JP2020187360A - Imaging device - Google Patents

Abstract

To provide an imaging device that can perform appropriate exposure control.SOLUTION: An imaging device comprises a photometry unit for separating a field into a plurality of regions and determining a photometric value of light incident on each of the separated regions, and an exposure control unit for determining exposure based on the photometric value in a photometric region including a region with the maximum output of the separated regions. The exposure control unit changes the size of the photometric region including the separated regions according to an imaging mode being selected.SELECTED DRAWING: Figure 2

Description

The present invention relates to an imaging device.

A technique for determining exposure by referring to the brightness of an AF (autofocus) area is known (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2000-75352

An object of the present invention is to provide an image pickup apparatus capable of appropriate exposure control.

The present invention solves the above problems by the following solutions.

In one embodiment of the present invention, a photometric unit that divides the field of view into a plurality of regions and obtains a photometric value of the light incident on each of the divided regions, and a photometric region including the maximum output region of the divided regions. The exposure control unit includes an exposure control unit that determines the exposure based on the photometric value of the above, and the exposure control unit changes the size of the photometric region including the divided region according to the selected shooting mode. Is.

According to the present invention, it is possible to provide an image pickup apparatus capable of appropriate exposure control.

It is the schematic of the camera of embodiment. It is a functional block diagram of the camera of embodiment. It is a flow chart which showed the control until the camera provided with the image pickup apparatus of 1st Embodiment performs a shooting operation after the power is turned on, and is turned off. This is an example of dividing the pixels of the second imaging unit. It is the figure which showed the scene which the person other than the person of a main subject is dark, and the highlight part is a person's face. It is a figure which showed the exposure calculation area at the time of a through image and a moving image. It is a figure which showed the exposure calculation area in the case of a still image. It is a figure which showed the field area divided by the 2nd imaging unit in 2nd Embodiment. It is a figure which showed the state which divided the light receiving element into 5 regions. It is a figure which showed the relationship between the maximum value BVMax of a 5-divided luminance value, and the provisional correction amount KBLHo. It is a figure which shows the change of KHLTHo. It is a flowchart of 3rd Embodiment. It is a figure explaining the relationship of a guide number. It is a figure which showed the warning in the finder when the amount of light emission becomes larger than the target guide number. It is a figure which showed the warning in the rear liquid crystal when the amount of light emission becomes larger than the target guide number. It is a flowchart which shows the sensitivity value change. It is a figure explaining the 3rd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings and the like. FIG. 1 is a schematic view of the camera 1 of the embodiment. FIG. 2 is a functional block diagram of the camera 1 of the embodiment.

The camera 1 includes a camera body 2 and a lens barrel 3 that can be attached to and detached from the camera body 2, and can shoot still images and moving images. Still image shooting is started by pressing the release switch 101. Movie shooting is started by pressing the movie switch 102.

When the release switch 101 is pressed, the quick return mirror 103 and the sub mirror 104 are retracted out of the shooting optical path, the shutter 105 is released, and the aperture 118 is narrowed down.
After passing through the photographing lens 109, the luminous flux from the subject passes through the opening of the aperture 118, and is imaged as a subject image on the first imaging unit 106.
The first imaging unit 106 is a CCD or CMOS image sensor in which a plurality of pixels (charge storage type photoelectric conversion elements) are arranged two-dimensionally, and the subject image acquired by the first imaging unit 106 is a display device 121. Is displayed in.

When the release switch 101 is not pressed, a through image (live view image) is displayed on the display device 121. When the moving image switch 102 is pressed, the camera 1 starts recording a moving image.

In the present embodiment, the focus detection is performed by the pupil division phase difference method.
In the split phase difference method, as shown by the broken line in FIG. 1, the luminous flux that has passed through the half mirror portion of the quick return mirror 103 is reflected by the sub mirror 104 before shooting, and the luminous flux is divided into two in the focus detection optical system 107. , These light fluxes are formed on the focus detection unit (focus detection unit) 108 to detect the phase difference. When there is no phase difference, it is in focus.

The focus detection unit 108 outputs a focus detection signal according to the image received by the CCD line sensor. The focus detection method is not limited to this, and a method of detecting contrast in the first imaging unit 106 may be used.

The focus detection unit 108 detects the focus state for five regions of the field of view. The information is processed by the camera control unit 201, becomes a lens drive amount, and is output to the lens drive unit 210, and the lens drive unit 210 drives the photographing lens 109 in the lens body to the in-focus state.

The lens barrel 3 is provided with a distance encoder 212 that outputs a signal corresponding to the rotation angle of the distance ring corresponding to the amount of extension of the lens.
The signal from the distance encoder 212 is processed by the lens control unit 203 to obtain distance information. This distance information is communicated to the camera control unit 201. In the camera control unit 201, various calculations and controls are performed.

Further, before shooting, the light flux is reflected by the quick return mirror 103 on the finder optical system. The reflected light flux is imaged on the diffusion screen 110. This image passes through the condenser lens 111, the pentaprism 112, and the eyepiece lens 113, and is observed by the photographer 114.

Further, a part of the luminous flux diffused by the diffusion screen 110 passes through the condenser lens 111, the pentaprism 112, the photometric prism 115, and the photometric lens 116, and is reimaged on the second imaging unit 117 (photometric unit). To. A light receiving element such as an SPD (silicon photodiode) is used for the second imaging unit 117.

The second imaging unit 117 is a color image sensor provided with a color filter having an RGB pixel array (for example, a color filter having a Bayer array).
The second imaging unit 117 divides the field of view and measures the light. This photometric image is output to the camera control unit 201. Based on this image, the camera control unit 201 performs known scene recognition (for example, face detection), performs automatic exposure based on the known scene recognition, and determines the exposure.

The metering mode selection unit 216 selects the metering mode by the user. The user can select a desired metering mode by operating the metering mode selection unit. However, in the camera control unit 201, a plurality of photometric methods are sequentially executed.

The metering modes that can be selected by the user include, for example, multi-pattern metering and highlight-weighted metering.
Multi-pattern metering is a mode in which metering is performed for each of a plurality of areas set on the screen, and the final exposure is determined based on information such as the brightness distribution, color, distance, and composition of the subject.
Highlight-weighted metering is a mode in which the exposure is mainly determined so that the highlight portion on the screen has an appropriate brightness.
In general, if the exposure is controlled so that the highlight portion in the screen has an appropriate brightness, the exposure of the highlight-weighted metering method is darker than that of the multi-pattern metering.

The control in the camera 1 is performed by the camera control unit 201. This control is roughly classified into photometry, autofocus, and light emitting device control.
The camera control unit 201 includes the output from the second image pickup unit 117, the open F value of the lens barrel 3 stored in the lens control unit 203 provided in the lens barrel 3, the focal length, the ejection pupil position, and the like. A brightness value related to constant light exposure is calculated based on lens information, sensitivity information of the first imaging unit 106 from a sensitivity setting unit (not shown), and the like.

It is converted into an aperture value and a shutter value, and output to the aperture control unit 204 and the shutter 105. The aperture control unit 204 controls the aperture / return of the aperture 118 in response to the release signal from the release switch 101.

When the light emitting device 119 is used, the set gain of the second imaging unit 117 is calculated and the gain is set based on the photometric value, the aperture value, the sensitivity value, the distance value, and the like.
After that, the camera control unit 201 preliminarily emits light from the light emitting device 119 through the lighting control unit 207 in the main body of the light emitting device 119, and the second imaging unit 117 receives a photocurrent corresponding to the amount of reflected light of the subject.
The camera control unit 201 calculates the main light emission amount instruction value using the received light amount, and outputs the main light emission instruction value to the illumination control unit 207 again.

(First Embodiment)
Next, the camera 1 of the first embodiment of the present invention will be described.
FIG. 3 is a flow chart showing control of the camera 1 of the first embodiment from turning on the power to performing a shooting operation and turning off the power.

First, after the camera 1 is activated, in S201, the camera control unit 201 causes the second imaging unit 117 to accumulate images.
In the initial accumulation when the camera is started, AV (APEX value of the aperture value of the shooting lens), TV (APEX value at the shutter second), and SV (APEX value of the sensitivity) used for exposure control are fixed values, for example, AV = 5. , TV = 6, SV = 5.
Next, the camera control unit 201 receives the output of the second imaging unit 117 accumulated in S201 as an image.

Next, in S202, the camera control unit 201 calculates an evaluation value for use in the photometric calculation from the image acquired in S201.
In the present embodiment, as shown in FIG. 4, the pixels of the second imaging unit 117 are divided into 10 horizontal × 10 vertical.
The camera control unit 201 obtains a total of 100 evaluation values for each divided region, that is, 10 horizontal × 10 vertical. The evaluation value of each region is the sum of the Y outputs of the pixels of the second imaging unit 117 within the range of the divided region.
YC [i] [j] = ΣΣY [X] [Y] ... (Equation 1)

In Equation 1, YC [i] and [j] are output of evaluation values in each divided region of FIG.
Y [X] [Y] are Y output values at coordinates X and Y of the second imaging unit 117, and take values of 0 to 4095, for example. The range of two Σ is the coordinate range of all the pixels constituting one evaluation value.

For example, when the number of pixels of the second imaging unit 117 is 2400 horizontal × 1600 vertical, dividing into 10 blocks of horizontal i = 0 to 9 and 10 blocks of vertical j = 0 to 9 constitutes one evaluation value. The number of pixels is 240 horizontal × 160 vertical. If i is 0 and j is 0, the range of Σ is 0 to 239 for X and 0 to 159 for Y.

(Calculation of photometric values for through images and movies)
Next, in S203, the camera control unit 201 calculates the photometric value BVMov for the through image moving image based on the evaluation value output.
BVMov = Log2 (
(YC [HiLight_i-1] [HiLight_J-1] +
YC [HiLight_i] [HiLight_J-1] +
YC [HiLight_i + 1] [HiLight_J-1] +
YC [HiLight_i-1] [HiLight_J] +
YC [HiLight_i] [HiLight_J] +
YC [HiLight_i + 1] [HiLight_J] +
YC [HiLight_i-1] [HiLight_J + 1] +
YC [HiLight_i] [HiLight_J + 1] +
YC [HiLight_i + 1] [HiLight_J + 1]) / 9
) + BVCONST + AV ... (Equation 2)

In Equation 2, Log2 () is a function that returns the logarithm of the argument with the base being 2, and BVCONST is a value determined by the accumulation time and the imaging sensitivity. HiLight_i and HiLight_j are the X and Y coordinates of the region where the evaluation values YC [X] and [Y] are maximized.
When shooting a scene in which a person other than the main subject is dark and the highlight part is the face of a person as shown in FIG. 5, evaluation values as shown by shading in FIG. 6 are calculated, and HiLight_i and HiLight_j are calculated. The coordinates are the coordinates of the white evaluation value area.

In the calculation of Equation 2, as shown in the thick frame in FIG. 6, the photometric value for the through image moving image is calculated by using the region where the evaluation value is maximum and the evaluation value of one peripheral block.
AV is the aperture value (APEX value) of the photographing lens 109 when the power is turned on.

(Calculation of photometric value for still image control)
Next, in S204, the camera control unit 201 calculates the photometric value BVIMG for still image control based on the evaluation value output.
BVIMG =
Log2 (YC [HiLight_i] [HiLight_j])
+ BVCONSTIMG + AV ... (Equation 3)

In Equation 3, BVCONSTING is a value determined by the aperture, storage time, and imaging sensitivity at the time of acquiring the imaging output.
In Equation 3, the photometric value for still image shooting is calculated using the region where the evaluation value is maximum. This is a region as shown in FIG. 7, and the exposure is determined in a narrow region as compared with the photometric value for the through image moving image calculated by Equation 2. In this case, the exposure stability is inferior when the composition of the camera is changed or the subject is moved.

Next, in S205, the camera control unit 201 determines the accumulation time TV (APEX value) and the gain SV (APEX value) of the first imaging unit 106 based on the calculated photometric value for through image control.
TV = 6 ... (Equation 4)
SV = AV + TV-BVTh ... (Equation 5)

In S206, the camera control unit 201 creates an image from the output of the first imaging unit 106, and causes the display device 121 to display the image.

If the release switch 101 is not pressed in S207, the camera control unit 201 does not perform the still image shooting operations of S208 to S210, and proceeds to the processing of S211 and subsequent steps.
When the release switch 101 is pressed, the process proceeds to S208.

In S208, the camera control unit 201 has a storage time TV (APEX value) and a gain SV (APEX value) of the first imaging unit 106 for taking a still image based on the photometric value BVIMG for still image control determined in S204. To determine.
TV = 6 ... (Equation 6)
SV = AV + TV-BVIMG ... (Equation 7)

In S209, the camera control unit 201 accumulates the first imaging unit 106 based on the exposure conditions determined in S208.
In S210, the camera control unit 201 creates a still image based on the output of the first imaging unit 106 accumulated in S209.

In S211 the camera control unit 201 determines whether or not the moving image recording has been started. When the moving image switch 102 is pressed, the process proceeds to S212.
When the moving image switch 102 is not pressed, the camera control unit 201 proceeds to S218 without performing the moving image recording process.

When the moving image switch 102 is pressed, the camera control unit 201 calculates the exposure control value for moving image recording in S212.
TV = 6 ... (Equation 8)
SV = AV + TV-BVMOV ... (Equation 9)
Here, the exposure control value is determined using the photometric value for the through image moving image calculated in S203.

In S213, the camera control unit 201 accumulates the first imaging unit 106 based on the exposure control value for moving images determined in S212.
In S214, the camera control unit 201 performs processing for moving images at the output of the first imaging unit 106.
In S215, the camera control unit 201 records the processed moving image.

In S216, the camera control unit 201 updates the photometric value for moving images. Here, the same calculation as the metering calculation performed in S203 is performed again.

In S217, the camera control unit 201 determines whether or not the moving image recording is stopped by the operation of the moving image switch 102. If it is stopped, the process proceeds to S218, and if it is not stopped, the operations S212 to S216 are repeated.

In S218, the camera control unit 201 repeats the processes from S201 to S217 unless the power of the camera is turned off.

(effect)
In a camera that controls exposure based on the amount of light received by an element having a plurality of regions, there is known a technique of performing exposure control using the output value of the element that receives the maximum amount of light.
However, when the exposure is controlled based on the maximum amount of light of the photometric element, the photometric value calculated by a slight composition change fluctuates greatly depending on the size of the point light source in the field of view, such as when shooting a moving image. In, the rampage of exposure is noticeable.

In the present embodiment, even when the photometric calculation that emphasizes the highlight portion is used, in the case of through image display or movie shooting, the priority of the photometric region is changed and the range of the minimum photometric region for detecting the highlight portion is set. Make it wider. Therefore, it is possible to record a stable moving image in which flicker and variation are suppressed, and it is possible to perform highly accurate exposure control.

(Transformed form)
(1) In the above embodiment, a mode for widening the range of the minimum photometric region for detecting the highlight portion has been described in the case of through image display or moving image shooting.
However, the present invention is not limited to this. For example, when the continuous shooting mode is set, or when shooting an interval timer or when shooting a time-lapse moving image, a continuous image is obtained, so that the variation in exposure control becomes more noticeable as compared with the case where a single image is shot.
In this case as well, by applying this embodiment and widening the range of the minimum metering area for detecting the highlight portion, it is possible to record a stable moving image in which flicker and variation are suppressed, and highly accurate exposure control is performed. Is possible.

(2) For cameras that have a crop mode and can switch the shooting range, the larger the shooting range, the smaller the size of the photometric area, and stable moving images that suppress flicker and variation. Recording becomes possible, and highly accurate exposure control becomes possible.
In this case as well, by applying the present embodiment and widening the range of the minimum photometric region for detecting the highlight portion, it is possible to suppress the disturbance of the photometric value.

(3) When the focal length is on the telephoto side, blurring is more likely to occur than on the wide side. In this case, the variation in exposure control becomes noticeable. In this case as well, by applying this embodiment and widening the range of the minimum metering area for detecting the highlight portion, it is possible to record a stable moving image in which flicker and variation are suppressed, and highly accurate exposure control is performed. Is possible.

(4) In the above-described embodiment, the mode in which the surface value of the region is obtained by using the luminance Y output has been described. In this case, the brightness Y enables exposure without overexposure, but there are cases where color saturation occurs in each of RGB.
Therefore, the brightness of each of RGB may be obtained, and the exposure may be detected based on the maximum value among them.
In this case, the maximum RGB brightness in the pixels of the second imaging unit 117 is calculated, and among the respective RGB brightness values, the one having the highest surface value (luminance value) is automatically exposed to perform a through image. The photometric value BVMov for moving images and the photometric value BVIMG for controlling still images are calculated.

(5) In the case of (4), as shown in Table 1 below, when the RGB output is viewed for each time (t1 to t5), the values may vary.

That is, the maximum brightness of RGB at t1 is 100 of R, the maximum brightness of RGB at t2 is 200 of G, and the maximum brightness of RGB at t3 is 100 of R and t4. The maximum luminance of RGB is 200 of G, and the maximum luminance of RGB at t5 is 100 of R.
The exposure is determined based on this maximum brightness, but the difference in maximum brightness is 100, and the variation in exposure determined based on this is large.

On the other hand, the difference in brightness Y (0.3R + 0.6G + 0.1B) is 69, which is small with 100 travel, so that the variation in exposure is smaller than when the maximum value of RGB is used.

Therefore, although RGB is usually used, if the variation in the maximum value of RGB is large, it may be controlled to switch to Y.

(6) When multiple metering modes such as multi-pattern metering, spot metering, and center-weighted metering are provided in addition to highlight-weighted metering, the finished photo is darker in the other metering modes than in highlight-weighted metering. If this is the case, the exposure value may be selected based on the one with the lowest photometric value.

(7) When highlight-weighted metering is performed, the smoothing coefficient may be changed to slow down the response. As a result, it is possible to eliminate a sudden change in exposure on the screen and improve the appearance.

(Second Embodiment)
Next, the camera 1A of the second embodiment of the present invention will be described. Since the camera 1A of the second embodiment has the same structure as the camera 1 of the first embodiment shown in FIGS. 1 and 2, detailed description thereof will be omitted.
FIG. 8 shows 140 regions of the field of view 117a divided by the second imaging unit 117. The range of the field of view captured by the captured image and the photometric image is the same, but the resolution is different.

1. 1. Light emission calculation / highlight-weighted metering correction 1-1. Calculation of light emission amount before correction When the subject is in focus by the focus detection unit 108, the camera control unit 201 instructs the preliminary light emission of the light emitting device 119 through the illumination control unit 207 in the light emitting device 119 main body.
The light emitting device 119 performs preliminary light emission with a predetermined minute amount of light according to this.
The preliminary light emission illuminates the subject, passes through the lens barrel 3 and the quick return mirror 103, and forms a subject image on the diffusion screen 110.

The second imaging unit 117 receives the subject image of the diffusion screen 110 by the second imaging unit 117, and outputs the brightness value Voy for each light receiving element.
Voice is an A / D conversion of the output from the second imaging unit 117 and is represented by 256 gradations of 0 to 255.
The second imaging unit 117 has linear input / output characteristics of the amount of incident light and the output voltage. With exactly the same gain and the same accumulation time as when the preliminary emission metering was performed, the metering is performed in a state where the preliminary emission is not performed, and the constant light luminance value Voyback at this time is obtained.

The camera control unit 201 removes the influence of the constant light from these luminance values Voy by the equation (10) to obtain a constant light removal image.

Vow [i, j] = Voymon [i, j]-Voyback [i, j]… (Equation 10)

The camera control unit 201 stores the brightness value Voy for each light receiving element that has undergone this correction.
Next, as shown in FIG. 9, the brightness value Voy is divided into five regions. This 5-division area is defined as RM [k] (k: 0 to 4).
The following calculation is performed from RM [k] to calculate RMMain.

RMMain = 0.16 * (RM [1] + RM [2] + RM [3] + RM [4]) + 0.33 * RM [0]… (Equation 11)

The difference in the number of stages (unit: EV) between the main light emission guide number and the preliminary light emission guide number GNMon is called the light emission amount stage number difference.
Further, the difference in the number of light emission stages is referred to as KGNApex.
KGNApex is obtained by the formula (12).

KGNApex = -log ₂ RMMain-Av0 + Av + KGNCONST… (Equation 12)

KGNCONST in the formula (12) is a difference in the number of steps of the amount of light emission for the captured image to have an appropriate luminance value in the main light emission with respect to a standard reflectance subject such as a standard reflector having an 18% reflectance.
Further, Av0 is the open F value (Apex) of the photographing lens 109, and Av is the aperture F value (Apex value) at the time of photographing.

1-2. Daytime Synchro Luminance Correction Using the maximum value BVMax of the 5-division brightness value, which is the brightness value of each region in FIG. 9, the provisional correction amount KBLHo is determined by the following (1) to (5).
FIG. 10 shows the relationship between the maximum value BVMax of the 5-division luminance value and the provisional correction amount KBLHo.
(1) BVMax <BLHOBV
KBLHo = KBLHOLO
(2) BLHOBV ≤ BVMax <BLHOBV
KBLHo = KBLHOLO + (KBLHo_Max-KBLHOLO) / (BV_BLHo-BLHOBV) * (BVMax-BLHOBV)
(3) BV_BLHo <BVMax
KBLHo = KBLHo_Max

Further, at the time of highlight-weighted metering, the following calculation is performed to correct KBLHo.
The difference between the highlight area focused metering result BvHiw and the multi-pattern metering result BvAmp is evaluated. The present embodiment is not limited to the multi-pattern photometric result BvAmp, and the average value BVmean of the entire screen may be used.

dAmpHLT = BvHiw --BvAmp

Here, KHLTHo is changed as shown in FIG. 11 and the following according to the value of dAmpHLT.
(1) When dAmpHLT <0
KHLTHo = 1.0
(2) When 0 ≤ dAmpHLT ≤ DelBLHo
KHLTHo = -1.0 / DelBLHo * dAmpHLT + 1.0
(3) When DelBLHo <dAmpHLT
KHLTHo = 0

KBLHo is corrected using the KHLTHo obtained from the above.
KBLHo = KBLHo * KHLTHo

Using the calculated KBLHo, the exposure deviation is corrected by the following calculation.
The dDC used below is an exposure deviation, and dDC = (AE indicated value-AE control value). dDC = 0 is the proper exposure. dDC <0 represents under, and dDC> 0 represents over.
(1) When dDC is 0 or more
KGNApex = KGNApex + BLHosei * KBLHo

(2) When dDC is BLHosei or more and less than 0
KGNApex = KGNApex + (BLHosei-dDC) * KBLHo

(3) When dDC is less than BLHosei, KGNApex is the same value.

From the above result, the present emission amount GN Non can be obtained by the formula (13) using the KGNApex of the formula (12).

GNHon ＝ GNMon ・ √2 ^KGNApex … (Equation 13)

The quick return mirror 103 and the sub mirror 104 are retracted out of the shooting optical path, the shutter 105 is opened, and the aperture 118 is narrowed down.
After that, the light emitting amount GN Hon obtained by the above formula is instructed to the light emitting device 119 to start the main light emitting.
A subject image is formed on the first imaging unit 106 by the lens barrel 3, and the accumulation of the first imaging unit 106 starts.

The illumination control unit 207 stops the light emission when the target light emission amount GN Non is reached.
When the predetermined exposure period elapses, the camera control unit 201 closes the shutter 105 and lowers the quick return mirror 103.
After that, the camera control unit 201 reads out the digital image data from the first imaging unit 106.
The first imaging unit 106 has linear input / output characteristics of the incident light amount and the output voltage, and the image data read at this time is digital data after A / D conversion.

(Effect of this embodiment)
In the calculation of TTL dimming, when daytime synchronized photography is performed using highlight-weighted metering, the metering value is determined so that the gradation of high brightness (for example, an empty region) does not skip. At this time, the constant light component hardly contributes to the subject area.
For this reason, when an algorithm that corrects dimming under is used in daytime synchronized photography, the subject is often simply under.
In the present embodiment, at the time of highlight-weighted metering, the multi-pattern metering brightness BvAmp or average brightness BvMean is compared with the highlight-weighted metering brightness BvHiw, and the larger the difference, the smaller the dimming correction amount on the underside. Increases the amount of light emitted.
According to this embodiment, the combination of highlight-weighted metering and strobe photography can reduce failed photographs.

(Third Embodiment)
Next, the camera of the third embodiment of the present invention will be described.
Similar to the second embodiment, the third embodiment has the same basic structure of the cameras shown in FIGS. 1 and 2. Then, the field of view 117a is divided into 140 regions by the second imaging unit 117 shown in FIG.

The relationship between the maximum value BVMax of the 5-divided luminance value and the provisional correction amount KBLHo is shown.
In this embodiment, it is assumed that the user has selected highlight-weighted metering. Further, it is assumed that the strobe mounted on the camera is set to the TTL dimming mode. Further, the shutter speed, the F value, the sensitivity value, the photometric value, and the guide number converted into APEX are expressed as TV, AV, SV, BV, and GV, respectively.

First, the metering value by highlight-weighted metering in the steady state before release is HiwBV, the guide number is HiwGV, the metering value by multi-pattern metering is AmpBV, and the guide number is AmpGV.
In the following, the main emission guide number is predicted using the exposure AmpAV and AmpSV based on the multi-pattern metering result, the exposure HiwAV and HiwSV based on the highlight-weighted metering result, and the distance information Dist obtained by lens communication in a steady state.
If the predicted guide number is greater than the target guide number, change the exposure to optimize.
However, when changing the exposure, make sure that the exposure is not brighter than the exposure determined by multi-pattern metering.

In the release sequence after pressing the release switch 101, the sensitivity value is further optimized by changing the sensitivity value when it is larger than the target guide number based on the guide number calculated by the TTL dimming.
In the steady state before the release, the elements for changing the main light emission guide number differ depending on the exposure mode, but in the present embodiment, the S (shutter priority) mode will be described.

The flowchart of this embodiment is shown in FIG.
Steady state before release In the case of S mode, TV is fixed, AV is variable, and SV is fixed.
The target guide number at the time of flash emission is TarGV (step S121).
In the case of flash emission (TV is less than flash synchronization seconds)
TarGV = FullGV -1
And.
The guide number is calculated by multi-pattern metering (step S122) and highlight-weighted metering (step S123).

Determining whether the shutter speed TV is greater than the flash tuning seconds (step S124)
(1) In the case of FP light emission (TV is larger than the flash synchronization second) (step S124, NO)
TarGV = FullGV FP -1
(Step S125).
Furthermore, the prediction guide number before release is obtained from pAmpSV = pHiwSV.
pHiwGV = pHiwAV + 2log2 (Dist) + (5-pHiwSV) + offset
pAmpGV = pAmpAV + 2log2 (Dist) + (5-pHiwSV) + offset
And.

(1-1) In the case of pAmpGV <TarGV <pHiwGV (step S127)
The case of pAmpGV <TarGV <pHiwGV is shown in FIG. 13 (a) (step S129).
The amount of light emitted that needs to be changed to prevent full light emission is pHiwGV-TarGV, and this difference in amount of light is absorbed by opening the aperture (step S128).
In the following, the shutter speed for main shooting will be HonTV, the aperture value will be HonAV, and the sensitivity value will be HonSV.

HonTV = HiwTV
HonAV = HiwAV-(pHiwGV-TarGV)
HonSV = HiwSV

(1-2) Case of TarGV ≦ pAmpGV The case of TarGV ≦ pAmpGV is shown in FIG. 13 (b) (step S129).
In this case, if the aperture of HiwGV-TarGV is opened, the result will be brighter than the shooting result of multi-pattern metering. In this case, the guide number is changed up to AmpGV.

HonTV = HiwTV
HonAV = HiwAV-(pHiwGV-pAmpGV)
HonSV = HiwSV

At this point, if the amount of light emitted is greater than the target guide number, the user is warned before the release. In the finder (FIG. 14) or during live view, the rear liquid crystal is made to blink, for example, the lightning mark M at regular intervals as shown in FIG. 14 (FIG. 15).

In the case of ISO-AUTO (ISO variable) after release, if the main light emission guide number is larger than the target guide number using the main light emission guide number HonGV obtained as a result of performing TTL dimming during the release sequence. , Correct with the sensitivity value.

FIG. 16 is a flowchart showing this sensitivity value change. The difference from FIG. 12 is that steps S129 and S128 of FIG. 12 are steps S169 and S168.
First, it is determined whether or not the speed is lower than the synchronized seconds.
In the case of low speed, that is, in the case of TV ≤ TVX (in the case of flash emission), and in the case of HiwBV- (HonGV-TarGV)> AmpBV
HonSV = HonSV + (HonGV --TarGV)
And.
In addition, TVX is the tuning second time (Apex value).

In the case of high speed, that is, in the case of TV> TVX (in the case of FP emission) and in the case of HiwBV- (HonGV-TarGVFP)> AmpBV
HonSV = HonSV + (HonGV --TarGVFP)
And.

(Fourth Embodiment)
The fourth embodiment is a case where the steady state before the release is different from the above-mentioned third embodiment, which is shown in FIG.

Steady state before release The weighting combination calculation of the highlight-weighted photometric value HiwBV and the multi-pattern photometric value AmpBV is performed to determine the photometric value HonBV value used for exposure control for shooting. As shown in FIG. 17, the weighting amount k of the highlight-weighted metering is determined, and the final BV value is determined.

HonBV = k * HiwBV + (1-k) * AmpBV
The weighting coefficient K has a characteristic that it approaches 0 as the main light emission guide number increases during highlight-weighted metering. In other words, it approaches multi-pattern metering.

In the case of flash emission (TV is less than flash synchronization seconds)
TarGV = FullGV -1
And.

In the case of FP flash (TV is larger than flash sync seconds)
TarGV = FullGV FP -1
And.

During the release sequence, the sensitivity is changed as in the second embodiment.

(Effects of the third embodiment and the fourth embodiment)
When daytime synchronized photography is performed using highlight-weighted metering, the metering value is determined so that the gradation in the sky area does not skip.
When exposure is controlled, the aperture tends to be narrowed down or the shutter speed tends to increase. At this time, a guide number larger than the full flash guide number of the attached strobe is required, and the completed photo tends to be underexposed.
If the guide number is insufficient, it is possible to change the aperture to open so that the main light emission reaches the subject. However, if you prioritize optimizing the guide number, the strobe light will reach you, but the exposure may be overexposed and the photo may look unattractive.

In the third and fourth embodiments, when it can be determined that the scene is underexposed by using the strobe, the exposure control and the photometric value are determined so that the guide number is within the light emission control range. However, the exposure is controlled so that the exposure is not brighter than the exposure by multi-pattern metering.
According to the third and fourth embodiments, the combination of light-weighted metering and strobe photography can reduce failed photographs.

1,1A: Camera, 2: Camera body, 3: Lens lens barrel, 101: Release switch, 102: Movie switch, 106: First imaging unit, 109: Photograph lens, 117: Second imaging unit, 117a: Photographed Field 119: Light emitting device, 201: Camera control unit, 201: Exposure control unit, 203: Lens control unit, 207: Illumination control unit, 216: Metering mode selection unit

The present invention relates to shooting device.

An object of the present invention is to provide a possible appropriate exposure control shooting device.

One embodiment of the present invention includes a plurality of photometric regions in which subject light is incident, and is based on a photometric unit for obtaining a photometric value of light incident on the plurality of photometric regions, and a photometric value of each of the plurality of photometric regions. The exposure control unit includes an exposure control unit that controls exposure based on the photometric value of the second photometric region including the first photometric region determined by the above, and the exposure control unit determines the size of the second photometric region according to the shooting mode. It is a shooting device to be changed .

According to the present invention, it is possible to provide a possible appropriate exposure control shooting device.

Claims (1)

A photometric unit that divides the field of view into multiple areas and obtains the photometric value of the light incident on each area.
An exposure control unit that determines exposure based on the photometric value of the photometric region including the maximum output region of the divided regions is provided.
The exposure control unit is an imaging device that changes the size of the photometric region including the divided region according to the selected imaging mode.

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