 0) β: weighting coefficient (βB + βG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0) (Similar scene same burning condition)

[0044]

[Equation 10]

ETl: Exposure exposure amount for printing ET0: Exposure amount for reference printing CT0: Reference density or transmittance NTl: Weighted average density or transmittance of each original color component, ie, NTl = c ＝ NT1B + d ・ NT1G + e ・ NT1c, d , E are c + d + e = 1, c> 0, d> 0, e>
EX: Exposure amount based on exposure correction amount information EX = 0: No exposure correction amount information EX ≠ 0: Exposure correction amount information exists x: Color component (B, G, R) m: Total number of target frames j: Target frame number α: Collection coefficient (-1 ≦ α ≦ 0) β: Weighting coefficient (βB + βG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0) In this way, if the weighting coefficient is set for each color component and the printing exposure amount is determined based on the weighted averaged density or transmittance, the same operation and effect as in the above embodiment can be obtained. By setting weights in consideration of the difference between the color characteristics of the original image and the color characteristics of the printing photographic paper, it is possible to determine an appropriate printing exposure amount and obtain a printing photograph having good brightness and color balance. By setting the weights of the color components according to the photographer's desire, it is also possible to obtain a printed photograph having the color balance desired by the photographer.

When the weights c, d, and e of B, G, and R for each color component are set to c = d = e = 1/3, it is the same as the case where the average density is simply obtained instead of each color component. Where, for example, c
= 1/6, d = 2/6, and e = 3/6, the image can be printed so as to make the bluish light and the reddish dark.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a photographic printing apparatus according to an embodiment.

FIG. 2 is a flowchart of a printing exposure amount calculation processing routine according to the embodiment.

[Explanation of symbols]

 20 Exposure control unit 22 Light source 29 Photodiode 30 Filter drive unit 31 Shutter drive unit 32a, 32b, 32c cut filter 40 Image processing unit 50 Film information processing unit F Photographic film

Claims (10)

[Claims] When printing an original image on a photographic material, print printing condition information effective for a plurality of continuous original images on the photographic material including the original image is recorded at the time of photographing. Determining a printing exposure amount for the original image based on the image characteristic values obtained from the plurality of continuous original images; A method for determining a photographic printing exposure amount, comprising: when exposure correction amount information indicating an amount of correction is recorded, correcting the printing exposure amount using the exposure correction information. 2. The image characteristic value is an average density or an average transmittance of the plurality of original images.
3. The method for determining the exposure amount of photographic printing according to item 1. 3. The photographic printing exposure method according to claim 1, wherein the image characteristic value is an average value of densities or transmittances of the color components (B, G, R) of the plurality of original images. How to determine quantity. 4. The photographic printing exposure determining method according to claim 1, wherein said image characteristic value is a color component weighted average value of density or transmittance of said plurality of original images calculated by the following equation. Method. NTli = (c · NTl Bi + d · NTl Gi + e · N
Tl Ri) NTl: Color component weighted average density or transmittance of each original image i: Target frame number c, d, e: c + d + e = 1, c> 0, d> 0, e> 0
Weighting factor that satisfies 5. The photograph according to claim 1, wherein a common photographic printing exposure amount is determined for all of the original images to be printed on the photographic material. Printing exposure determination method. 6. The print printing condition information according to claim 1, wherein the print printing condition information is information for instructing printing of all original images on the photographic material under the same printing condition. 4. A method for determining an exposure amount for photographic printing according to any one of (1) to (4). 7. The photographic printing method according to claim 1, wherein said print printing condition information is information indicating that the image is an original image of a related scene. Exposure determination method. 8. The method according to claim 1, wherein, when correcting the printing exposure amount using the exposure correction amount, the printing exposure amount is corrected by a formula including a term shown in the following (1). A method for determining a photographic printing exposure amount according to one of the above. (Equation 1) n: total number of target frames i: target frame number EX: exposure amount based on exposure correction amount information EX = 0: no exposure correction amount information EX ≠ 0: exposure correction amount information exists 9. The printing method according to claim 1, wherein the printing exposure amount of each original image is calculated by the following equation.
4. A method for determining an exposure amount for photographic printing according to any one of (1) to (4). (Equation 2) ETl: Printing exposure amount ET0: Reference printing exposure amount CT0: Reference density or transmittance CTl: Average density or transmittance for each color component of each original image EX: Exposure amount based on exposure correction amount information EX = 0: Exposure correction amount information None EX # 0: Exposure correction amount information exists x: Color component (B, G, R) n: Total number of target frames i: Target frame number α: Collection coefficient (-1 ≦ α ≦ 0) β: Weighting coefficient (βB + ΒG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0) 10. The photographic exposure determining method according to claim 1, wherein the printing exposure of each original image is calculated by the following equation. (Equation 3) ETl: Exposure exposure amount for printing ET0: Reference exposure amount for printing CT0: Reference density or transmittance NTl: Weighted average density or transmittance of each original color component, that is, NTl = c.NT1B + d.NT1G + e.NT1c , C + d + e = 1, c> 0, d> 0, e>
Weighting coefficient EX satisfying 0: exposure amount based on exposure correction amount information EX = 0: no exposure correction amount information EX ≠ 0: exposure correction amount information exists x: color component (B, G, R) n: total number of target frames i: target frame number α: collection coefficient (−1 ≦ α ≦ 0) β: weighting coefficient (βB + βG + βR = 1 _, βB> 0 _,
βG> 0 _, βR> 0)