JP2013044996A - Imaging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent deterioration in calculation accuracy of the quantity of main light emission.SOLUTION: An imaging apparatus comprises: a main flash device; at least one sub flash device; light emission controlling means for controlling preliminary light emission on the main flash device, preliminary light emission on each sub flash device after the preliminary light emission on the main flash device, and main light emission based on the result of the preliminary light emission; photometric means for measuring a light from a subject; photometry controlling means for performing first photometry which measures a reflected light from the subject by the photometric means at preliminary light emission on the main flash device and the sub flash device, and performing second photometry which measures a normal light of the subject by the photometry means, just before or just after the preliminary light emission; and calculating means for calculating the quantity of the main light emission on the main flash device and the sub flash device, by removing a normal light component obtained by the second photometry from the photometry result obtained by the first photometry.

Description

  The present invention relates to an imaging apparatus.

  2. Description of the Related Art Conventionally, there has been known an imaging device that calculates a main light emission amount using a light measurement result of stationary light and a light measurement result at the time of preliminary light emission for a master flash device and a remote flash device (for example, Patent Document 1).

JP 2010-231228 A

  However, as the number of remote flash devices increases, there is a problem that the interval between the light measurement of the steady light and the light measurement during the preliminary light emission becomes longer, and the calculation accuracy of the main light emission amount decreases.

  The imaging device according to the first aspect of the present invention includes a main flash device, at least one sub flash device, preliminary light emission for the main flash device, and each of the sub flash devices after preliminary light emission of the main flash device. Light emission control means for controlling the preliminary light emission and the main light emission based on the result of the preliminary light emission, the light measurement means for measuring the light from the subject, and the light metering means at the time of the preliminary light emission of the main flash device and the sub flash device from the subject. Metering control means for performing first metering for metering the reflected light, and second metering for metering the steady light of the subject by the metering means immediately before or after the preliminary light emission, and the metering result obtained by the first metering And calculating means for calculating a main light emission amount of the main flash device and the sub flash device by removing the steady light component obtained by the second photometry.

  According to the present invention, it is possible to prevent a reduction in the calculation accuracy of the main light emission amount.

The figure explaining the principal part structure of the digital camera by embodiment of this invention FIG. 1 is a block diagram illustrating a configuration of a control system of a digital camera according to an embodiment Conceptual diagram for explaining an image signal from a photometric sensor according to an embodiment The figure explaining the image signal from the photometry sensor by embodiment The figure which shows the timing of the monitor light emission of the flash device by embodiment, and the photometry by a digital camera The figure which explains the operation by the calculation part conceptually Flowchart for explaining operation of digital camera according to embodiment The figure which shows the timing of the monitor light emission of the flash device by conventional technology, and the photometry with the digital camera The figure explaining the calculation by the calculation part in 2nd Embodiment The figure explaining the charge read-out time from the photometry sensor in a modification

-First embodiment-
A camera according to a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a main configuration of the digital camera 1. The digital camera 1 includes a camera body 100, an interchangeable lens 200, a main flash device (master flash device) 300, and a sub flash device (remote flash device) 400. The interchangeable lens 200 and the master flash device 300 are attached to the camera body 100 via mount parts (not shown). In this specification, for convenience of explanation, the case where there is one remote flash device 400 is shown as an example, but the number of remote flash devices 400 is not limited.

  As shown in FIG. 1, the camera body 100 includes a quick return mirror 10, a focusing screen 11, a pentaprism 12, an eyepiece lens 13, an image sensor 14, a focus detection sensor 15, a photometric prism 16, a photometric lens 17, A photometric sensor 18 and a shutter 19 are provided. The interchangeable lens 200 is provided with a photographing lens 201 and a diaphragm 202. In FIG. 1, for convenience of illustration, various lenses are represented by a single photographing lens 201.

  FIG. 2 is a block diagram of the control system of the digital camera 1. In FIG. 2, the components shown in FIG. The control system of the digital camera 1 includes an image sensor 14, a control circuit 20, an LCD drive circuit 21, a liquid crystal display 22, an operation unit 23, and a memory card interface 24.

  Referring to FIG. 1, subject light that has entered the digital camera 1 after passing through the photographing lens 201 is guided upward by a quick return mirror 10 positioned as indicated by a solid line in FIG. 1 before the shutter release. An image is formed on the focusing screen 11. The subject image formed on the focusing screen 11 is guided to the eyepiece 13 by the pentaprism 12. As a result, the subject image is observed by the photographer. Further, the subject image formed on the focusing screen 11 forms an image on the imaging surface of the photometric sensor 19 via the photometric prism 16 and the photometric lens 17.

  Part of the subject light passes through the semi-transmission region of the quick return mirror 10, is reflected downward by the sub mirror 10 a, and enters the focus detection sensor 15. After the release, the quick return mirror 10 rotates to a position (mirror up position) indicated by a broken line in FIG. 1, the subject light is guided to the image sensor 14, and a subject image is formed on the imaging surface.

The control system will be described in detail with reference to FIG.
In the imaging element 14, photoelectric conversion elements (pixels) constituted by, for example, a CCD or a CMOS are two-dimensionally arranged. The image sensor 14 is driven according to the control of the control circuit 20 to be described later, captures a subject image formed by the light beam that has passed through the photographing lens 201, and outputs an image signal obtained by the imaging.

  In the photometric sensor 18, photoelectric conversion elements (pixels) made of, for example, CMOS are two-dimensionally arranged. The photometric sensor 18 is driven according to the control of the control circuit 20 described later, captures the subject image formed by the light beam that has passed through the photographing lens 201, and outputs an image signal obtained by the imaging. The light receiving surface of the photometric sensor 18 is provided with a color filter arranged in a Bayer arrangement corresponding to the pixel position, and is configured to obtain color information from the output signal of the photometric sensor 18.

  The control circuit 20 includes a CPU, a ROM, a RAM, and the like (not shown), and is an arithmetic circuit that controls each component of the digital camera 1 and executes various data processing. The control circuit 20 generates image data after performing image processing such as white balance processing, gamma correction processing, color interpolation processing, edge enhancement, and vignette correction on the image signal output from the image sensor 14. To be recorded in the memory card 25.

  When the release button is fully pressed when the flash device that irradiates the subject with the photographing auxiliary light is permitted, the control circuit 20 performs the TTL light control operation and then performs the photographing control. In the TTL dimming operation, the control circuit 20 causes the photometry sensor 18 to perform an accumulation operation in accordance with the preliminary light emission of the master flash device 300 and the remote flash device 400, and the TTL dimming is performed based on the signal obtained by the accumulation operation. Perform the operation. Then, the control circuit 20 controls the main light emission amounts of the master flash device 300 and the remote flash device 400 based on the TTL dimming calculation result.

  The control circuit 20 functionally includes a light emission control unit 211, a photometry control unit 212, a determination unit 213, and a calculation unit 214 in order to perform the above TTL dimming calculation. The light emission control unit 211 controls preliminary light emission and main light emission of a master flash device 300 and a remote flash device 400 described later. The photometric control unit 212 controls the operation of the photometric sensor 18 when the master flash device 300 and the remote flash device 400 perform preliminary light emission. As will be described later, the determination unit 213 determines whether or not the photometric result obtained by the photometric sensor 18, that is, the output value of the photometric result satisfies a predetermined condition. The calculation unit 214 calculates the master flash device 300 and the remote flash device based on the photometry result when the master flash device 300 and the remote flash device 400 perform preliminary light emission and the photometry result when the master flash device 300 and the remote flash device 400 do not emit light. The main light emission amount of the flash device 400 is calculated. Details of the light emission control unit 211, the photometry control unit 212, the determination unit 213, and the calculation unit 214 will be described later.

  The memory card interface 24 is an interface to which the memory card 25 can be attached and detached. The memory card interface 24 writes image data to the memory card 25 or reads image data recorded on the memory card 25 based on the control of the control circuit 20. The memory card 25 is a semiconductor memory card such as a compact flash (registered trademark) or an SD card.

  The LCD drive circuit 21 is a circuit that drives the liquid crystal display 22 based on a command from the control circuit 20. The liquid crystal display 22 displays menu data for setting the operation of the digital camera 1 and display data created by the control circuit 20 based on image data recorded on the memory card 25 in the playback mode. . The operation unit 23 is a switch that receives a user operation. The operation unit 23 includes a power switch, a release switch, a display switch for other setting menus, a setting menu determination button, and the like.

  The master flash device 300 includes a master flash emitter 301 and a master flash control circuit 302. The master flash control circuit 302 controls the operation of the master flash device 300, that is, the flash emission of the master flash emitter 301, in response to an instruction signal from the control circuit 20 of the digital camera 1. The instruction signal from the control circuit 20 of the digital camera 1 is transmitted to the master flash control circuit 302 via a mount unit (not shown) provided in the camera body 100. The master flash control circuit 302 causes the master flash emitter 301 to emit light in response to an instruction signal from the control circuit 20 of the digital camera 1 for the purpose of transmitting information to the remote flash device 400 described later.

  The remote flash device 400 includes a remote flash light emitter 401, a remote flash control circuit 402, and a remote light receiving unit 403. The remote light receiving unit 403 receives a slight amount of light emission (pulse light emission) from the master flash device 300. The remote flash control circuit 402 controls the operation of the remote flash device 400, that is, the flash emission of the remote flash emitter 401, according to the pulse emission received by the remote light receiving unit 403.

  Hereinafter, the operation of the digital camera 1 during TTL light control will be mainly described. Prior to the description of the TTL light control operation, the image signal readout control of the photometric sensor 18 by the control circuit 20 will be described. In the present embodiment, the control circuit 20 converts the image signal output from the photometric sensor 18 into blocks of different sizes for each function (exposure calculation function, subject tracking function, face detection function, and TTL dimming calculation function). Blocking process is performed.

  FIG. 3A is a front view showing a partial configuration of the photometric sensor 18. The photometric sensor 18 includes a plurality of pixels (photoelectric conversion elements) 180 arranged in a matrix, and the number of pixels is, for example, about 100,000 pixels. Each pixel 180 is provided with any one of red (R), green (G), and blue (B) color filters to form a Bayer array.

  FIG. 3B is a diagram for explaining exposure calculation blocking. In the photometric sensor 18, the control circuit 20 combines adjacent a × a pixels 180 into one exposure calculation block 181, and synthesizes and adds image signals for each pixel 180 included in the exposure calculation block 181. As shown in FIG. 3B, the shape of the exposure calculation block 181 is square, and the number of pixels (a) in the horizontal and vertical directions included in the exposure calculation block 181 is the same.

  FIG. 3C is a diagram for explaining block formation for subject tracking. In the photometric sensor 18, the control circuit 20 combines adjacent b × b pixels 180 into one subject tracking block 182, and synthesizes and adds image signals for each pixel 180 included in the subject tracking block 182. The size of the subject tracking block 182 is set smaller than the size of the exposure calculation block 181 (that is, b <a). Further, as shown in FIG. 3C, the subject tracking block 182 has a square shape, and the horizontal and vertical pixel numbers (b) included in the subject tracking block 182 are the same.

  FIG. 3D is a diagram for explaining block detection for face detection. The control circuit 20 treats one pixel 180 in the photometric sensor 18 as one face detection block 183, and uses an image signal from the face detection block 183 (that is, an image signal from each pixel 180) as face detection data. . That is, since the size of the face detection block 183 is the same as the size of each pixel 180, it is smaller than any of the size of the exposure calculation block 181 and the subject tracking block 182.

  During the TTL light control operation, an operation of reading a signal from the photometric sensor 18 for each predetermined number of horizontal pixel columns (horizontal lines), so-called thinning readout, is performed. FIG. 4A is a diagram for explaining this thinning readout. In FIG. 4A, a pixel 180 with a hatched line indicates a pixel from which an image signal is not read, and a pixel 180 without a hatched line indicates a pixel from which an output signal is read. In FIG. 4, for the convenience of illustration, a part of the photometric sensor 18 is extracted and shown. As shown in FIG. 4A, signals are read from the photometric sensor 18 by d columns for every c columns. The present embodiment is configured such that the readout time can be shortened by performing thinning readout in this way.

  FIG. 4B is a diagram for explaining blocking for TTL dimming calculation. The control circuit 20 collects adjacent d × e pixels 180 in a region where the photometric sensor 18 is thinned and read out to form one TTL dimming calculation block 184, and the pixels included in the TTL dimming calculation block 184 The image signals for every 180 are synthesized and added. The number of pixels in the vertical direction of the TTL dimming calculation block 184 is d corresponding to the d columns to be thinned and read out. In the present embodiment, the TTL dimming calculation block 184 has a horizontally long rectangular shape, and the number of pixels in the horizontal direction is larger than the number of pixels in the vertical direction of the TTL dimming calculation block 184 (that is, d <e). .

  With reference to the time chart shown in FIG. 5, the description will be focused on the photometry processing by the photometry sensor 18 and the calculation processing of the main light emission amounts of the flash devices 300 and 400 at the time of TTL light control. Hereinafter, description will be made separately on the photometry processing and the main light emission amount calculation processing.

(1) Photometry processing FIG. 5 shows a case where an operation signal is output from the operation unit 23 in response to a full press operation of the release switch by the user, that is, a photographing instruction operation at time t0. Note that the main flash device 300 and the remote flash device 400 perform monitor light emission at the position where the aperture 202 is opened and the quick return mirror 10 is at the position (mirror down position) shown by the solid line in FIG.

  Before the time t0, that is, before the photographing instruction operation is performed by the user, the photometric sensor 18 outputs a photometric signal corresponding to the subject image formed through the photographing lens 201 to the control circuit 20 every predetermined period. The control circuit 20 calculates an appropriate exposure value related to the steady light exposure based on the photometric signal input from the photometric sensor 18, and determines an aperture value and a shutter speed.

  When a shooting instruction operation is performed by the user at time t0, the light emission control unit 211 of the control circuit 20 of the digital camera 1 outputs a monitor light emission instruction signal that instructs the master flash control circuit 302 to perform monitor light emission. When a monitor light emission instruction signal is input, the master flash control circuit 302 causes the master flash light emitter 301 to perform monitor light emission at a predetermined monitor light emission amount at time t1. As a result, as shown in FIG. 5, the master flash light emitter 301 performs monitor light emission in the period Δt between times t1 and t2. Further, the monitor flash control device 302 causes the master flash light emitter 301 to emit pulses, and causes the remote flash device 400 to perform monitor light emission during the period Δt ′ from time t5 to t6.

  When the monitor light emission instruction signal is output by the light emission control unit 211, the photometry control unit 212 charges the photometric sensor 18 while the master flash light emission unit 301 emits light, that is, during the period Δt between times t1 and t2. To accumulate. In this case, the photometric sensor 18 emits light from the master flash device 300, is reflected by the subject, and enters through the photographing lens 201 (subject reflected light amount) and ambient light (steady light) of the subject. The charge signal corresponding to is output to the control circuit 20. In the following description, the charge accumulation operation performed by the photometric sensor 18 during monitor light emission is referred to as monitor photometry.

  Immediately after the monitor photometry is performed, that is, after the sweep of the electric charge accumulated by the monitor photometry is completed (time t3 in FIG. 5), the photometry control unit 212 performs the period Δt of the time t3 to Δt4 with respect to the photometry sensor 18. To accumulate charge. In other words, the photometric sensor 18 accumulates charges for a period Δt from time t3 continuously with monitor photometry. In this case, the photometric sensor 18 is a charge signal corresponding to the amount of light incident through the photographing lens 201 when the master flash device 300 is not emitting light, that is, the amount of steady light that is ambient light of the subject. Is output to the control circuit 20. In the following description, the charge accumulation operation performed by the photometric sensor 18 when no light is emitted is referred to as steady-state photometry. In the present embodiment, the photometry control unit 212 controls the time during which the photometry sensor 18 performs steady-state photometry to be the same period Δt as the monitor photometry time.

  The determination unit 213 and the calculation unit 214 calculate the main light emission amount of the master flash light emission unit 301 based on the photometry value obtained by the monitor photometry and the photometry value obtained by the steady light photometry. Details of the main light emission amount calculation processing by the determination unit 213 and the calculation unit 214 will be described later.

  Subsequently, in the remote flash device 400, the remote flash control circuit 402 causes the remote flash light emitting unit 401 to emit a monitor in response to the pulse signal received by the remote light receiving unit 403. As shown in FIG. 5, the remote flash light emission unit 401 emits monitor light during a period Δt ′ from time t5 to time t6. When the remote flash light emission unit 401 starts monitor light emission at time t5, the photometry control unit 212 emits light to the photometry sensor 18 while the remote flash light emission unit 401 emits light, that is, during a period Δt ′ from time t5 to t6. Perform monitor metering. That is, the photometric sensor 18 emits a charge signal corresponding to the amount of reflected light that is emitted from the remote flash device 400, reflected by the subject, and incident through the photographing lens 201, and the amount of steady light that is ambient light of the subject. Output to the control circuit 20.

  Immediately after the monitor photometry is performed, that is, after the sweep of the electric charge accumulated by the monitor photometry is completed (time t7 in FIG. 5), the photometry control unit 212 performs the period Δt of the time t7 to t8 with respect to the photometry sensor 18. Use 'to perform steady-state photometry. In other words, the photometric sensor 18 performs steady-state photometry for a period Δt ′ from time t7 continuously to monitor photometry. In this case, the photometric sensor 18 outputs to the control circuit 20 a charge signal corresponding to the amount of light that has entered through the photographing lens 201 when the remote flash device 400 is not emitting light and is not emitting light, that is, the amount of steady light. To do. In the case of the remote flash device 400 as well, the photometry control unit 212 controls the time during which the photometry sensor 18 performs steady light photometry to be the same period Δt ′ as the monitor photometry time. The determination unit 213 and the calculation unit 214 calculate the main light emission amount of the remote flash light emission unit 401 based on the photometric value obtained by the monitor photometry and the photometric value obtained by the steady light photometry.

(2) Real Light Amount Calculation Processing Details of the main light emission amount calculation processing by the determination unit 213 and the calculation unit 214 will be described. In the following description, the process for calculating the main light emission amount of the master flash light emitting unit 301 is performed, but the same process is performed for the process for calculating the main light emission amount of the remote flash light emitting unit 401. For convenience of explanation, a photometric value obtained by monitor photometry is called a monitor photometric value, and a photometric value obtained by steady light photometry is called a steady light photometric value.

  As described above, the monitor photometric value obtained by monitor photometry is a value corresponding to the light amount including the subject reflected light amount and the steady light amount. Therefore, the calculation unit 214 performs an operation of removing (subtracting) the steady light amount, that is, the steady light metering value representing the steady light component of the subject, from the monitor metering value in order to calculate the main light emission amount corresponding to the subject reflected light amount. (Subtraction processing) is performed. However, when the output value of the stationary light metering value is small, that is, when it corresponds to the noise level, the calculation unit 214 prohibits the above subtraction. Details will be described below.

  The determination unit 213 determines whether or not the output value of the monitor photometric value is equal to or greater than a predetermined threshold th1. Further, the determination unit 213 determines whether the output value of the steady light photometric value is equal to or greater than a predetermined threshold th2. When it is determined that the output value of the monitor photometric value is equal to or greater than the threshold th1 and the output value of the steady light photometric value is equal to or greater than the threshold th2, the calculation unit 214 subtracts the steady light photometric value from the monitor photometric value. Then, the calculation unit 214 calculates the main light emission amount of the master flash light emission unit 301 using a known technique based on the value obtained by the subtraction process.

  When it is determined that the output value of the monitor photometric value is less than the threshold th1 and the output value of the steady light photometric value is less than the threshold th2, the calculation unit 214 does not subtract the steady light photometric value from the monitor photometric value. That is, the calculation unit 214 calculates the main light emission amount of the master flash light emission unit 301 using a known technique based on the monitor photometric value. Note that the threshold values th1 and th2 are determined according to the gain of the photometric sensor 18 as a value corresponding to the noise level of the output level of the photometric value, and stored in advance in a memory (not shown).

  FIG. 6 shows the relationship between the monitor photometric value, the steady light photometric value, and the subject reflected light amount. FIG. 5 shows that the subject reflected light amount is calculated by subtracting the steady light metering value from the monitor photometric value including the subject reflected light amount and the steady light amount. FIG. 6A shows, for example, the relationship between the monitor photometry value, the steady light photometric value, and the subject reflected light amount when monitor photometry and normal light photometry are performed on a nearby subject in a situation where the periphery of the subject is relatively bright. Indicates. In this case, the output value of the monitor photometric value and the output value of the steady light photometric value are sufficiently larger than the noise level. Accordingly, the influence of the noise component by the photometric sensor 18 is not added to the value of the subject reflected light amount obtained by subtracting the steady light photometric value from the monitor photometric value.

  FIG. 6B shows, for example, the relationship between the monitor photometry value, the steady light photometric value, and the subject reflected light amount when monitor photometry and normal light photometry are performed on a nearby subject in a relatively dark environment. Indicates. In this case, the output value of the monitor photometric value is sufficiently larger than the noise level, but is small enough that the output value of the steady light photometric value is regarded as the noise level. That is, the output value of the steady light metering value may vary. However, the output value of the monitor photometric value is sufficiently large.In other words, the subject reflected light amount included in the monitor photometric value is large. Therefore, even if the steady light photometric value is subtracted from the monitor photometric value, the influence of noise variation is small. Become.

  FIG. 6C shows, for example, the relationship between the monitor photometric value, the steady photometric value, and the subject reflected light amount when monitor photometry and normal light photometry are performed on a distant subject in a situation where the subject is relatively bright. Indicates. In this case as well, as in the case shown in FIG. 6A, the output value of the monitor photometric value and the output value of the steady light photometric value are sufficiently larger than the noise level. Accordingly, the influence of the noise component by the photometric sensor 18 is not added to the value of the subject reflected light amount obtained by subtracting the steady light photometric value from the monitor photometric value.

  6D and 6E show, for example, monitor photometry value, steady light photometry value, and subject when monitor photometry and normal light photometry are performed on a distant subject in a situation where the subject is relatively dark. The relationship of the amount of reflected light is shown. In this case, the output value of the monitor photometric value and the output value of the steady light photometric value are small enough to be regarded as a noise level. As shown in FIGS. 6D and 6E, there is a possibility that the variation sign is reversed to the output value of the steady light photometric value. Since the output value of the monitor photometric value is also a small value, the subject reflected light amount obtained by subtracting the steady light photometric value from the monitor photometric value varies depending on whether the sign of the steady light photometric value is positive or negative. .

  However, in the present embodiment, when the output value of the steady light metering value is determined to be less than the threshold th2, the calculation unit 214 does not perform the subtraction process of the steady light metering value from the monitor metering value. That is, in the cases shown in FIGS. 6D and 6E, the subtracting process of the steady light metering value is not performed, so that the calculation unit 214 calculates the main light emission amount without using the value in which the variation occurs due to the subtraction process. it can.

  When the main light emission amounts of the master flash light emission unit 301 of the master flash device 300 and the remote flash light emission unit 401 of the remote flash device 400 are calculated as described above, the light emission control unit 211 sends the light emission control unit 211 to the master flash control circuit 302. A main light emission instruction signal for instructing main light emission is output. As a result, at time t9, the master flash light emitting unit 301 and the remote flash light emitting unit 401 perform main light emission to illuminate the subject.

  FIG. 7 is a flowchart illustrating the operation of the digital camera 1 according to the embodiment. 7 is stored in a memory (not shown) in the control circuit 20, and is activated by the control circuit 20 when a shooting instruction signal is output from the operation unit 23 in response to the release full-press operation by the user. To be executed.

  In step S1, the light emission control unit 211 outputs a monitor light emission instruction signal to the master flash control circuit 302, and proceeds to step S2. In step S2, the photometry control unit 212 causes the photometry sensor 18 to start monitor photometry, and ends monitor photometry in step S3. In step S4, the light emission control unit 212 causes the photometric sensor 18 to start steady light metering, and ends the steady light metering in step S5.

  In step S6, the control circuit 20 determines whether or not the monitor photometry and the steady light photometry have been completed for all the flash devices. If monitor metering and steady-light metering have not been completed for all flash devices, the control circuit 20 makes a negative determination in step S6 and returns to step S2. If the monitor photometry and the steady light photometry have been completed for all the flash devices, the control circuit 20 makes a positive determination in step S6 and proceeds to step S7.

  In step S7, the main emission amount of the flash device is calculated by the calculation unit 214, and the process proceeds to step S8. In step S <b> 8, the light emission control unit 212 outputs a main light emission instruction signal to the master flash control circuit 302. Then, the control circuit 20 performs a photographing process and ends the process.

According to the digital camera 1 according to the first embodiment described above, the following operational effects can be obtained.
(1) The light emission control unit 211 performs preliminary light emission (monitor light emission) of the master flash device 300, preliminary light emission for each of the remote flash devices 400 after monitor light emission of the master flash device 300, and main light emission based on the result of the monitor light emission. And control. The photometric sensor 18 measures light from the subject. The metering control unit 212 performs monitor metering in which the reflected light from the subject is metered by the metering sensor 18 when the master flash device 300 and the remote flash device 400 emit light, and immediately after the monitor light emission, Performs constant light metering to measure light. Then, the calculation unit 214 calculates the main light emission amounts of the master flash device 300 and the remote flash device 400 by removing the steady light component obtained by the steady light metering from the photometry result obtained by the monitor photometry.

  In the conventional technique shown in FIG. 8, steady light photometry is performed from time tn-1 to time tn before the photographing instruction operation is performed at time t0. For the master flash device 300, calculation is performed using the photometric value of the steady photometry performed at the time tn-1 to the time tn and the photometric value of the monitor photometry performed at the time t1 to t2. Is called. For the remote flash device 400, calculation is performed using the photometric value of steady-light photometry performed at time tn-1 to time tn and the photometric value of monitor photometry performed at times t5 to t6. Is called. For this reason, the time interval from stationary light metering to monitor metering becomes long. In particular, as the number of remote flash devices increases, the interval between the monitor photometry and the steady light photometry for the remote flash devices that emit the monitor light in the slow order becomes longer. For this reason, when the subject is moving or when camera shake occurs, the calculated main light emission amount may not be suitable for shooting.

  In particular, when the photometric sensor 18 is performing decimation readout, the position of the subject with respect to the same readout row in the photometric sensor 18 is greatly different if the time interval from stationary photometry to monitor photometry is increased. As a result, the longer the time interval between monitor metering and steady-light metering is, the more susceptible to subject movement and camera shake. In the present embodiment, since constant light metering is performed immediately after monitor metering, it is possible to suppress the influence of movement and camera shake on the subject, and to prevent a reduction in the calculation accuracy of the main light emission amount.

(2) The determination unit 213 determines whether the photometric result obtained by monitor photometry is greater than the threshold th1, and determines whether the photometric result obtained by steady-state photometry is lower than the threshold th2. When the determination unit 213 determines that the photometry result by the steady light metering is lower than the threshold th2, and the photometry result by the monitor photometry is lower than the threshold th1, the calculation unit 214 performs the photometry obtained by the monitor photometry. The main flash amount of the master flash device 300 and the remote flash device 400 is calculated using the result. When the output value of the monitor photometric value and the output value of the steady light photometric value are small enough to be regarded as a noise level, the result calculated by the subtraction process may vary. In the present embodiment, it is possible to calculate the main light emission amount without using a value in which variation has occurred due to the subtraction process, and to prevent a reduction in the calculation accuracy of the main light emission amount.

-Second Embodiment-
A digital camera 1 according to the second embodiment will be described with reference to FIG. In the following description, the same components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described. Points that are not particularly described are the same as those in the first embodiment. The present embodiment is different from the first embodiment in that a value obtained by weighting the output value of the steady light metering value is subtracted from the monitor metering value.

  The following description will be focused on the processing of the determination unit 213 and the calculation unit 214. As in the case of the first embodiment, the determination unit 213 determines whether or not the output value of the steady light photometric value is equal to or greater than the threshold th2. Further, the determination unit 213 determines whether or not the output value of the steady light photometric value is equal to or greater than a threshold th3 (> th2). Then, the calculation unit 214 determines the weighting coefficient k for the output value of the steady light photometric value according to the determination result of the output value of the steady light metering value by the determination unit 213. The threshold values th2 and th3 and the coefficient k are values determined according to the gain of the photometric sensor 18, and are recorded in advance in a processing memory (not shown).

  As illustrated in FIG. 9, when the determination unit 213 determines that the output value of the steady light metering value is less than the threshold th2, the calculation unit 214 sets the coefficient k to 0. When the determination unit 213 determines that the output value of the steady light metering value is equal to or greater than the threshold th3, the calculation unit 214 sets the coefficient k to 1. When the determination unit 213 determines that the output value of the steady light metering value is greater than or equal to the threshold th2 and less than the threshold th3, the calculation unit 214 sets the value of the coefficient k to a value between 0 and 1. At this time, the calculation unit 214 makes the value of the coefficient k approach 0 as the output value of the steady light photometric value approaches the threshold value th2, and sets the value of the coefficient k to 1 as the output value of the steady light photometric value approaches the threshold value th3. The value of the coefficient k is set so as to approach. In other words, the calculation unit 214 gradually decreases the contribution rate to the calculation of the subject reflected light amount as the output value of the steady light metering value decreases.

When the value of the coefficient k is set as described above, the calculation unit 214 calculates the subject reflected light amount using the following equation (1). Then, the calculation unit 214 calculates the main light emission amount of the flash device using the calculated subject reflected light amount.
Subject reflected light amount = monitor photometric value−k × stationary light photometric value (1)

According to the digital camera 1 according to the second embodiment described above, the following functions and effects can be obtained in addition to the functions and effects obtained by the first embodiment.
The determination unit 213 determines whether or not the photometric result obtained by the steady light photometry is lower than the threshold th3 (> th2). When the determination unit 213 determines that the photometry result obtained by the steady light metering is larger than the threshold th2 and lower than the threshold th3, the calculation unit 214 outputs the output value output during the steady light metering. The closer to the threshold th2, the smaller the coefficient k indicating the weighting value added to the output value output at the time of stationary light metering. Therefore, even when the steady light metering value is a relatively low output value, the steady light metering value is reflected in the calculation of the main light emission amount according to the output value, thereby improving the calculation accuracy of the main light emission amount. Can do.

The digital camera 1 according to the first and second embodiments described above can be modified as follows.
(1) The photometry control unit 212 may cause the photometry sensor 18 to perform monitor photometry immediately after stationary light photometry, instead of causing the photometry sensor 18 to perform steady light metering immediately after monitor photometry. In this case, the light emission control unit 211 outputs a monitor light emission instruction signal so that the flash device emits monitor light immediately after the constant light photometry by the photometric sensor 18 is finished.

(2) The photometry control unit 212 may set the constant light metering gain obtained by the photometry sensor 18 and the monitor metering gain the same. In other words, the photometry control unit 212 sets the amplification factor for the image signal output from the photometry sensor 18 during steady-state photometry and the amplification factor for the image signal output from the photometry sensor 18 during monitor photometry to the same value. As a result, the output value of the steady light metering value and the output value of the monitor light metering value are amplified by the same gain at the same time Δt, that is, acquired under the same conditions. Can be improved.

(3) The digital camera 1 may include two or more rolling shutter modes with different readout times when reading out the electric charges accumulated in the pixels of the photometric sensor 18. A case where the rolling shutter mode of the photometric sensor 18 has, for example, a first mode and a second mode will be described. As shown in FIG. 10, in the first mode, for example, the photometric sensor 18 starts charge accumulation in the next pixel row after a time T1 from the start of charge accumulation in a certain pixel row. In the second mode, the photometric sensor 18 starts charge accumulation in the next pixel row after a time T2 from the start of charge accumulation in a certain pixel row. At this time, the time T2 is shorter than the time T1. In this case, the readout time when reading out the charges accumulated in the pixels of the photometric sensor 18 in the second mode is shorter than the charge readout time in the first mode. Then, the photometry control unit 212 may set the same rolling shutter mode, for example, the second mode, and read out the charges during the steady-light photometry and the monitor photometry.

(4) Instead of the calculation unit 214 performing subtraction based on the determination result regarding the output value of the stationary light metering value and the output value of the monitor light metering value by the determination unit 213, the output value of the steady light metering value by the determination unit 213 The calculation unit 214 may perform subtraction on the basis of the determination result regarding. In this case, when the determination unit 213 determines that the output value of the steady light metering value is less than the predetermined threshold, the calculation unit 214 does not subtract the steady light metering value from the monitor photometry value.

  In addition, the present invention is not limited to the above-described embodiment as long as the characteristics of the present invention are not impaired, and other forms conceivable within the scope of the technical idea of the present invention are also within the scope of the present invention. included. The embodiments and modifications used in the description may be configured by appropriately combining them.

18 photometric sensor, 20 control circuit,
211 light emission control unit, 212 photometry control unit,
214 calculation unit, 300 master flash device,
400 Remote flash device

Claims (4)

A main flash device;
At least one secondary flash device;
Light emission control means for controlling preliminary light emission for the main flash device, preliminary light emission for each of the sub flash devices after preliminary light emission of the main flash device, and main light emission based on the result of the preliminary light emission,
A photometric means for measuring light from the subject;
First photometry in which reflected light from the subject is metered by the photometry means during the preliminary light emission of each of the main flash device and the sub flash device, and immediately before or after the preliminary light emission, the photometry means Metering control means for performing second metering for metering stationary light;
Calculating means for removing the steady light component obtained by the second photometry from the photometric result obtained by the first photometry and calculating the main light emission amount of the main flash device and the sub flash device;
An imaging apparatus comprising: The imaging device according to claim 1,
The photometric control means uses the photometric means to make the photometric time of the first photometry and the photometric time of the second photometry the same. The imaging device according to claim 1,
The imaging device, wherein the photometry control unit sets the gain of the first photometry and the gain of the second photometry by the photometry unit to the same gain. The imaging device according to claim 1,
Comprising setting means for setting a first readout mode and a second readout mode, each of which has a different readout time when reading out the charges accumulated in the plurality of pixels constituting the photometric means;
The imaging apparatus according to claim 1, wherein the photometry control unit sets the same readout mode for the first photometry and the second photometry by the photometry unit.

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