JPH05122708A - Electronic camera - Google Patents

Abstract

PURPOSE:To easily obtain picture data under a standard lighting by measuring a spectral distribution at image pickup in addition to picture data of an object and correcting the picture data based on the spectral distribution. CONSTITUTION:A three original color (RGB) camera output V'i comprising different spectral sensitivity characteristic of an object picked up by an image pickup section 2 in a camera 1 is given to an A/D converter 3, in which the signal is converted into picture data S1 and it is stored in a memory 2. Moreover, a spectral distribution measurement section 4 measures a spectral distribution S'(lambda) of lighting for the object and stores a spectral distribution data S2 to a memory 1 via a bus 5. A CPU 6 corrects the spectral distribution S'' (l) at image pickup state read from the memory 1 based on the picture data S1 resulting from the standard spectral distribution S(lambda) stored in a memory 2 and the result is stored in a memory 3 via an interface section 7 as corrected picture data S3. Thus, even when the spectral distribution at lighting at image pickup differs from the lighting of the standard spectral distribution, the spectral distribution is corrected into the standard spectral distribution.

Description

Detailed Description of the Invention

[0001]

[Table of Contents] The present invention will be described in the following order. Field of Industrial Application Conventional Technology Problems to be Solved by the Invention Means for Solving the Problems (FIGS. 1 and 2) Action Example (FIGS. 1 and 2) Effect of the Invention

[0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic camera, and is suitable for application to, for example, an electronic still camera which stores captured still image information on a magnetic disk.

[0003]

2. Description of the Related Art Conventionally, color reproduction of an image photographed by using an electronic camera is affected by the color temperature of a light source at the time of photographing. For example, it is widely known that if an image is taken at sunset when the color temperature is low, the entire image taken is reddish. Conventionally, as a countermeasure against this, a blue optical filter is attached in front of the lens to control the color temperature or electronically achieve white balance.

[0004]

However, in order to use an optical filter, it is necessary to prepare several kinds of optical filters in advance, and color reproduction is not sufficient only by electronically white-balancing. It was. Further, when performing color correction on a captured image, the correction amount that is appropriate for a person who performs color correction differs and varies. Therefore, incorrect correction may be performed. This is because there is no clear standard for the correction amount.

The present invention has been made in consideration of the above points, and is intended to propose an electronic camera capable of reproducing a photographed image at a desired color temperature regardless of the color temperature of a light source at the time of photographing. is there.

[0006]

In order to solve such a problem, according to the present invention, in an electronic camera 1 for recording photographed image information in a recording medium (memory 3) by electronic processing, a spectral distribution of a light source at the time of photographing. Spectral distribution measuring means 4 for measuring information S ′ (λ), first storage means (memory 2) for storing image information V′i, and spectral distribution information S ′ (λ).
And a spectral distribution information S ′ stored in the second storage unit (memory 1).
Image processing for obtaining correction image information VCi obtained by obtaining a color balance correction coefficient Kij based on (λ) and correcting the color balance of the image information V'i stored in the first storage means (memory 2). Means 6 and the corrected image information VCi or the image information V′i and the spectral distribution information S ′ (λ) stored in the first and second storage means (memory 1 and memory 2) depending on the selection at the time of shooting. Any of the above is recorded in the recording medium (memory 3).

[0007]

When the image information under the standard illumination is desired to be recorded by the selection at the time of photographing, the image information under the illumination at the time of photographing is corrected and the corrected image information VCi is recorded in the recording medium (memory 3). When it is desired to record the image information V′i and the spectral distribution information S ′ (λ) at the time of photographing as they are, after photographing based on the spectral distribution information S ′ (λ), under an arbitrary illumination. Since the image information can be reproduced, the color reproducibility can be further improved as compared with the conventional case.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings.

In FIG. 1, reference numeral 1 denotes an electronic still camera which stores a still image obtained by photographing on a magnetic disk as a whole, and three primary colors (RGB) having different spectral sensitivity characteristics of an object imaged by an imaging section 2. The camera output V'i is converted into image data S1 via the analog / digital (A / D) conversion circuit 3 and stored in the memory 2.

The spectroscopic measurement unit 4 measures the spectral distribution S '(λ) of the illumination received by the subject and stores the spectral distribution data S2 in the memory 1 via the bus 5. By the way, if the illumination of the position of the subject and the illumination of the position of the electronic camera at the time of shooting are almost the same,
The spectral distribution of the illumination can be measured at the same time as the shooting of the presentation object.

Central processing unit (hereinafter CPU (central proc
The image data S1 stored in the memory 2 is corrected based on the spectral distribution of the illumination at the time of shooting and the standard spectral distribution read from the memory 1, and the corrected image data S3 is used as an interface. The data is stored in the memory 3 composed of a magneto-optical disk via the unit 7.

Here, the CPU 6 stores the corrected image data S3 in the memory 3 based on the processing procedure shown in FIG. That is, the CPU 6 enters the processing procedure from step SP1, measures the spectral distribution S '(λ) of the illumination in step SP2, and stores it in the memory 1.

Subsequently, the CPU 6 stores the image data S1 of the camera output V'i in the memory 2 at step SP3, moves to step SP4, and determines whether or not to immediately correct the image data S1. If a negative result (which means no correction) is obtained here, CP
U6 moves to step SP5, stores the spectral distribution data S2 of the illumination and the photographed image data S1 in the memory 3 so that the image data S1 can be corrected later, and moves to step SP6 to end the processing. There is.

By storing the spectral distribution data S2 of the illumination and the photographed image data S1 in the memory 3 in this way, the illumination at the time of photographing is assumed to be the illumination as if the illumination of the later spectral distribution is assumed. It is designed so that it can be corrected as if it were hot.

On the other hand, when an affirmative result is obtained (this means that the correction is made), the CPU 6 moves to step SP7 to obtain the correction coefficient Kij, and the subsequent step SP.
8, the image data S1 is corrected to the corrected image data S3 based on the equation (3). After that, in step SP9, the CPU 6 stores the corrected image data S3, which is corrected as if the illumination at the time of shooting was standard illumination, in the memory 3, and ends the processing.

In the above structure, the electronic still camera 1
Corrects the image data S1 based on the following procedure when a subject is imaged. That is, if the standard illumination spectral distribution is S (λ) (where λ is the wavelength; the same applies hereinafter) and the illumination spectral distribution at the time of shooting is S ′ (λ), the standard illumination spectral distribution S ( λ) is known, and the spectral distribution S ′ (λ) of the illumination at the time of shooting is measured at the time of shooting (step SP2).

Further, the spectral sensitivity of the camera is Ri (λ) (i =
1, 2, ... N), and in the case of this embodiment, the spectral sensitivity Ri
(λ) is known. Generally, n is 3, and the spectral sensitivity R1
(λ), R2 (λ) and R3 (λ) are the three primary colors R and
It corresponds to the spectral sensitivity of G and B. Further, the spectral sensitivity Ri (λ) is assumed to be 0 at wavelengths other than visible light wavelength λ = 380 to 780 [nm].

Further, assuming that the spectral reflectance of the object is ρ (λ) and the camera output Vi under standard illumination is obtained, the following equation is obtained.

[Equation 1] It is represented by. Where ∫ represents the definite integral and the integration range is λ
= 380 to 780 [nm].

On the other hand, the camera output V'i at the time of photographing is
The following formula

[Equation 2] It is represented by. Here, the corrected camera output VCi is calculated by using the following camera output V'i at the time of shooting.

[Equation 3] Can be expressed as

[Equation 4] The variable Kij that reduces the error ERRi between the camera output Vi due to the standard illumination given by and the corrected camera output VCi is calculated, and is substituted into the equation (3) to obtain the camera output V'i at the time of shooting as a standard value. It can be corrected to the camera output Vi under various lighting conditions.

Here, the electronic still camera 1 has a step S
At P7, the variable Kij for reducing the equation (4) is obtained by the following method. That is, the electronic still camera 1
By transforming equation (3), the following equation

[Equation 5] Can be expressed as S (λ) · Ri in equation (1)
(λ) and S ′ (λ) · (ΣKij · Ri (λ) in equation (5)
It is expected that the error ERRi will also be small if the difference between) and S (λ) · Ri (λ) and S ′ (λ) ·
Integrated value IERRi of the squared value of the difference of (ΣKij · Ri (λ))
Ask for.

Where IERRi is the following equation

[Equation 6] (6) is minimized by the following equation for each i, j (i = 1, 2 ... n, j = 1, 2 ... n)

[Equation 7] By satisfying the condition of

[Equation 8] In, i and j are respectively changed to 1, 2, ... N (n is arbitrary) to obtain n ² equations including n ² variables Kij.

By solving these n ² equations as simultaneous equations, the variable Kij can be obtained.
By using ij, the illumination at the time of photographing can be corrected as if the illumination had a standard spectral distribution (step SP8).

According to the above configuration, when the subject is photographed, the spectral distribution of the illumination at the time of photographing is measured together with the image data, so that the spectral distribution of the illumination at the time of photographing is different from that of the standard spectral distribution. Also in this case, it is possible to correct the image data with the illumination of the standard spectral distribution and store it in the memory 3. Further, by measuring the spectral distribution of the illumination when photographing the subject together with the image data of the subject and storing it in the memory 3, after the photographing, the spectral distribution of the illumination during the photographing is used to measure the spectral distribution of the illumination during the photographing. The image data under different illumination can be easily obtained by correcting.

In the above embodiment, when the spectral reflectance ρ (λ) is constant regardless of the wavelength λ, the camera output Vi obtained by standard illumination does not match the corrected camera output VCi (Vi ≠). VCi) is used to correct the image data, but the present invention is not limited to this, and when the spectral reflectance ρ (λ) is constant regardless of the wavelength, the camera output Vi by standard illumination and the corrected camera are corrected. The image data may be corrected by obtaining the variable Kij that minimizes the error IERRi under the condition that the outputs VCi match (Vi = VCi).

That is, when the spectral reflectance ρ (λ) is constant irrespective of the wavelength, the camera output Vi obtained by standard illumination and the corrected camera output VCi coincide with each other.

[Equation 9] Is established. Here, from equation (9),

[Equation 10]

[Equation 11] In order to minimize the error IERRi by

[Equation 12] It is time for

Thus, the following equation

[Equation 13] I and j of i = 1, 2 ... N, j = 2, 3 ...
... When the value of definite integral is calculated by changing it to n, n (n-
1) There are n (n-1) equations including the variables Kij. This n (n-1) simultaneous equations are solved and the variables Kij
The variable Ki ₁ may be obtained by obtaining

Further, in the above-mentioned embodiment, the case where the spectral reflectance ρ (λ) is constant regardless of the wavelength has been described, but the present invention is not limited to this, and the spectral reflectance ρ (λ) is different for each wavelength. It can be applied to different cases. That is, the spectral reflectance of a standard subject, such as human skin, blue sky, and green of plants, is ρk (λ) (k = 1, 2 ... m) (m is arbitrary), and the spectral reflectance ρk (λ) Is known, the camera output Vki of a standard subject with standard lighting at this time is

[Equation 14] It is represented by.

On the other hand, the standard camera output V'ki of the illuminator at the time of photographing is

[Equation 15] It is represented by. Here, the output VCki, which is obtained by correcting the camera output of the standard exhibitor with the lighting at the time of shooting,

[Equation 16] And

At this time, the camera output V by standard illumination
The error ERRi between ki and the corrected camera output VCi is

[Equation 17] If SERRi given by is small, the error ERRi is also expected to be small.

[Equation 18] Can be obtained by obtaining a variable Kij that minimizes.

Equation (18) is minimized here by

[Formula 19] By satisfying,

[Equation 20] In, the values of the camera output Vki and the like under standard illumination are calculated by changing i = 1, 2 ... n and j = 1, 2 ... n, and n ² variables including n ² variables Kij are calculated. The equation of The same effect as described above can be obtained by using the variable Kij obtained by solving this equation as a simultaneous equation.

Further, in the above-mentioned embodiment, the case of the three primary color signals as the camera output has been described, but the present invention is not limited to this and can be widely applied to the case of inputting other video signals.

Further, in the above-mentioned embodiment, the case where the magneto-optical disk is used as the memory 3 which is a storage medium of the image data and the spectral distribution data has been described, but the present invention is not limited to this and is applied to a memory card or the like. May be.

Further, in the above-mentioned embodiments, the case where the present invention is applied to the electronic still camera has been described, but the present invention is not limited to this, and an electronic camera such as a video camera for storing image information of a subject as image data. It can also be widely applied to.

[0034]

As described above, according to the present invention, when the subject is not photographed under the standard illumination by measuring the spectral distribution of the illumination at the time of photographing in addition to the image data of the subject. However, by correcting the image data based on the spectral distribution, the image data under standard illumination can be easily obtained, and the color reproducibility can be further improved as compared with the conventional one. .. In addition, by storing the spectral distribution of illumination at the time of shooting and the image data of the photographed subject, even if image data under illumination with an arbitrary spectral distribution is required after shooting, The image data can be easily corrected and obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an electronic camera according to the present invention.

FIG. 2 is a flow chart used for explaining the processing procedure.

[Explanation of symbols]

1 ... Electronic still camera, 2 ... Imaging unit, 3 ... Analog / digital conversion circuit, 4 ... Spectroscopic measurement unit, 6 ... C
PU, 7 ... Interface section.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Kaoru Yoshino 6-735 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation (72) Inventor Akira Ogai 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Within the corporation

Claims (1)

[Claims] 1. An electronic camera for recording photographed image information on a recording medium by electronic processing, wherein a spectral distribution measuring means for measuring spectral distribution information of a light source at the time of photographing, and a first memory for storing the image information. Means, a second storage means for storing the spectral distribution information, and a color balance correction coefficient based on the spectral distribution information stored in the second storage means.
Image processing means for obtaining corrected image information obtained by correcting the color balance of the image information stored in the storage means, and the corrected image information or the first and second storages is selected according to the selection at the time of photographing. An electronic camera, characterized in that one of the image information and the spectral distribution information stored in the recording means is recorded in the recording medium.