JP6192420B2 - Imaging device - Google Patents

Description

  The present invention relates to an imaging device capable of emitting light from a second flash device located outside in correspondence with light emission of a first flash device on the imaging device side.

  Using the output of a photometric element such as an image sensor provided inside the camera, the light emission operation is synchronized with the pre-light emission operation and the main light emission operation by TTL (Through the Lens) dimming control, and is arranged outside the image pickup apparatus. In addition, slave TTL dimming control that simply controls TTL adjustment of a flashlight emitting device (external flash) is known (see, for example, Patent Document 1).

  The slave TTL dimming control is widely used for underwater photography and the like because the TTL dimming can be performed without a cable on an external flash that emits a large amount of light with a small, small-intensity flash built in the camera. In this slave TTL light control, the external flash side light emission start / stop operation is performed in synchronization with the pre-light emission and the main light emission start / stop timing detected by the light receiving element on the external flash side. Control the amount.

JP 2007-298880 A

  In recent years, the amount of light emitted from a flash device built in or connected to a camera has been reduced due to high sensitivity of an image sensor and miniaturization of the camera itself. That is, the light emission time for controlling the light emission amount is becoming shorter. In particular, since the pre-light emission operation is a small amount of light emission, the light emission operation is performed in a shorter time, and the light emission stop timing cannot be detected by the light receiving element on the external flash side, and the light emission may not be performed. As described above, in the conventional slave TTL dimming control, (1) when the emission stop timing at the time of pre-emission cannot be received, the captured image becomes under, and (2) when the emission stop timing at the time of main emission cannot be received. May cause the captured image to be over.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide an imaging apparatus capable of reliably performing appropriate slave TTL dimming control according to light emission from the imaging apparatus side.

In order to achieve the above object, an imaging apparatus according to a first aspect of the present invention is an imaging apparatus capable of emitting light from a second flash apparatus located outside in correspondence with light emission of a built-in first flash apparatus. A first flash device including a flash light emitting unit that emits light, and a flash light emission control unit that controls light emission of the flash light emitting unit; a first light emission mode that does not use the second flash device; A light emission mode setting unit capable of setting a second light emission mode using a flash device, and when the second light emission mode is set, when performing a pre-light emission operation prior to the main light emission, the flash emission control section delays the emission stop time of the preliminary light emission than the light emitting stop time of preliminary light emission when the first light emitting mode is set, the pre-emission originating Increasing the amount of light emission of preliminary light emission than the amount.

An image pickup apparatus according to a second aspect of the present invention is an image pickup apparatus capable of emitting a second flash device located outside in correspondence with light emission of a built-in first flash device. A first flash device having a flash light emission control unit that controls light emission of the flash light emission unit, a first light emission mode that does not use the second flash device, and a first flash device that uses the second flash device. A flash mode setting unit capable of setting two flash modes, and when the second flash mode is set, the flash flash control unit sets the first flash mode during the main flash. than the emission stop time of the light emission if it is delayed luminescence stop time of main flash, the emission amount of the light emission in the case where the first light emitting mode is set highest To increase the light emission amount of the light emission than the value.

  An image pickup apparatus according to a third invention includes, in the second invention, an aperture that restricts a light beam of the photographing optical system and an aperture control unit that controls an aperture value corresponding to the aperture opening. In the second light emission mode, the control unit controls the aperture value at the time of pre-emission to an aperture value larger than the aperture value in the first light emission mode.

  In the imaging device according to a fourth aspect of the present invention, in the first or second aspect, the light emission mode setting unit is configured to perform the second light emission mode when the imaging device is set to a photographing mode suitable for underwater photographing. Set to.

An image pickup apparatus according to a fifth aspect of the present invention includes, in the first or second aspect of the invention, an image pickup unit that converts a subject image into image data and outputs the image data, and the light emission mode setting unit is controlled by the flash light emission unit. performs detection for preliminary light emission, based on the image data acquired during this mode detection preflash, you determine whether the second light-emitting mode.

  ADVANTAGE OF THE INVENTION According to this invention, the imaging device which can perform appropriate slave TTL dimming control reliably according to light emission from the imaging device side can be provided.

It is a figure which shows arrangement | positioning of the camera system which concerns on 1st Embodiment of this invention. 1 is a block diagram mainly showing an electrical configuration of a slave flash according to a first embodiment of the present invention. 1 is a block diagram mainly showing an electrical configuration of a camera according to a first embodiment of the present invention. It is a wave form diagram showing TTL operation at the time of slave mode setting in a camera system concerning a 1st embodiment of the present invention. It is a wave form diagram showing TTL operation at the time of slave mode setting in a camera system concerning a 1st embodiment of the present invention. It is a wave form diagram which shows the TTL operation | movement at the time of slave mode setting in the conventional camera system compared with the camera system which concerns on 1st Embodiment of this invention. It is a wave form diagram which shows the TTL operation | movement at the time of slave mode setting in the conventional camera system compared with the camera system which concerns on 1st Embodiment of this invention. It is a flowchart which shows the light emission control operation | movement of the camera which concerns on 1st Embodiment of this invention. It is a flowchart which shows the light emission control operation | movement of the camera which concerns on 1st Embodiment of this invention. It is a figure which shows the relationship of the light emission amount in the pre light emission amount table in the camera which concerns on 1st Embodiment of this invention. It is a figure which shows the relationship of the light emission quantity in the main light emission quantity table in the camera which concerns on 1st Embodiment of this invention. It is a flowchart which shows the light emission control operation | movement of the camera which concerns on 2nd Embodiment of this invention. It is a flowchart which shows the light emission control operation | movement of the camera which concerns on 2nd Embodiment of this invention. It is a wave form diagram which shows TTL operation | movement in the camera system which concerns on 3rd Embodiment of this invention. It is a flowchart which shows the light emission control operation | movement of the camera which concerns on 3rd Embodiment of this invention. It is a flowchart which shows the light emission control operation | movement of the camera which concerns on 3rd Embodiment of this invention.

  A preferred embodiment will be described below using a camera system including a camera to which the present invention is applied and a slave flash according to the drawings. FIG. 1 is a diagram showing the arrangement of cameras and slave flashes in the camera system according to the first embodiment of the present invention.

  The camera 100 includes a built-in flash 101 and can perform pre-flash and main flash toward the subject 300. A slave flash 200 </ b> A and a slave flash 200 </ b> B are disposed around the subject 300. The slave flashes 200A and 200B have flashes 201A and 201B and flash light receiving units 203A and 203B, respectively, which receive pre-flashes and main flashes from the flash 101 of the camera 100, and synchronize with these flashes. Flash fires.

  As described above, the camera 100 according to the present embodiment is configured so that the slave flashes 200A and 200B (the first ones) positioned outside in correspondence with the light emission of the flash 101 (corresponding to a part of the first flash device built in the imaging device). 2 corresponding to the flash device 2) can emit light.

  FIG. 2 is a block diagram showing details of the slave flashes 200A and 200B shown in FIG. In this embodiment, the slave flashes 200A and 200B are described as having the same configuration, but they may not have the same configuration. The slave flashes 200A and 200B include a flash 201, a flash light receiving unit 203, and a control unit 210.

  The flash 201 has a flash light emission tube, and starts flash emission and stops flash emission based on the emission control signal from the flash emission amount control unit 211. The flash light receiving unit 203 includes a light receiving element, and outputs a light reception signal corresponding to the light reception intensity to the light reception control unit 215. Therefore, when the pre-flash or the main flash is received from the flash 101 of the camera 100, the flash light receiving unit 203 outputs a light reception signal corresponding to the light emission to the light reception control unit 215.

  The control unit 210 includes a flash light emission amount control unit 211, a flash light emission amount calculation unit 213, and a light reception control unit 215. The light reception control unit 215 outputs a light reception signal corresponding to the light reception intensity received by the flash light reception unit 203 to the flash light emission amount control unit 211 and the flash light emission amount calculation unit 213.

  The flash light emission amount control unit 211 outputs an external flash side light emission control signal to the flash 201 in accordance with a signal from the light reception control unit 215 or the flash light emission amount calculation unit 213. When the slave flash 200A, 200B is set to an operation mode in which slave TTL dimming control is performed, the flash light emission amount control unit 211 outputs an H signal when the light reception signal from the light reception control unit 215 is equal to or greater than a predetermined value. If it is less than the predetermined value, the L signal is output to the flash 201. The flash 201 starts to emit light in synchronization with the rise from the L signal to the H signal from the flash emission amount control unit 211, and the flash 201 stops emitting in synchronization with the fall from the H signal to the L signal ( (See FIG. 4 described later).

  Further, when the flashes 200A and 200B are not set to the operation mode for performing the slave TTL dimming control, an operation as a normal external flash is performed. That is, the flash light amount control unit 211 causes the flash 201 to pre-emit with a predetermined pre-emission light amount, and the flash light receiving unit 203 receives the reflected light from the subject. The light reception control unit 215 outputs a light reception signal corresponding to the light reception intensity received by the flash light reception unit 203 to the flash light emission amount calculation unit 213. The flash light emission amount calculation unit 213 calculates the light emission amount of the main light emission of the flashes 200A and 200B based on the light reception signal from the light reception control unit 213, and outputs the light emission amount to the flash light emission amount control unit 211. The flash light emission amount control unit 211 controls the light emission amount of the flash 201 based on the light emission amount from the flash light emission amount calculation unit 213 and executes the main light emission.

  FIG. 3 is a block diagram showing details of the camera 100 shown in FIG. The taking lens 111 is an optical lens for forming a subject image of the subject 300, and the lens control unit 131 moves the focus lens and the zoom lens in the optical axis direction. An aperture 113, an ND filter 115, and a shutter 117 are disposed on the optical axis of the photographing lens 111, and an imaging element 119 is disposed on the optical axis of the photographing lens 111 and in the vicinity of the image formation position of the optical image. Has been.

  The aperture 113 has a variable aperture and controls the light beam of the photographing optical system. The aperture controller 129 controls the aperture value corresponding to the aperture opening. The diaphragm 113 adjusts the amount of the subject luminous flux that has passed through the photographic lens 111 based on a control signal from the diaphragm controller 129. The ND filter 115 is an optical filter that reduces the amount of transmission of the subject luminous flux, and can move forward and backward on the optical axis of the photographing lens 111 based on a control signal from the ND control unit 127.

  At the time of shooting, the shutter 117 allows the subject light flux to pass for a time determined by the shutter time based on a control signal from the shutter control unit 125. Further, when the live view is displayed, it is in an open state.

  In the present embodiment, the aperture 113, the ND filter 115, and the shutter 117 are arranged on the optical axis of the photographing lens 111 to perform exposure control, but some of these elements are omitted. Exposure control may be performed. Further, the shutter time may be controlled by an electronic shutter in the image sensor 119 instead of the shutter 117.

  The image sensor 119 photoelectrically converts the subject image formed by the photographing lens 111 and outputs an image signal to the image processing unit 121. The imaging control unit 123 performs control such as charge accumulation and reading of the imaging element 119 based on a control signal from the control unit 150. The image processing unit 121 receives an image signal from the image sensor 119, performs various image processing such as amplification processing, AD conversion processing, OB processing, and gamma processing, and outputs image processed image data to the control unit 150. The imaging element 119, the image processing unit 121, and the imaging control unit 123 function as an imaging unit that converts a subject image into image data and outputs the image data.

  In addition to the image processing unit 121, the imaging control unit 123, the shutter control unit 125, the ND control unit 127, the aperture control unit 129, and the lens control unit 131, the control unit 150 includes a flash control unit 103, a recording unit 133, An audio processing unit 135, a display unit 141, and an operation unit 143 are connected.

  The flash control unit 103 outputs light emission control signals such as light emission start and light emission stop to the flash 101 based on the control signal from the control unit 150, and the flash 101 applies to the subject 300 based on the light emission control signal. Flash light is emitted. The flash 101 has a function as a flash light emitting unit that emits flash light, and the flash control unit 103 has a function as a flash light emission control unit that controls light emission of the flash light emitting unit. Functions as a flash device.

  The recording unit 133 includes a recording medium, and records the image data output from the image processing unit 121 on the recording medium. Also, the audio data output from the audio processing unit 135 at the time of recording the image data can be recorded on the recording medium.

  The audio processing unit 135 is connected to a microphone 137 and a speaker 139, processes an audio signal collected by the microphone 137, records it in the recording unit 133, and processes audio data recorded in the recording unit 133. Then, playback is performed from the speaker 139.

  The display unit 141 includes a display member such as a liquid crystal panel, and performs live view display for confirming a subject, reproduction display of an image recorded in the recording unit 133, display of a menu screen, and the like. The operation unit 143 includes various operation members such as a release button and a menu button. The operation unit 143 detects the operation state of these operation members and outputs the operation state to the control unit 150.

  The control unit 150 includes a slave mode determination control unit 151, a flash emission amount control unit 153, an AF control unit 155, and an AE control unit 157. In addition, a CPU (Central Processing Unit) and a non-volatile memory (not shown) are provided in the control unit 150, and the CPU performs overall control of the camera 100 according to a program stored in the non-volatile memory. Each unit such as the slave mode determination control unit 151 may be configured by hardware, or may be configured by software by a CPU and a program.

  The slave mode determination unit 151 determines whether or not the slave mode performs flash emission by slave TTL light control in cooperation with the slave flashes 200A and 200B. The slave mode determination unit 151 is capable of setting a first flash mode that does not use the second flash device (supported by the slave flash 200A and the like) and a second flash mode that uses the second flash device. It functions as a part. The slave mode is determined as follows.

(1) When the slave mode (slave TTL) is set from the flash emission modes on the menu screen of the camera 100 or the like.
(2) On the menu screen of the camera 100 or the like, “with slave flash” is set from the accessory setting mode.

(3) When the underwater shooting mode is set on the menu screen of the camera 100 or the like. In the case of underwater shooting, shooting using a slave flash is performed because the surroundings are dark.
(4) A case where a water pressure sensor is provided in the camera 100 and the water pressure sensor determines that the water is underwater. As described above, in the case of shooting underwater, shooting using a slave flash is performed because the surroundings are dark.

(5) When it is determined that the slave flash is used based on the image data from the image sensor 119 during the pre-flash. That is, when the flash 101 of the camera 100 pre-flashes for slave flash detection and the slave flashes 200A and 200B emit light in response to the pre-flash, the image data from the image sensor 119 is affected by the flash 101 emission. Since there is a difference between the number of imaging lines (bright lines) and the number of imaging lines (bright lines) affected by light emission from the slave flashes 200A and 200B, the determination is made based on the difference. This determination method will be described later with reference to FIGS. 12, 13A, and 13B.

  In the slave mode (slave TTL dimming control), the flash light emission amount control unit 153 calculates the light emission amount during the main light emission of the flash 101 using image data based on the output of the image sensor 119 during the pre-light emission. Then, the light emission amount of the flash 101 is controlled via the flash control unit 103. In addition, the pre-emission amount and the like in the slave mode are also controlled (in this embodiment, a predetermined emission amount (see S9, S11 in FIG. 8A, FIG. 9)). When the auto mode or manual mode other than the slave mode is set, the flash light emission amount control unit 153 controls the light emission amount according to each mode.

  The AF control unit 155 uses the image data based on the output of the image sensor 119 to extract a contrast signal, and the focus lens in the photographing lens 111 via the lens control unit 131 so that the contrast signal reaches a peak. Control the position of the.

  The AE control unit 157 obtains the subject brightness value using the image data based on the output of the image sensor 119, and based on the subject brightness value, the aperture value for proper exposure, the presence / absence of the ND filter, the shutter speed, and the ISO sensitivity. And the like, and control is performed via the shutter control unit 125, the ND control unit 127, the aperture control unit 129, and the like based on the calculation result.

  When the second light emission mode (the light emission mode using the second flash device (supported by the slave flash 200A or the like)) is set, the control unit 150 performs the pre-light emission operation prior to the main light emission. In addition, the flash emission control unit controls the pre-emission amount to be larger than the pre-emission amount when the first emission mode (emission mode not using the second flash device) is set. (See S9 in FIG. 8A).

  In addition, when the second light emission mode (the light emission mode using the second flash device (supported by the slave flash 200A or the like)) is set, the controller 150 controls the flash light emission control unit for the first light emission. Control is performed so that the light emission amount of the main light emission becomes larger than the minimum value of the light emission amount of the main light emission when the first light emission mode (the light emission mode not using the second flash device) is set (S17 in FIG. 8B). reference).

  Next, the operation of slave TTL light control in the camera system according to the present embodiment will be described using FIG. In FIG. 4, the inside of the broken line T1 is the pre-light emission operation, and the inside of the broken line T2 is the main light emission operation.

  The first level (uppermost level) in FIG. 4 shows a camera-side light emission control signal output from the flash control unit 103 in the camera 100, and the second level shows a light emission intensity waveform due to the light emission operation of the flash 101 of the camera 100. Show. The third stage shows the external flash side emission control signal output from the flash emission amount control unit 211 of the slave flashes 200A and 200B, and the fourth stage (bottom stage) is the external flash side in the slave flashes 200A and 200B. The light emission intensity waveform by light emission operation is shown.

  The camera-side light emission control signal changes from the L level to the H level at time t1 during the pre-light emission operation, and changes from the H level to the L level at time t3. When the camera-side light emission control signal changes from the L level to the H level, the flash 101 in the camera 100 starts to emit light, and the light emission intensity exceeds the predetermined level P at time t2. When the camera side light emission control signal changes from the H level to the L level, the flash 101 stops emitting light, and the light emission intensity becomes lower than the predetermined level P at time t4.

  When the flash 101 starts emitting light, in the slave flashes 200A and 200B, the flash light receiving unit 203 receives the reflected light from the subject 300 due to the light emission of the flash 101, and sends a signal according to the received light amount to the light receiving control unit 215. Output to. The light reception control unit 215 outputs a signal corresponding to the flash light emission amount control unit 211 when the light reception amount reaches a level corresponding to the predetermined level P which is the light emission intensity at time t2. As a result, the external flash-side light emission control signal output from the flash light emission amount control unit 211 changes from the L level to the H level at time t2. Further, the flash-side light emission control signal changes from the H level to the L level at time t4 by an operation opposite to that at time t2 by stopping the light emission of the flash 101. When the external flash side light emission control signal changes from the L level to the H level, the slave flashes 200A and 200B start to emit light, and when the external flash side light emission control signal changes from the H level to the L level, the slave flashes 200A and 200B stop emitting light.

  Also in the main light emission, as shown in the broken line T2 in FIG. 4, the camera side light emission operation is performed in accordance with the camera side light emission control signal in the same manner as the pre-light emission operation. A side light emission control signal is output, and an external flash side light emission operation is performed.

  As described above, in the slave TTL dimming control in the present embodiment, the slave flashes 200A and 200B start and stop the light emission in synchronization with the start and stop of the light emission from the camera 100. However, if the light emission time for controlling the light emission amount is short, the light receiving element in the flash light receiving unit 203 on the external flash side may not receive the light emission stop timing and may not be able to stop the light emission. Therefore, in the present embodiment, when the slave mode (slave TTL dimming control) is set, the pre-emission emission on the camera 100 side is compared with the emission amount when the slave flashes 200A and 200B are not used. I try to increase the amount. In the case of the main light emission, the light emission amount is set larger than the minimum value of the main light emission amount on the camera 100 side.

  This light emission amount control will be described with reference to FIG. The pre-emission amount in the camera 100 is determined by the emission time. In the present embodiment, when the slave mode is set, the pre-emission time is longer than the pre-emission time in the normal TTL dimming control, and the external flash Side (slave flash side) emission stop timing can be taken sufficiently. That is, the pre-flash time during normal TTL dimming is from time t1 to time t3a, but when the slave mode is set, the timing of time t3 at which the light emission is stopped is later than time t3a. (Refer to the broken line A in FIG. 5). For this reason, in the external flash side light emission control signal, a sufficient time from the light emission start (time t2) to the light emission stop (time t4) can be secured, and failure of the light emission stop can be prevented.

  In addition, even during main light emission, the light emission time is longer than the minimum light emission time (light emission amount) during normal main light emission, so that the light emission stop timing on the external flash side can be sufficiently taken. That is, the minimum light emission time during normal main light emission is from time t6 to t9a, and when the slave mode is set, the timing of time t9 at which light emission is stopped is set to be later than time t9a. (Refer to the broken line B in FIG. 5). For this reason, in the external flash side light emission control signal, a sufficient time from the light emission start (time t7) to the light emission stop (time t8) can be secured, and failure of the light emission stop can be prevented.

  Thus, in the present embodiment, when the slave mode is set, a lower limit value is provided for the light emission time (light emission amount) on the camera side, and a light emission time longer than the lower limit value is ensured. A case where such setting is not performed will be described with reference to FIGS.

  FIG. 6 shows a case where the pre-emission time on the camera 100 side is the minimum pre-emission amount during normal TTL light control (when the emission stop time t13 is earlier than the emission stop time t3a). In this case, in the slave flashes 200A and 200B, it cannot be detected that the light emission intensity becomes smaller than the predetermined amount P at t14 corresponding to the light emission completion timing of the flash 101 at the light emission stop time t14. For this reason, as indicated by a broken line C, the pre-flash operation on the slave flash 200A, 200B side cannot be stopped and full flash is generated (the slave flash side forcibly outputs a flash stop signal at time t5). Since full light emission occurs at the time of pre-light emission, as indicated by a broken line D during main light emission, there is no light emission energy in the slave flashes 200A and 200B, and main light emission cannot be performed, and the camera 100 takes an under-exposure image. .

  FIG. 7 shows a case where the main light emission time on the camera 100 side is the minimum light emission amount of the main light emission in the normal TTL light control (when the light emission stop time t29 is earlier than the light emission stop time t9a). In this case, in the slave flashes 200A and 200B, it cannot be detected that the light emission intensity becomes smaller than the predetermined amount P at time t28 corresponding to the light emission completion timing of the flash 101 at the light emission stop time t29. For this reason, as indicated by the broken line E, the main light emission operation on the slave flash 200A, 200B side cannot be stopped and full light emission occurs (the slave flash side forcibly outputs a light emission stop signal at time t30). Since the slave flashes 200A and 200B cannot stop the light emission when the flash 101 is stopped during the main light emission, the camera 100 captures an overexposed image.

  Next, the operation of light emission control in the present embodiment will be described using the flowcharts shown in FIGS. 8A and 8B. This flow is executed by the control unit 150 (the same applies to FIGS. 11A, 11B, 13A, and 13B described later). As described above, the control unit 150 includes a CPU and a non-volatile memory (not shown), and the CPU controls each unit in the camera 100 according to a program stored in the non-volatile memory. Execute this flow.

  In the light emission control flow shown in FIG. 8A, first, it is determined whether or not the 2nd release is on (S1). When the photographer observes the live view image displayed on the display unit 141 and decides the composition, the release button as one of the operation units 143 is fully pressed. Since the 2nd release switch is turned on when the release button is fully pressed, it is determined in this step whether or not the 2nd release switch is turned on. If the result of this determination is that the 2nd release switch is not on, a standby state is awaited until the 2nd release switch is turned on.

  If the 2nd release is turned on as a result of the determination in step S1, it is next determined whether or not flash light is emitted (S3). Here, it is determined whether or not the flash 101 emits light. The light emission of the flash 101 is determined based on the shooting mode, subject brightness, and the like. If the result of this determination is that flash emission is not performed, the process proceeds to step S27 to perform a shooting operation.

  If the result of determination in step S <b> 3 is that there is flash emission, then a steady light metering operation is performed (S <b> 5). Here, the AE control unit 157 acquires subject luminance information based on the image data.

  Once the steady light metering operation is performed, next, slave TTL determination is performed (S7). Here, the slave mode determination unit 151 determines whether or not the slave mode is set. If the slave mode is set as a result of this determination, the slave TTL pre-emission amount (emission amount A) is determined (S9). If the result of determination in step S7 is that slave mode is not set, a normal TTL pre-emission amount (emission amount B) is determined (S11).

  The pre-emission amount A and the pre-emission amount B are read from a pre-emission light emission table stored in a nonvolatile memory (not shown) in the control unit 150. The pre-emission amount A and the pre-emission amount B are uniform values, and can be expressed by the emission amount, guide number (Gno), or emission time. As shown in FIG. 9, pre-emission amount A> pre-emission amount The quantity B is related. That is, the pre-emission amount A when the slave mode is set is larger than the pre-emission amount B when the slave mode is not set (normal TTL).

  Once the pre-emission amount is determined in step S9 or S11, pre-emission and photometry are then performed (S13). In this step, the flash 101 is caused to perform pre-emission with the pre-emission amount determined in step S9 or S11 (slave flashes 200A and 200B are also pre-emission in synchronization with this pre-emission), and at this time, the AE control unit 157 measures the reflected light returned from the subject 300 based on the image data.

  Once the pre-flash and metering operations have been performed, next, slave TTL determination is performed as in step S7 (S15). If the result of this determination is slave mode (slave TTL), a slave TTL main light emission amount calculation table (table C) is determined (S17). On the other hand, if the result of determination in step S15 is not slave mode (slave TTL), a normal TTL light emission amount calculation table (table D) is determined (S19).

  Tables C and D are tables for obtaining the light emission amount during the main light emission based on the photometric information during the pre-light emission. As shown in FIG. 10, this light emission table has a range in light emission amount, guide number (Gno), and light emission time. The light emission table C has a larger light emission amount than the light emission table D on the minimum light emission amount side (minimum Gno side, minimum light emission time side). This is because, as described above, in the slave mode and the main light emission, the main light emission amount on the camera 100 side is set larger than the minimum light emission amount. The light emission table C has a light emission amount smaller than that of the light emission table D on the maximum light emission amount side (maximum Gno side, maximum light emission time side). On the maximum side of the light emission table C, the light emission table D may be the same as the light emission table D. However, the light emission table C is reduced in consideration of the fact that more light emission energy is used during pre-emission.

  If the main light emission amount calculation table is determined in step S17 or S19, next, the main light emission amount calculation is performed (S21). In this step, the light emission amount during the main light emission is obtained from the main light emission amount calculation table or the like based on the photometric result during the pre-light emission operation performed in step S13.

  When the actual light emission amount calculation is performed, or when the result of determination in step 3 is that there is no flash emission, a photographing operation is performed (S27). In this step, the main flash is performed by the flash 101 in the case of the flash emission (the main flash of the slave flashes 200A and 200B in the slave mode), and the image data based on the image signal of the image sensor 119 is recorded in the recording unit 133. To record. When the photographing operation is finished, the light emission control flow is finished.

  As described above, in the first embodiment of the present invention, in the slave mode, the light emission amount (light emission time) in the camera 100 during the pre-light emission and the main light emission is larger than the predetermined light emission amount (light emission time). To be (longer). For this reason, on the slave flash 200A, 200B side, the pre-flash or the main flash can be surely stopped, and an underexposed or overexposed photographed image can be prevented.

  Next, a second embodiment of the present invention will be described with reference to FIG. In the first embodiment of the present invention, pre-emission is performed while the aperture 113 is open in the slave mode, but in the second embodiment, the aperture control is performed during pre-emission in the slave mode. . This is to prevent the amount of reflected light from becoming excessive because the pre-emission amount is increased in the slave mode.

  The configuration of the second embodiment is the same as that of the first embodiment, and only the flowchart shown in FIGS. 8A and 8B is replaced with the flowchart shown in FIGS. 11A and 11B. Further, the flowcharts shown in FIGS. 11A and 11B are different from the flowcharts shown in FIGS. 8A and 8B in that steps S10, S12, S23, S25, and S26 are added. Therefore, this difference will be mainly described.

  11A is entered, steps S1 to S5 are executed, and if the result of determination in step S7 is slave mode, the slave TTL pre-emission amount (emission amount A) is determined (S9), and then Then, narrowing-down control is performed (S10). Here, the aperture control unit 129 performs aperture control of the aperture 113 so that a predetermined aperture value is obtained. Note that the ND filter 115 may be inserted into the optical path to reduce the light amount instead of or together with the narrowing control.

  If the result of determination in step S7 is not slave mode, a normal TTL pre-emission amount (emission amount B) is determined (S11), and no narrowing control is performed (S12). In this case, the diaphragm 113 remains open at the time of pre-emission.

  Once the processing of step S10 or S12 is performed, pre-flash and photometric operations are then performed (S13). In this step, in the slave mode, the camera 100 performs pre-light emission and photometry operation with the aperture 113 closed, and when not in the slave mode, the camera 100 performs pre-light emission and photometry operation with the aperture 113 in the open aperture state. Do.

  When the pre-light emission and the photometric operation are performed, steps S15 to S21 are executed as in the flow shown in FIG. 8B. Once the main light emission amount calculation is performed in step S21, it is next determined whether or not the light emission amount is the minimum light emission amount (S23). Here, it is determined whether or not the main light emission amount calculated in step S21 is the minimum light emission amount. As the minimum light emission amount, a value stored in a light emission table for main light emission as shown in FIG. 10 is read and used. In the main light emission amount calculation process, when the main light emission amount is calculated to be smaller than the minimum light emission amount as a result of the calculation, the main light emission amount is rounded to the minimum light emission amount.

  If the result of determination in step S23 is the minimum light emission amount, narrowing-down control is performed as in step S10 (S25). In this step, the aperture control unit 129 controls the aperture 113 to the same aperture value (see S10) as during pre-emission. On the other hand, if the result of determination in step S23 is not the minimum light emission amount, no narrowing control is performed (S26). If the processing in step S25 or S26 is performed, or if the result of determination in step S3 is that there is no flash emission, then the shooting operation is performed (S27), and if the shooting operation is performed, the flow of light emission control ends. .

  As described above, in the second embodiment of the present invention, in the slave mode, the diaphragm 113 is narrowed during pre-light emission or main light emission. Also in the present embodiment, in the slave mode, the light emission amount (light emission time) in the camera 100 at the time of pre-light emission and main light emission is made larger (longer) than a predetermined light emission amount (light emission time). As a result, the amount of pre-emission or main emission is increased to prevent overexposure.

  Further, in the present embodiment, when the obtained main light emission amount is the minimum light emission amount, the aperture control of the diaphragm 113 is performed (S25). That is, the aperture control unit sets the aperture value (FNO) at the time of pre-emission in the first emission mode (emission mode not using the slave flash) in the second emission mode (emission mode using the slave flash). The aperture value (FNO) is controlled to be larger than the aperture value (FNO). For this reason, it is possible to prevent overexposure.

  Next, 3rd Embodiment of this invention is described using FIG. 12, FIG. 13A, and 13B. In this embodiment, when the slave mode determination control unit 151 determines the setting of the slave mode, whether or not shooting is performed using the slave flash based on the image data from the image sensor 119 during the slave flash detection pre-flash. If the result of the determination is that shooting is performed using a slave flash, the slave mode is automatically set.

  First, determination of whether or not the slave flash is used will be described with reference to FIG. The image sensor 119 in this embodiment has a rolling shutter. In other words, charge accumulation and readout are sequentially performed for each line. In FIG. 12, the first stage (uppermost stage) shows the imaging operation timing, the second stage is the exposure timing, the third stage is the light emission timing of the flash 101 built in the camera 100, and the fourth stage (lowermost stage) is. Indicates the flash timing of the slave flash. The second stage START indicates the charge accumulation start timing for each line in the rolling shutter operation of the image sensor 119, and END indicates the charge accumulation end timing for each line.

  Now, it is assumed that the camera 100 performs shooting while emitting light in synchronization with the slave flashes 200A and 200B. The light emission period of the flash 101 of the camera 100 at this time is between time t41 and time t42 as shown in the third row of FIG. 12, and at this time, pixels in the range R of the flash 101 are on the image sensor 119. The exposure is performed by the amount of light (the imaging lines in the range R are exposed brightly), and the number of imaging lines in the range R is A.

  In addition, the light emission period of the slave flashes 200A and 200B is between time t41 and time t43 as shown in the fourth stage of FIG. 12. At this time, in the image sensor 119, pixels in the range S are slave flashes 200A and 200B. (The imaging lines in the range S are exposed brightly), and the number of imaging lines in the range S is B.

  Therefore, when the flash 101 of the camera 100 is made to emit light prior to the pre-emission, and the image line exposed by the flash light appears only in the range R in the image data from the image sensor 119, the slave flash is not arranged around. This is the case (normal TTL dimming control mode). On the other hand, when the image line exposed by the flash light appears in the range S in the image data from the image sensor 119, the slave flash is disposed around (slave mode).

  The configuration of the third embodiment is the same as that of the first embodiment, and only the flowchart shown in FIGS. 8A and 8B is replaced with the flowchart shown in FIGS. 13A and 13B. 13A and 13B is different in that step S7 is replaced with steps S6 and 8 in the flowchart of FIG. 8A, and steps S23, 25, and 26 are added similarly to the flowchart of FIG. 11B. Therefore, the steps S6 and S8, which are different points, will be mainly described.

  After entering the flow shown in FIG. 13A and executing steps S1 to S3 and performing a steady light metering operation in step S5, a slave flash detection pre-flash metering operation is then performed (S6). In this step, as described with reference to FIG. 12, in order to detect whether or not the slave flashes 200A and 200B exist in the vicinity, the slave flash detection pre-flash is performed on the flash 101 of the camera 100. Let it be done.

  If the pre-flash photometric operation for slave flash detection is performed in step S6, then the number of lines is determined (S8). Here, the number of imaging lines to be exposed described in FIG. 12 is detected, and it is determined whether or not the number of imaging lines is greater than A.

  If the result of determination in step S <b> 8 is that the number of imaging lines is exposed to more than A, the slave flashes 200 </ b> A and 200 </ b> B emit light in synchronization with the pre-emission of the flash 101. In this case, since the slave mode is set, the slave TTL pre-emission amount (emission amount A) is determined (S9). On the other hand, when the number of imaging lines is A or less, it is a case where only the flash 101 of the camera 100 emits light and there is no slave flash around. In this case, the normal TTL pre-emission amount (emission amount B) is determined (S11).

  When the pre-emission amount is determined in step S9 or S11, pre-emission and photometry operation are performed (S13), and slave TTL determination is performed (S15). The determination of slave TTL in step S15 uses the determination result in step S8. That is, when the exposure is performed on the lines larger than the number A of lines, the slave TTL main light emission amount calculation table is determined (S17). A TTL main light emission amount calculation table is determined. When the main light emission amount calculation table is determined, step S21 and the subsequent steps are executed. Since these steps are the same as those in FIGS. 8B and 11B, detailed description thereof is omitted.

  As described above, in the third embodiment of the present invention, prior to pre-emission, the flash emission unit performs pre-emission for mode detection (see S6), and based on the image data acquired at the time of pre-emission for mode detection. Then, it is determined whether or not the mode uses the slave flash (see S8), and the slave mode is set based on the determination result (S9 and S17). For this reason, in the present embodiment, it is possible to accurately and automatically determine whether there is a slave flash around.

  As described above, in each embodiment of the present invention, when the second light emission mode (light emission mode when using the slave flash) is set, the pre-light emission operation prior to the main light emission is performed. The flash emission control unit makes the pre-emission amount larger than the pre-emission amount when the first emission mode (emission mode not using the slave flash) is set (S9 in FIG. 8A). (See FIG. 9 etc.) Further, when the second light emission mode is set, during the main light emission, the flash light emission control unit performs the main light emission more than the minimum value of the main light emission amount when the first light emission mode is set. Is increased (see S17 in FIG. 8B, FIG. 10, etc.). For this reason, it is possible to perform slave TTL dimming control that ensures appropriate exposure according to light emission from the imaging device side.

  In each embodiment of the present invention, the flash 101 is built in the camera 100 as the first flash device. However, the present invention is not limited to this. For example, a type in which a flash is externally attached to the camera 100 may be used. In each embodiment of the present invention, the light emission amount is controlled in both pre-light emission and main light emission. However, only one of them may be used.

  In each embodiment of the present invention, the pre-emission light emission amount table shown in FIG. 9 is only one of the pre-emission amounts A in the slave TTL mode (see S9 in FIG. 8A). May be prepared so that the photographer can arbitrarily select it. Further, in each embodiment of the present invention, the main light emission amount table shown in FIG. 10 is only one of the tables C in the slave TTL mode (see S17 in FIG. 8B). May be prepared so that the photographer can arbitrarily select it.

  In the present embodiment, the digital camera is used as the photographing device. However, the camera may be a digital single-lens reflex camera or a compact digital camera, and may be used for moving images such as video cameras and movie cameras. It may be a camera, or may be a camera built into a mobile phone, a smart phone, a personal digital assistant (PDA), a game machine, or the like. In any case, the present invention can be applied to any device for photographing that can be used in combination with a slave flash.

  Of the techniques described in this specification, the control mainly described in the flowchart is often settable by a program and may be stored in a recording medium or a recording unit. The recording method for the recording medium and the recording unit may be recorded at the time of product shipment, may be a distributed recording medium, or may be downloaded via the Internet.

  In addition, regarding the operation flow in the claims, the specification, and the drawings, even if it is described using words expressing the order such as “first”, “next”, etc. It does not mean that it is essential to implement in this order.

  The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, you may delete some components of all the components shown by embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

DESCRIPTION OF SYMBOLS 100 ... Camera, 101 ... Flash, 103 ... Flash control part, 111 ... Shooting lens, 113 ... Aperture, 115 ... ND filter, 117 ... Shutter, 119 ... Image sensor 121, image processing unit 123, imaging control unit 125, shutter control unit, 127 ND control unit, 129 aperture control unit 131 lens control unit ,... 133, recording unit, 135, audio processing unit, 137, microphone, 139, speaker, 141, display unit, 143, operation unit, 150, control unit, 151 ... Slave mode determination unit, 153 ... Flash light emission amount control unit, 155 ... AF control unit, 157 ... AE control unit, 200A ... Slave flash, 200B ... Slave flash 201 ... Flash, 203 ... flash light receiving unit, 210 ... controller, 211 ... flash amount control unit, 213 ... flash amount calculating section, 215 ... light control unit

Claims (5)

In an imaging device capable of emitting light from a second flash device located outside in correspondence with light emission from a built-in first flash device,
A flash light emitting part for flashing;
A flash emission control unit for controlling emission of the flash emission unit;
A first flash device having:
A light emission mode setting unit capable of setting a first light emission mode that does not use the second flash device and a second light emission mode that uses the second flash device;
Comprising
When the second light emission mode is set, when performing the pre-light emission operation prior to the main light emission, the flash light emission control unit stops the light emission of the pre-light emission when the first light emission mode is set. An imaging apparatus characterized in that the pre-emission emission stop time is delayed from the time, and the pre-emission emission amount is made larger than the pre-emission emission amount. In an imaging device capable of emitting light from a second flash device located outside in correspondence with light emission from a built-in first flash device,
A flash light emitting part for flashing;
A flash emission control unit for controlling emission of the flash emission unit;
A first flash device having:
A light emission mode setting unit capable of setting a first light emission mode that does not use the second flash device and a second light emission mode that uses the second flash device;
Comprising
When the second light emission mode is set, during the main light emission, the flash light emission control unit stops the light emission of the main light emission from the light emission stop time of the main light emission when the first light emission mode is set. An imaging apparatus characterized in that the light emission amount of main light emission is made larger than the minimum value of light emission amount of main light emission when the time is delayed and the first light emission mode is set . An aperture that limits the luminous flux of the photographic optical system;
A diaphragm control unit for controlling an aperture value corresponding to the aperture of the diaphragm above,
Have
3. The aperture control unit according to claim 2, wherein, in the second light emission mode, the aperture control unit controls the aperture value at the time of pre-emission to an aperture value larger than the aperture value in the first light emission mode. Imaging device.   The imaging device according to claim 1 or 2, wherein the light emission mode setting unit sets the second light emission mode when the imaging device is set to a photographing mode suitable for underwater photographing. An imaging unit that converts the subject image into image data and outputs the image data;
The light emission mode setting unit performs pre-light emission for mode detection by the flash light emission unit, and determines whether or not the second light emission mode is based on the image data acquired at the time of the pre-light emission for mode detection. The imaging apparatus according to claim 1, wherein the imaging apparatus is characterized.

Images