KR20120130051A - Imaging apparatus, light emitting device, imaging system, and control method - Google Patents

Abstract

PURPOSE: A photographing device, a light emitting device, a photographing system, and a controlling method are provided to prevent a lack of an exposure by controlling a light emitting amount when photographing a main subject. CONSTITUTION: A photographing device comprises a light measurement value acquisition unit, a color information acquisition unit, a determination unit, a calculation unit, and a selection unit. The light measurement value acquisition unit acquires a plurality of light measurement values respectively corresponding to each light measurement area. The color information acquisition unit acquires a plurality of color information respectively corresponding to the each light measurement area. The determination unit determines a weighting factor vector of a plurality of the light measurement areas. The calculation unit calculates a main light emitting amount of a light emitting device after adding a weighted grade to the light measurement areas according to the weighting factor vector determined by the determination unit. The selection unit selects a reference area used for determining the weighting factor vector of the light measurement areas.

Description

Imaging Apparatus, Light Emitting Apparatus, Imaging System and Control Method {IMAGING APPARATUS, LIGHT EMITTING DEVICE, IMAGING SYSTEM, AND CONTROL METHOD}

The present invention relates to light emission control when photographing using a light emitting device.

There is a method of determining the amount of light emitted by performing preliminary light when photographing a subject by light emission imaging using a light emitting device. According to this method, the preliminary light emission is performed using a light emitting device before main photographing, and the amount of reflected light from the subject is obtained. The amount of light emitted during the main photographing is calculated based on the amount of reflected light acquired in the preliminary light emission. For example, Japanese Patent Laid-Open No. 2005-275265 discloses a method for determining the amount of light emitted by the calculation described below.

First, the ratio of the luminance value H (i) at the time of preliminary emission in each of the photometric areas A0 to A22 to the object luminance value P (i) in each of the light metering areas A0 to A22 immediately before the preliminary emission. Calculate R (i)

Next, the largest value of the ratio R (i) in the said photometric area A0 to A22 is extracted as a reference value aseR. The photometric area used as the target area when the ratio R (i) is extracted to the reference value JasrR is a photometric area between the threshold LL0 and L1 where the amount of reflected light at the time of preliminary light emission is set according to the distance to the subject.

Further, when determining the photometric area used as the target area when extracting the photometric area whose ratio R (i) is the reference value JasrR, if the attached lens unit has a distance encoder, the above-described information is obtained based on the information obtained from the distance encoder. Set the threshold L_L0 and L_L1. In the case where the attached lens unit does not have a distance encoder, the threshold LXL0 and LXL1 are set by a distance determined according to past experience.

The extracted reference value JasrR is compared with the ratio R (i) in each of the photometric areas A0 to A22, and the weighting coefficient W (i) in each of the photometric areas A0 to A22 is obtained. The weighting calculation of the reflected light of a subject is performed using the obtained weighting coefficient W (i). In addition, the amount of light emitted during imaging is calculated using the result of the weighting operation.

According to the method described in Japanese Patent Laid-Open No. 2005-275265, stable exposure is obtained in many scenes. In addition, when imaging is performed in the same scene but with a slightly different composition, an imaging result with less change in exposure can be obtained.

However, since the weighting factor W (i) is increased based on the main subject area, which is a light metering area where R (i) is the maximum by satisfying a predetermined condition, an object is positioned relatively close to the shooting screen or a product having high reflectance is included. In this case, the weighting coefficient W (i) may become large.

For example, in the past experience, when the shooting screen includes a high reflection object such as a gold screen, and the accuracy of the distance encoder information obtained from the distance encoder mounted on the lens unit is poor or the lens unit does not have a distance encoder. In determining the distance accordingly, the photometric area including the gold folding screen is regarded as the main subject area. In such a case, when the light emission amount is calculated, the weighting coefficient W (i) of the light metering area including the gold screen becomes large, so that the light emission amount is insufficient for photographing the main subject, and the exposure may be insufficient.

According to one aspect of the present invention, an imaging device that can be photographed using a light emitting device includes: a metering value acquisition unit for acquiring a plurality of metering values corresponding to each of a plurality of metering areas; A color information acquiring unit for acquiring a plurality of color information corresponding to each of the plurality of photometric areas; A determination unit for determining respective weighting coefficients of the plurality of photometric areas; An arithmetic unit for weighting the respective photometric values of the plurality of photometric regions according to the weighting coefficient determined by the determination unit, and then calculating a main light emission amount of the light emitting device; And a selection unit that selects, from the plurality of photometric areas, a reference area used when the weighting coefficient of each of the plurality of photometric areas is determined by the determination unit, wherein the selection unit includes the color information acquisition unit. The reference area is selected so as to preferentially select a light metering area different from a light metering area in which the color information acquired by < Desc / Clms Page number 12 >

Further features and aspects of the present invention will become apparent from the following detailed description of exemplary embodiments with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments, features and aspects of the invention and, together with the description, serve to explain the principles of the invention.
1 is a cross-sectional view of a camera, an interchangeable lens unit, and a flash unit according to an exemplary embodiment of the present invention.
2 is a diagram illustrating a configuration example of a focus detection sensor.
3A and 3B are diagrams showing an example of the configuration of the photometric sensor.
4 is a block diagram showing an electric circuit of a camera body, an interchangeable lens unit, and a flash unit.
5 is a flowchart showing various processes when performing flash photography.
6 is a flowchart showing arithmetic processing of the main light emission amount.
7A to 7D show a photometric area in which a photometric area including a main subject is selected.
8 is a table used to determine the threshold LXL0.
9 is a table used to determine the weighting coefficient W (i).
FIG. 10 is a diagram showing a discrimination reference parameter used to discriminate an area including a gold folding screen.

Hereinafter, various exemplary embodiments, features, and aspects of the present invention will be described in detail with reference to the drawings.

1 is a cross-sectional view of an imaging system having a camera as an imaging device, an interchangeable lens unit, and a flash unit as a light emitting device according to an exemplary embodiment of the present invention. 1 shows a so-called, single-lens reflex type camera which is interchangeable with a lens, but a lens integrated camera may also be used.

In addition, although the flash unit as the light emitting device is detachable from the camera main body in the following description, a flash unit (built-in flash unit) built in the camera main body may also be used.

The camera body 1 includes a shutter 10 that is a mechanical shutter, an optical low pass filter 11, and an imaging device 12. This imaging device is made of an area type charge storage photoelectric conversion device and includes, for example, a complementary metal oxide semiconductor (CMOS) sensor or a charge coupled device (CCD) sensor. Both the partially transmissive main mirror 13 and the first reflective mirror 14 bounce during shooting. The light reflected from the first reflection mirror 14 is the paraxial imaging surface 15, the second reflection mirror 16, and the infrared cut-off positioned at the position conjugated with the image pickup device surface by the first reflection mirror 14. The filter 17, the aperture 18 having two openings, and the secondary imaging lens 19 are led to the focus detection sensor 20.

The focus detection sensor 20 is made of, for example, an area type charge accumulation photoelectric conversion element such as CMOS or CCD. As shown in FIG. 2, the light receiving sensor unit each comprising a plurality of blocks is divided into a pair of area 20A and 20B corresponding to two openings of the diaphragm 18. According to the structure of the camera main body 1 from the 1st reflection mirror 14 to the focus detection sensor 20, a focus can be detected using a phase difference detection system in the arbitrary position in a photography screen.

A part of the light beam reflected by the main mirror 13 is guided to the eyepiece 23 via the focal glass 21 and the pentaprism 22 having light diffusing property. The remaining light beam is further guided to the photometric sensor 26 via the third reflection mirror 24 and the condenser lens 25. The photometric sensor 26 obtains luminance information of the subject.

The photometric sensor 26 is formed of an area type charge accumulation photoelectric conversion element such as a CMOS sensor or a CD sensor. As shown in Fig. 3A, the photometric sensor 26 outputs a signal for a corresponding subject for each area of the divided image pickup screen.

In the following description, the photometric value based on the signal output from the photometric sensor 26 is also called luminance information, and the information regarding the color based on the signal output from the photometric sensor 26 is also called color information.

In the present exemplary embodiment, the picked-up image is divided into 35 (7 x 5) areas, and these areas are called photometric areas PD1-CD35.

Each photometric area of the PD1 to PD35 is further divided into small light receiving pixels as shown in Fig. 3B. These light receiving pixels are attached with color filters in a constant arrangement. In Fig. 3B, primary color filters (red (R), green (G) and blue (B)) are arranged in a stripe shape.

Furthermore, the camera body 1 is used to mount the mount portion 27 used to mount the lens unit, the contact portion 28 used to communicate with the mounted lens unit, and the flash unit 3. It has a connecting portion 29.

The interchangeable lens unit 2 includes an optical lens 30a to 30e constituting the photographing lens, an aperture 31, a contact portion 32 for performing information communication with the camera body 1, and the interchangeable lens unit ( 2) is provided with the mount part 33 attached to the camera main body 1. As shown in FIG.

The flash unit 3 monitors a light emitting portion 34 having a xenon tube as a light source, a light reflector 35, a Fresnel lens 36 for condensing a light beam, and an amount of light emitted from the light emitting portion 34. A sensor 37 and a mount portion 38 used to mount the flash unit 3 on the camera body 1 are provided.

4 is a block diagram showing an example of the electric circuits of the camera body 1, the interchangeable lens unit 2, and the flash unit 3 according to the present embodiment.

The camera main body 1 is equipped with the control part 41 which performs the general control of the camera main body 1. As shown in FIG. The control unit 41 is a single-chip microcomputer consisting of an arithmetic logic unit (ALL), a read-only memory (ROM), a random access memory (RAM), an analog-to-digital (A / D) converter, a timer, and a serial communication port (SPI). It's a computer. The control flow of the control unit 41 will be described later.

The output signals of the focus detection sensor (autofocus sensor) 20 and the photometry sensor (AE sensor) 26 are input to the A / D converter input terminal of the control unit 41. The timing generator 42 generates a timing signal that is used when accumulating a signal in the photometric sensor 26 or reading a signal from the sensor.

The signal processing circuit 43 performs A / D conversion on the image pickup signal output from the image pickup device 12 in accordance with an instruction from the control section 41. Thus, an image signal is obtained. Before storing the obtained image signal, the image signal is subjected to image processing such as compression.

The memory 44 is, for example, DDR, and is used as a work memory when the signal processing circuit 43 performs various types of signal processing. The memory 44 is also used as a video RAM (BRAM) used when displaying an image on the display unit 45 to be described later.

The display part 45 is comprised from the liquid crystal panel, and displays various shooting information and a picked-up image according to the instruction | indication of the control part 41. FIG. The storage unit 46, such as a flash memory and an optical disk, receives the captured image signal from the signal processing circuit 43 and stores it.

The first motor driver 47 drives the first motor 48 based on the control signal output from the controller 41. The first motor 48 moves the main mirror 13 and the first reflection mirror 14 up and down. The first motor 48 also serves as a shutter charge motor of the shutter 10.

The release switch 49 is a switch used to start shooting. The input / output terminal of the serial communication port of the control unit 41 is connected to the contact unit 28. The contact portion 28 is connected to the interchangeable lens unit 2 so that communication is possible. The input / output terminal from the serial communication port of the control unit 41 is connected to the connection unit 29. The connection part 29 is connected to the flash unit 3 so that communication is possible. The shutter driver 50 is connected to the output terminal of the controller 41 to drive the shutter 10.

The interchangeable lens unit 2 includes a lens control unit 51 that performs overall control of the interchangeable lens unit 2. The lens control unit 51 is a single-chip microcomputer provided with an AL, ROM, RAM, timer, and SPI.

The second motor driver 52 drives the second motor 53 to perform focus adjustment based on the control signal output from the lens control unit 51. Similarly, the third motor driver 54 drives the third motor 55 to control the aperture 31 based on the signal output from the lens control unit 51.

The distance encoder 56 is used to obtain an extended amount of focusing lens. In other words, the distance encoder 56 is used to obtain information about the object distance. The distance encoder 56 is connected to the input terminal of the lens control unit 51. When the interchangeable lens unit 2 is a zoom lens, the zoom encoder 57 is connected to an input terminal of the lens control unit 51 to obtain focal length information.

The contact part 32 is connected to the camera main body 1 so that communication is possible. The input / output terminal of the serial communication port of the lens control unit 51 is connected to the connection unit 29. When the interchangeable lens unit 2 is mounted on the camera body 1, the contact portion 28 and the contact portion 32 are connected, so that the control portion 41 and the lens control portion 51 can communicate with each other.

Lens-specific optical information required when the control unit 41 performs focus detection and exposure calculation is transmitted from the lens control unit 51 to the control unit 41 through data communication. In addition, the object distance information and the focal length information acquired by the distance encoder 56 and the zoom encoder 57 are also transmitted from the lens control unit 51 to the control unit 41 through data communication.

In addition, when the control unit 41 performs focus detection and exposure calculation, the focus control information and the aperture information acquired by the control unit 41 are transmitted from the control unit 41 to the lens control unit 51 via data communication. The lens control unit 51 controls the second motor driver 52 in accordance with the focus adjustment information, and controls the third motor driver 54 in accordance with the aperture information. Such information is obtained from the control unit 41 via data communication.

The flash unit 3 is provided with the flash control part 61 which performs the whole control of the flash unit 3. The flash control unit 61 is a single chip microcomputer provided with an AL, ROM, RAM, A / D converter, timer, and SPI. The boosting unit 62 generates a high voltage of about 300V necessary for light emission of the light emitting unit 34, and charging is performed at the generated high voltage.

When the flash unit 3 is attached to the camera main body 1, the connection part 29 and the connection part 38 are connected. The control unit 41 and the flash control unit 61 can communicate with each other. The flash controller 61 controls the booster 62 in accordance with the information obtained from the controller 41 to start / stop the light emission of the light emitter 34. In addition, the flash control unit 61 transmits information on the amount of light emitted by the monitor sensor 37 to the control unit 41. In addition, the light emission color information of the light emitting section 34 is also transmitted from the flash control section 61 to the control section 41.

Next, the process of flash photography is explained with reference to the flowchart of FIG. When the power switch (not shown) is turned on, the flowchart shown in FIG. 5 is started, and in step S101, the control unit 41 communicates with the lens control unit 51 to exchange the lens unit required for focusing and metering processing. Acquire various information of (2).

In step S102, the control unit 41 instructs the flash control unit 61 to operate the boosting unit 62 to obtain a sufficiently large charging voltage. The control unit 41 also communicates with the flash control unit 61 to obtain light emission color information of the flash unit 3.

In step S103, the control unit 41 outputs a control signal to the focus detection sensor 20 so that the focus detection sensor 20 accumulates the signal. When the accumulation ends, the controller 41 A / D converts the signals accumulated in the focus detection sensor 20 while reading out the signals accumulated from the focus detection sensor 20. Further, the control unit 41 performs various correction processing such as shading correction on the read digital data.

In step S104, the control unit 41 calculates the focus state of the focus detection area on the photographing screen based on the various information of the interchangeable lens unit 2 and the digital data obtained from the focus detection sensor 20 acquired in step S101. do.

Next, the controller 41 determines a focus detection area to be focused among the focus detection areas. This focus detection area can be determined by the photographer designating an arbitrary area using the operation member. Alternatively, the focus detection area may be determined by the controller 41 based on a predetermined algorithm.

Then, the control unit 41 calculates the amount of movement necessary when adjusting the focus state to the focus state according to the determined focus state of the focus detection area, and outputs information on the calculated amount of movement of the lens to the lens control unit 51. . According to the information about the lens shift amount, the lens control unit 51 outputs a control signal to the second motor driver 52 to drive the second motor 53 to move the focus adjusting lens according to the control signal. .

By the focus adjustment operation, the subject included in the determined focus detection area is in a confocal state. Since the information output from the distance encoder 56 changes in accordance with the drive of the focusing lens, various information of the interchangeable lens unit 2 is also updated.

In step S105, the control unit 41 controls the timing generator 42 to perform accumulation control and signal readout control of the signals accumulated in the photometric sensor 26. In this operation, the photometric sensor 26 accumulates signals at a predetermined length of time. Then, the control unit 41 sequentially reads the accumulation signals of the plurality of pixels, performs A / D conversion, and stores them in the RAM.

The accumulated signal information of the photometric sensor 26 stored in the RAM is added for each color of R, G, and B for each of the photometric regions PD1 to PD35. Accordingly, R (i), G (i) and B (i) are calculated. Further, a matrix operation is performed using predetermined coefficients M11 to M33 for R (i), G (i) and B (i). Thereby, the subject luminance value r (i), the subject color information Cv (i), and Cxy (i) in the linear system for each photometric area are calculated.

(1)

(One)

i = 1? 35

The subject luminance value r (i) in the linear system for each metering area is further converted into a logarithmic compression system with a base of 2 and correction processing S of luminance information for each screen area based on optical characteristics such as lens information. Do it. The subject luminance information of the logarithmic compression system is referred to as subject luminance value B '(i).

B '(i) = ｌｏｇ ₂ {Ｂｒ (i)} × S (i)

i = 1? 35

In step S106, the control unit 41 communicates with the flash control unit 61, and determines whether or not the charging voltage is sufficient to emit light. If the charging voltage is not sufficient to emit light, charging is continued until the charging voltage is sufficient.

In step S107, the control unit 41 calculates luminance information of the entire photographing screen according to the weighting operation. According to this weighting operation, the object luminance value B '(i) for each photometric area obtained in step S105 is weighted. Then, the accumulation time (shutter speed), aperture value, and imaging sensitivity of the imaging device 12 are determined on the basis of the luminance information of the entire photographed screen and the predetermined program diagram calculated in this way. These values are displayed on the display unit 45.

If any one of the shutter speed, aperture value, and shooting sensitivity has been predefined and preset by the photographer, the remaining parameters may be set to the above values that can be combined with the preset values to achieve an optimal exposure. Decide In the following description, the exposure value determined based on the determined Apex value of the shutter speed and aperture value is referred to as EBT. The exposure value EBT is obtained from the following relational expression.

ＥＶＴ = Ｔｖ + Ａｖ

Here, TV is a peak value of a shutter speed, and AB is a peak value of an aperture value.

In step S108, the control unit 41 determines whether the release switch is "ON". If the release switch is "on" (YES in step S108), the processing proceeds to step S109. If the release switch is " off " (NO in step S108), the process returns to step S101.

In step S109, the control unit 41 controls the timing generator 42 to control the timing generator 42 so as to perform photometry by the flash unit 3 without using the flash before preliminary light emission. Accumulation control and read control are performed.

According to this control, the photometric sensor 26 accumulates electric charges for a predetermined length of time. Thereafter, the control unit 41 sequentially reads the accumulated signals of the plurality of pixels, performs A / D conversion, and stores them in the RAM. The signal information of the photometric sensor 26 stored in the RAM is added for each color of R, G, and B for each of the photometric regions PD1 to PD35. Accordingly, R '(i), Ｇｐ (i) and Ｂｐ (i) are calculated.

In addition, matrix operations are performed on R '(i), V (i), and V (i) using predetermined coefficients M11 to M33. Thereby, the subject luminance value Pr (i), the subject color information Cx (i), and Cxy (i) immediately before the preliminary light emission in the linear system for each photometric area are calculated.

(2)

(2)

i = 1? 35

The luminance value Pr (i) of the subject immediately before the preliminary light emission in the linear system for each metering area is further converted into a logarithmic compression system with a bottom 2, and luminance information for each screen area based on optical characteristics such as lens information. Correction processing S is performed. The subject luminance information in the logarithmic compression system is called the subject luminance value P (i) immediately before the preliminary light emission.

P (i) = ｌｏｇ ₂ {Ｐｒ (i)} × S (i)

i = 1? 35

In step S110, the control unit 41 instructs the flash control unit 61 to communicate with the flash control unit 61 and to preliminarily emit light before the main light emission. Thereafter, the flash control unit 61 controls the light emitting unit 34 to emit a predetermined light emission amount determined for the preliminary light emission based on the signal output from the monitor sensor 37.

In order to obtain the photometric information of the subject during the preliminary light emission, the control unit 41 controls the timing generator 42 to perform predetermined accumulation control and signal readout control of the signals accumulated in the photometric sensor 26. Do it.

In accordance with this operation, signals are accumulated in the photometric sensor 26 for a predetermined period, and the control unit 41 sequentially reads the accumulated signals of the plurality of pixels, performs A / D conversion, and stores the converted signals in the RAM. do. The signal information of the photometric sensor 26 stored in the RAM is added for each color of R, G, and B for each of the photometric regions PD1-35. In this way, R (i), Ｇｈ (i) and Ｂｈ (i) are obtained.

In addition, matrix operations are performed for R ary (i), Ｇｈ (i) and Ｂｈ (i) using predetermined coefficients M11 to M33. As a result, the subject luminance information Hr (i), the subject color information Cyl @ (i), and Cylxy (i) at the time of linear preliminary light emission are calculated for each photometric area.

(3)

(3)

i = 1? 35

The subject luminance information Hr (i) at the time of preliminary light emission in the linear system for each light metering area is further converted into a logarithmic compression system with a base of 2 and luminance information for each screen area based on optical characteristics such as lens information. Correction processing S is performed. Subject luminance information in a logarithmic compression system is referred to as subject luminance value H (i) at preliminary emission.

H (i) = ｌｏｇ ₂ {Hr (i)} × S (i)

i = 1? 35

In step S111, the control unit 41 calculates the light emission amount (hereinafter referred to as the main light emission amount) at the time of photographing. This operation will be described below with reference to FIG. 6.

In step S112, the control unit 41 outputs a control signal to the first motor driver 47 to drive the first motor 48, so that the main mirror 13 and the first reflection mirror 14 bounce off. Rises. Furthermore, the control part 41 outputs the aperture information regarding the aperture value determined in step S107 to the lens control part 51.

In accordance with this aperture information, the lens control unit 51 outputs a control signal to the third motor driver 54 so that the third motor 55 drives the aperture 31. Accordingly, the aperture size of the diaphragm 31 is changed to the size corresponding to the diaphragm value determined in step S107.

In step S113, the controller 41 outputs a control signal to the shutter driver 50 to open the shutter 10. Thereafter, light is incident on the imaging device 12 through the photographing lens, so that imaging can be performed. Then, the control unit 41 instructs the signal processing circuit 43 to accumulate the signals in the imaging device 12 according to the accumulation time and the imaging sensitivity determined in step S107.

The control unit 41 also instructs the flash control unit 61 to emit light when the imaging element 12 performs imaging. The flash control part 61 controls the light emission part 34 based on the output signal of the said monitor sensor 37 so that according to the instruction by the said control part 41, the light emission amount same as the main light emission amount acquired by step S111 is emitted. do. In this way, imaging is performed using light emission of the flash unit 3.

When the imaging is finished, the controller 41 outputs a control signal to the shutter driver 50. In response to this signal, the shutter 10 is closed and light incident on the image pickup device 12 through the photographing lens is blocked.

In step S114, the control unit 41 instructs the lens control unit 51 to open the diaphragm 31. According to this instruction, the lens control unit 51 outputs a control signal to the third motor driver 54 such that the third motor 55 drives the aperture 31. As a result, the aperture 31 of the photographing lens is opened. Furthermore, the control part 41 outputs a control signal to the 1st motor driver 47, and drives the 1st motor 48. FIG. Accordingly, the main mirror 13 and the first reflection mirror 14 are brought down.

In step S115, the control unit 41 instructs the signal processing circuit 43 to perform A / D conversion of the image pickup signal output from the image pickup device 12. The converted signal is further subjected to correction processing and interpolation processing.

In step S116, the control unit 41 instructs the signal processing circuit 43 to perform white balance adjustment on the image signal subjected to the correction process and interpolation process.

In step S117, the control unit 41 instructs the signal processing circuit 43 to compress the image signal subjected to the white balance adjustment and convert it into a recording file format. The acquired signal is stored in the storage unit 46.

Thereafter, various processes for performing flash photography are finished.

Next, the calculation processing of the main light emission amount in step S111 will be described with reference to the flowchart of FIG. 6.

In step S151, the control unit 41 reflects the preliminary light emitted from the flash unit 3 using the subject luminance value P (i) immediately before the preliminary light emission and the subject luminance value H (i) at the time of preliminary light emission for each photometric area. Only the luminance value D (i) is calculated. Since the subject luminance value P (i) immediately before the preliminary light emission and the subject luminance value H (i) at the time of preliminary light emission are values in the compression system, the values are raised and expanded. The difference is then computed and the resulting value is computed logarithmically as follows:

D (i) = ｌｏｇ ₂ (2H (i) -2P (i))

i = 1? 35

In addition, the flash unit 3 at the time of preliminary light emission is performed by using the subject color information Cx (i) and Cxy (i) immediately before the preliminary light emission for each photometric area, and the subject color information Ccylin (i) and Cylxy (i) at the time of preliminary light emission. The subject color information EV (i) and Exy (i) of only the reflected light output from the image are calculated.

Ｅｘ (i) = Ｃｈｘ (i) -Ｃｐｘ (i)

エ ｙ (i) = Ｃｈｙ (i) -Ｃｐｙ (i)

i = 1? 35

In step S152, the controller 41 calculates the luminance ratio R (i) using the subject luminance value P (i) immediately before the preliminary light emission and the subject luminance value H (i) at the preliminary light emission for each photometric area.

R (i) = H (i) -P (i)

Since the subject luminance value P (i) immediately before the preliminary light emission and the subject luminance value H (i) at the time of preliminary light emission are values in a logarithmic compression system, obtaining a difference between these values is equivalent to obtaining a ratio of the luminance values.

By obtaining the ratio of the luminance values, the photometric regions (obtained by dividing the image pickup screen into 35 regions) having the same ratio of luminance values can be considered to be located at the same distance from the subject.

In step S153, the control unit 41 calculates the threshold LL0 and LL1 based on the information of the distance encoder 56 obtained from the lens control unit 51, in other words, the object distance information D (hereinafter referred to as distance information D). do.

The threshold LXL0 is based on the distance information D obtained from the lens control unit 51 and the information C2 on the amount of light emitted at the time of preliminary light emission, and only the reflected light of the preliminary light emission when the subject having the standard reflectance is positioned at the distance indicated by the distance information D. It is calculated in consideration of the luminance value.

The threshold LXL0 is determined to be slightly higher than the luminance value of only the reflected light of the preliminary light when the subject having the standard reflectance is located at the distance indicated by the distance information D. The reason why the threshold LkL0 is set slightly higher is that the threshold requires taking into account some margin of error of the distance information D. By raising the threshold LkL0 to a level corresponding to this margin, the luminance value of only the reflected light of the preliminary light emission when the subject of the standard reflectance actually exists is prevented from being higher than LkL0.

ＬＶＬ0 = -ｌｏｇ ₂ (D) × 2 + C2

The threshold LXL1 is determined by subtracting C3 from the threshold LXL0. C3 is determined in consideration of the error of the distance information D possible. In this way, the luminance value of only the reflected light of the preliminary light emission when the subject of the standard reflectance actually exists prevents the threshold LBL1 from being lowered.

ＬＶＬ1 = ＬＶＬ0-C3

As described above, when the luminance value of only the reflected light of the subject at the time of preliminary light emission is between the threshold LWL0 and LL1, the determination operation of the main emission amount is performed.

In the case of a single-lens reflex type camera having an interchangeable lens, it is not necessary to include a distance encoder depending on the attached lens. In this case, distance information D is not obtained. If the distance information D is not obtained, the threshold LXL0 and LXL1 are determined as described below.

If the mounted interchangeable lens unit does not include the distance encoder, the threshold LXL is determined according to Table 1 shown in FIG. 8 based on the focal length information of the photographing lens acquired in step S101.

ＬＶＬ0 = table 1 (f)

For example, if the focal length of the photographing lens is 28 mm, the luminance value of only the reflected light of the preliminary light when the subject of the standard reflectance is located at a distance of 0.5 m is set as the threshold LXL0. In general, when a photographing lens with such a focal length is used, it is very rare to photograph a subject at a distance closer than 0.5 m. Therefore, there is a high possibility that the luminance value of only the reflected light of the preliminary light emission becomes lower than the threshold LXL0.

Similarly, the remaining components of Pat1 of FIG. 8 are obtained.

If the focal length is a 50 mm photographing lens, the luminance value of only the reflected light of the preliminary light when the subject of the standard reflectance is located at a distance of 0.8 m is set as the threshold LXL0.

According to the present exemplary embodiment, the focal length of the photographing lens is given in a number of steps as shown in FIG. 8. The number and range of steps and the object distance assigned to each step are not limited to those shown in FIG.

The threshold LBL1 is determined by subtracting C1 from the threshold LLKL0. C1 is determined based on an empirical rule so that the luminance value of only the reflected light of the preliminary light emission is not lower than L1L1. For example, in the case of flash photography using a 50mm focal length lens, it is very rare to photograph a subject located farther than 6.4m. In this way, the reflected light from the subject with respect to the threshold LXL0 can be set within a range of six levels. Accordingly, C1 is set to six.

ＬＶＬ1 = ＬＶＬ0-C1

Here, both the threshold LLLO and LL1 are values in a logarithmic compression system.

In step S154, the control unit 41 sets the predetermined initial value to the coefficient K (i). The photometric area in which the reference area described below is selected is determined according to the coefficient K (i). In the following description, the photometric area is referred to as the target area. The coefficient K (i) is set to 0 or 1 for each of the 35 photometric areas as shown in Fig. 7A.

The initial value is 0 for the area where the main subject is unlikely to be present at the time of normal photography. In Fig. 7B, K (1)? Which is the margin area of the shooting screen? (8), K (14), K (15), K (22), K (23), K (28), K (29), and K (35) areas are set to 0, and other areas Is set to 1.

In step S155, the controller 41 compares the luminance value D (i) for each photometric area acquired in step S151 with the threshold values LL0 and LL1 determined in step S153. And the control part 41 sets the coefficient K (i) of the photometric area | region which becomes D (i)> LL0 or D (i) <LL1 to zero.

Thereby, for example, the coefficient K (i) of the metering area having a very high luminance value D (i) is set to zero due to the specular reflection from a subject having a mirror surface such as glass. Similarly, since the position of the reflector is so far that the light emitted from the flash unit 3 cannot reach the reflector, the coefficient K (i) of the photometric region having a very low luminance value D (i) is also set to zero. . The metering area set to the initial value in step S154 is set to 0 regardless of the luminance value D (i). Therefore, it is not necessary to compare the luminance value D (i) with the thresholds L'L0 and L'L1.

In step 156, the controller 41 emits light of the flash unit 3 acquired in step S102 a determination reference parameter (hereinafter referred to as a reference parameter) which is a specific condition used to determine the light metering area including the gold screen. Correction based on color information. The reference parameter is stored in the ROM in advance.

There are four reference parameters used to determine the metering area including the gold screen. 10 shows four parameters. The value of each parameter is set based on the color range of the reflected light when the light of the standard emission color is emitted from the light emitting device on the gold folding screen under the standard emission conditions.

Since the light emission color emitted from the light emitting device changes depending on the product model and the light emission conditions, the reference parameter is corrected according to a value suitable for the light emission color in the light emission color information acquired from the attached flash unit 3.

By correcting the parameter, even when the emission color is intentionally changed by changing the emission source or attaching the filter to the flash unit 3, when the emission color information of the new color is acquired, the area including the gold folding screen is determined. can do.

In the present exemplary embodiment, a method of correcting the reference parameter is described as an example of changing the reference parameter. However, when a plurality of reference parameters are stored in the ROM in advance, the method is used based on the emission color information of the flash unit 3. You may change the reference parameter.

In the following description, the reference parameters are denoted by EbMn, Ebm, Eymm, and Eymm. In addition, the correction parameter which is the data after correct | amending the reference parameter is shown by EBCmI, EBCmAv, ExyCmIn, and ExyCmAv.

Then, the correction parameter and the subject color information EV (i) and Exy (i) of only the reflected light of the preliminary light output from the flash unit 3 are compared for each of the photometric areas calculated in step S151. When the subject color information EV (i) and Exy (i) are within the range of the parameter after correction, the area is regarded as an area including the gold screen. In other words, even when there are gold screens in the light metering area, when the ratio of the light metering area including the gold screens is too small to satisfy the following conditions, the area is regarded as an area including the gold screens.

Ｅｘｃｍｉｎ≤Ｅｘ (i) ≤Ｅｘｃｍａｘ

エ ｙｃｍｉｎ≤Eｙ (i) ≤Eｙｃｍａｘ

In step S157, the control unit 41 determines whether or not a light metering area including a gold folding screen exists according to the comparison made in step S156. If there is a light metering area including a gold folding screen (YES in step S157), the processing proceeds to step S158. If there is no metering area including the gold folding screen (NO in step S157), the processing proceeds to step S159.

In step S158, the control unit 41 sets the coefficient K (i) of the metering area including the gold folding screen to zero. As for the photometric area where K (i) is set to 0 in step S154 or S155, the coefficient is set to 0 regardless of whether or not it includes a gold folding screen. Thus, there is no need to perform the comparison in step S156. Further, in the case where it is determined whether the light metering area includes the gold screen according to the comparison in step S156, and in the light metering area including the gold screen, K (i) is set to 0 in step S154 or step S155. If it is limited to the metering area, step S158 can be skipped.

Next, a description will be given of the case where photographing is performed with the photographing composition shown in Fig. 7C with respect to the determination of the coefficient K (i) in step S158.

In FIG. 7C, the gold folding screen 71 exists behind the main subjects 72 and 73. Therefore, the gold folding screen is contained in many areas of 35 metering areas. In this way, the subject color information EV (i) indicating that light is reflected from the gold screen from the CD1 to CD9, the CD11, the CD13 to the CD16, the CD18, the CD20 to the CD23, the CD27 and the CD28 which acquire the color information of the gold screen. Exy (i) is obtained. If the coefficient K (i) for each metering area is also changed to 0, the metering area will be as shown in Fig. 7D. As described above, the target area in which the reference area is selected is determined.

In step 159, the control unit 41 selects a photometric area having the maximum luminance ratio R (i) from the photometric areas where K (i) is 1, and sets it as a reference area. As described above, the light metering area having K (i) of 1 is a light metering area having a high possibility of the area including the main subject. Of these areas, the metering area where R (i) is maximum is the area that may most likely contain the main subject.

In step S160, the control unit 41 calculates the difference RR (i) between the luminance ratio R (i) and the reference value AAseR in each of the 35 photometric areas.

ＲＲ (i) = ｂａｓｅＲ-R (i)

Since both the luminance ratio R (i) and the reference value JasrR are values in a logarithmic compression system, the difference RR (i) is the ratio between the luminance ratio R (i) of the reference region and the luminance ratio R (i) of the other photometric region. to be. The light metering area having a smaller value of the difference RR (i) is a light metering area in which a subject exists at a distance approximately equal to that of the subject in the reference area.

The light metering area having a larger value of the difference RR (i) in the forward direction is a light metering area in which the subject exists at a distance substantially larger than the distance of the subject from the reference area. On the other hand, the light metering area in which the value of the difference RR (i) is negative in the negative direction is a light metering area in which the subject exists at a distance substantially closer than the distance of the subject in the reference area.

In step S161, the controller 41 determines the weighting factor W (i) based on the difference RR (i) determined for each of the 35 photometric areas. Specifically, the weighting coefficient W (i) is determined according to the difference RRR (i) of the photometric area shown in the region 2 in FIG.

W (i) = ｔａｂｌｅ2 (ＲＲ (i))

According to T2, the weighting coefficient W (i) increases as the difference RR (i) approaches 0, and the weighting coefficient W (i) decreases as the absolute value of the difference RRR (i) increases. In other words, the weight of the reference area is the largest. As described above, the light metering area in which the difference RR (i) is close to 0 is a light metering area in which a subject exists at a distance equal to that of the subject in the reference area. Accordingly, there is a high possibility that the metering area includes a subject equal to the subject of the reference area or a subject having the same importance as compared to the subject of the reference area.

On the other hand, the light metering area having a large absolute value of the difference RR (i) is a light metering area in which the subject exists at a distance that is significantly different from that of the subject in the reference area. Accordingly, it is unlikely that the photometric area is an area including a subject having the same importance as compared with the subject in the reference region. According to the above method, even if the photometric area is a photometric area in which the coefficient K (i) is set to 0 in steps S154? S158 and is excluded from the target area, when the difference RR (i) is close to zero, The weighting factor W (i) will be increased.

Therefore, almost the same main light emission amount is calculated for the case where the main subject position in the photographing screen is shifted for each photographing or when the same scene with a slightly different composition is photographed. Shooting with the same exposure can be obtained, and stable shooting results can be obtained.

The light reflected from the gold folding screen varies greatly depending on the angle with respect to the imaging device or the light emitting device. Accordingly, the luminance value D (i) of the reflected light of the light emission output from the flash unit 3 is greatly changed. Even when a certain area is discriminated as a metering area including a gold screen according to the subject color information, if the amount of reflected light of the light emitted from the flash unit is small, the value of the difference RR (i) is close to 0 and the weighting coefficient W (i) Even in a high case, a good image can be obtained.

In step S162, the control part 41 performs weighting calculation of the luminance value D (i) of each light metering area using the weighting factor # (i) determined in step S161.

AJ = Σ (D (i) × W (i)) / ΣW (i)

According to this weighting operation, the weighted average value ABE of the luminance value of only the reflected light of the preliminary light output from the flash unit 3 of the entire photographed screen is calculated.

In step S163, the control unit 41 calculates the main light emission amount information G from the exposure value EBT determined in step S107 and the weighted average value ABE calculated in step S161.

G = ＥＶＴ-ＡＶＥ

As can be seen from the above equation, the main emission amount information G represents a relative value of the emission amount with respect to the emission amount at the time of preliminary emission. In practice, it represents main light emission information. The calculated main light emission amount information G is transmitted from the control unit 41 to the flash control unit 61. In step S113, the main light emission of the flash unit 3 is performed in accordance with the information of the main light emission amount information G.

As described above, when the gold screen is included in the photographing screen, the light metering area including the gold screen is excluded from the target area for selecting the reference area when the main emission amount is calculated. By doing so, it is possible to calculate an appropriate light emission amount for the main subject to be photographed by the photographer. This makes it possible to obtain an appropriate image even when the gold screen is included in the shooting screen.

The present invention is not limited to the above exemplary embodiments, and various modifications and changes are possible as long as they are within the scope of the present invention.

For example, according to the exemplary embodiment described above, in step S156 of FIG. 6, the light metering area including the gold screen is determined according to the subject color information acquired at the time of preliminary light emission of the flash unit 3. This is because a light source that emits the strongest light to the gold screen can be identified by the light emission of the flash unit 3, and whether or not the gold screen is present can be more easily determined.

However, if the color of the subject can be detected without being influenced by the light source color, the subject color information acquired from light other than the preliminary light emission of the flash unit 3 can be used for the determination of the photometric area including the gold folding screen.

Further, according to the above exemplary embodiment, in step S156 of FIG. 6, the reference parameter used to determine the photometric area including the gold screen is corrected by the emission color information transmitted from the flash unit 3.

However, the subject color information EV (i) and Exy (i) of only the reflected light of the preliminary light output from the flash unit 3 can be corrected using the emission color information of the flash unit 3, and the result obtained is It can be compared with reference parameters Eｘｍｉｎ, Eｘｍａｘ, Eｙｍｉｎ, Eｙｍａｘ. Furthermore, the predetermined coefficients M11 to M33 used to calculate the subject color information EV (i) and Exy (i) of only the reflected light of the preliminary light output from the flash unit 3 can be corrected.

In the above-described exemplary embodiment, the metering area including the gold screen is excluded from the target area for selecting the reference area. However, the metering area including the other type of highly reflective subject may have the same characteristics as that of the gold screen. It may be excluded from the target area.

Further, in the above exemplary embodiment, although the gold screen is used as an example of the gold subject, a gold subject other than the gold screen may be used. The reference parameter of the above exemplary embodiment may be set based on the color range of the light reflected from the gold subject when emitting light to the gold subject.

In addition, since the photometric area other than the photometric area where the color information satisfies a specific condition can be preferentially selected, when the reference area is selected, the photometric area where the color information satisfies the specific condition is selected from a target area for selecting the reference area. Not necessarily excluded.

In addition, based on the color information, it is determined whether there is a photometric area that satisfies a specific condition, but the color information may be information in consideration of luminance. When the color information is information in consideration of luminance, the photometric area including the light reflection subject can be determined more accurately.

In the above exemplary embodiment, the photometric sensor 26 is used as a sensor for obtaining luminance information (photometric value) and a sensor for obtaining color information.

However, two sensors, i.e., sensors for acquiring luminance information and sensors for acquiring color information, can be used in place of the photometric sensor 26. In addition, when one sensor is used to acquire luminance information and color information, the imaging element 12 can be used in place of the photometric sensor 26 for acquiring luminance information and color information of the subject.

In addition, the flash control unit 61 of the flash unit 3 can execute a part of the processing relating to the calculation of the main light emission amount described in the above-described exemplary embodiment. The processing relating to the calculation of the main light emission amount is processing for determining weighting coefficients for the plurality of photometric areas, processing for selecting a reference region used when determining the weighting coefficient, and processing for calculating the main light emission amount.

In addition, the flash unit 3 may be provided with a sensor for acquiring luminance information and color information.

While the present invention has been described with reference to exemplary embodiments, it will be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all modifications, equivalent structures and functions.

Claims (20)

An imaging device that can shoot using a light emitting device,
A metering value acquiring unit for acquiring a plurality of metering values corresponding to each of the plurality of metering regions;
A color information acquiring unit for acquiring a plurality of color information corresponding to each of the plurality of photometric areas;
A determination unit for determining respective weighting coefficients of the plurality of photometric areas;
An arithmetic unit for weighting the respective photometric values of the plurality of photometric regions according to the weighting coefficient determined by the determination unit, and then calculating a main light emission amount of the light emitting device; And
And a selection unit that selects, from the plurality of photometric regions, a reference region used when determining the weighting coefficients of the plurality of photometric regions by the determination unit,
And the selection unit selects the reference region so as to preferentially select a photometric region different from the photometric region in which the color information acquired by the color information acquisition unit satisfies a specific condition.
The method of claim 1,
And the selection unit selects the reference area to preferentially select a light metering area other than a light metering area in which a highly reflective subject may exist based on color information acquired by the color information acquisition unit.
The method of claim 1,
And the color information acquired by the color information acquisition unit is information including luminance related information.
The method of claim 1,
The selection unit is configured to perform preliminary light emission of the light emitting device, and based on the color information acquired by the color information acquisition unit, the color information acquired by the color information acquisition unit is different from the photometric area that satisfies the specific condition. And the reference area is selected to preferentially select a photometric area.
The method of claim 4, wherein
And a changing unit for changing said specific condition based on light emission color information of preliminary light emission of said light emitting device.
The method of claim 1,
And the selection unit selects the reference region to preferentially select a photometric region different from the photometric region in which the color information acquired by the color information acquisition unit satisfies the gold color.
The method of claim 1,
And the determination unit maximizes the weighting coefficient of the reference region among the weighting coefficients of the plurality of photometric regions.
The method of claim 1,
The determination unit is configured such that the ratio of the photometric value acquired from the acquisition unit to preliminary light emission of the light emitting device without light emission of the light emitting device is closer to the ratio of the reference area. An imaging device which assigns a larger weighting factor to the photometric area.
The method of claim 1,
And the photometric value and the color information are acquired based on a signal output from the same sensor.
A metering value acquiring unit for acquiring a plurality of metering values respectively corresponding to the plurality of metering regions;
A color information acquiring unit for acquiring a plurality of color information corresponding to each of the plurality of photometric areas;
A determination unit for determining respective weighting coefficients of the plurality of photometric areas;
An arithmetic unit for weighting the respective photometric values of the plurality of photometric regions according to the weighting coefficient determined by the determination unit, and then calculating a main light emission amount of the light emitting device; And
And a selection unit that selects, from the plurality of photometric regions, a reference region used when determining the weighting coefficients of the plurality of photometric regions by the determination unit,
And the selection unit selects the reference region so as to preferentially select a photometric region different from the photometric region in which the color information acquired from the color information acquisition unit satisfies a specific condition.
An imaging system comprising an imaging device and a light emitting device,
A metering value acquiring unit for acquiring a plurality of metering values respectively corresponding to the plurality of metering regions;
A color information acquiring unit for acquiring a plurality of color information corresponding to each of the plurality of photometric areas;
A determining unit for determining weighting coefficients of each of the plurality of photometric areas;
An arithmetic unit that calculates a main light emission amount of the light emitting device after weighting the photometric values of each of the plurality of photometric areas according to the weighting coefficient determined by the determination unit; And
And a selection unit for selecting a reference region used when the weighting coefficient of each of the plurality of photometric regions is determined by the determination unit from the plurality of photometric regions,
And the selection unit selects the reference region so as to preferentially select a photometric region different from the photometric region in which the color information acquired from the color information acquisition unit satisfies a specific condition.
The method of claim 11,
And the selection unit selects the reference area to preferentially select a light metering area other than a light metering area in which a highly reflective subject may exist based on color information acquired by the color information acquisition unit.
The method of claim 11,
And the color information acquired by the color information acquisition unit is information including luminance related information.
The method of claim 11,
The selection unit is configured to perform preliminary light emission of the light emitting device, and based on the color information acquired by the color information acquisition unit, the color information acquired by the color information acquisition unit is different from the photometric area in which the specific condition is satisfied. And selecting the reference area to preferentially select a photometric area.
15. The method of claim 14,
And a change unit which changes said specific condition on the basis of light emission color information of preliminary light emission of said light emitting device.
The method of claim 11,
And the selection unit selects the reference region to preferentially select a photometric region different from the photometric region in which the color information acquired by the color information acquisition unit satisfies the gold color.
The method of claim 11,
And the determination unit maximizes the weighting coefficient of the reference region among the weighting coefficients of the plurality of photometric regions.
The method of claim 11,
The determination unit is configured such that the ratio of the photometric value acquired from the acquisition unit to preliminary light emission of the light emitting device without light emission of the light emitting device is closer to the ratio of the reference area. An imaging system, which assigns a larger weighting factor to the photometric area.
The method of claim 11,
And the photometric value and the color information are acquired based on a signal output from the same sensor.
As a control method of the light emission amount of a light emitting device,
Obtaining a plurality of metering values respectively corresponding to the plurality of metering areas;
Acquiring a plurality of color information corresponding to each of the plurality of photometric areas;
Determining weighting factors of each of the plurality of photometric areas;
Calculating a main emission amount of the light emitting device after weighting each of the photometric values of the plurality of photometric areas according to the determined weighting coefficient; And
Selecting from the plurality of light metering areas a reference area used for determining respective weighting coefficients of the plurality of light metering areas,
And the reference region is selected so as to preferentially select a photometric region different from the photometric region in which the acquired color information satisfies a specific condition.

Images