JP2010114600A - Camera system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a camera system for easily obtaining a confirmation image of the effect of flash even when using a multiple lamp flash unit. <P>SOLUTION: When a release operation is performed during a simulation mode, data for imaging required to prepare a simulation image is passed from a camera 100 to external flash units 200a, 200b and 200c. Thereafter, after a quick return mirror is moved to an up position, imaging by an imaging element 119 is executed so as to be synchronized with light emission by the respective external flash units 200a, 200b and 200c, and imaging by the imaging element 119 is executed so as to be synchronized in the state that all the external flash units 200a, 200b and 200c are not emitting light thereafter. Images obtained through the imaging element 119 are preserved in an SDRAM 124. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a camera system that can perform photographing using a plurality of flash devices.

  Multi-flash photography is known in which two or more flash devices are arranged around a subject and photographing is performed in synchronization with light emission of each flash device. In such multi-flash photography, in recent years, it has become possible to control each flash device by wireless communication. In such multi-flash photography, it is possible to freely perform lighting that erases shadows behind the subject or intentionally shades the subject. However, in multi-flash photography, the placement of each flash unit and the balance of the amount of emitted light have a large effect on the final image quality. It is considered important to have experience.

As a technique for making up for the lack of experience of the photographer, for example, Patent Document 1 proposes a technique for enabling the effect of flash photography to be confirmed before actual photography. In Patent Document 1, a preliminary light emission image obtained by preliminarily emitting a flash device and a difference image of a steady light image obtained without performing preliminary light emission are created, and a predetermined image is obtained from the difference image and the constant light image. An image corresponding to the case of flash photography with the amount of emitted light is appropriately combined and displayed.
JP 2006-303967 A

  Here, the technique of Patent Document 1 assumes a case where the flash device has one light. That is, if the technique of Patent Document 1 is applied as it is to a multi-flash device as it is, it is difficult to quickly shoot because it is relatively complicated to acquire an image as a basis for synthesis.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a camera system that can easily acquire a confirmation image of a flash effect even when a multi-flash device is used.

  In order to achieve the above object, the camera system according to the first aspect of the present invention individually controls a plurality of light emitting devices that emit light to a subject, and whether or not each of the plurality of light emitting devices emits light. A light emission control unit, an imaging unit that outputs a light flux from the subject as an image, and a part of a series of sequences that controls the imaging unit to continuously operate and continuously operate the imaging unit. A control unit that controls the light emission control unit so that each of the plurality of light emitting devices emits light independently in synchronization with the operation of the plurality of light emitting devices, and from the imaging unit when each of the plurality of light emitting devices emits light alone. The image processing apparatus includes: a storage unit that stores each output image and an image output from the imaging unit when all of the plurality of light-emitting devices do not emit light.

  In order to achieve the above object, the camera system according to the second aspect of the present invention includes a plurality of light emitting devices that emit light to a subject, and whether or not each of the plurality of light emitting devices emits light and the amount of light emitted. A light emission control unit that controls the light emission, an imaging unit that outputs the light flux from the subject as an image, and the light emission control unit that controls each of the plurality of light emitting devices to emit light independently in one shooting sequence. The control unit that operates the imaging unit while controlling the light emission control unit so as to operate the imaging unit in synchronization with each light emission and not to cause all the light emitting devices to emit light, and the plurality of light emitting devices A plurality of images respectively output from the imaging unit when each of the plurality of light emitting devices emits light alone, and an image output from the imaging unit when not emitting all of the plurality of light emitting devices. And having a storage for storing.

  According to the present invention, it is possible to provide a camera system that can easily acquire a confirmation image of the flash effect even when a multi-flash device is used.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
First, a first embodiment of the present invention will be described. FIG. 1 is a diagram showing a configuration of a camera system according to the first embodiment of the present invention. The camera system includes a camera 100 having a function as a master flash device and a plurality of external flash devices 200a, 200b, and 200c having a function as a slave flash device. Here, the camera 100 and the external flash devices 200a, 200b, and 200c are connected so as to be capable of wireless communication. The wireless communication method between the camera 100 and the external flash devices 200a, 200b, and 200c is not particularly limited. However, in the following description, for example, flash light emission from the flash device built in the camera 100 is used. Communication.

  The camera 100 captures an image based on the luminous flux of the subject 300. Further, at the time of flash photography, the camera 100 also controls the operations of the external flash devices 200a, 200b, and 200c through wireless communication.

  The external flash devices 200a, 200b, and 200c are light emitting devices that are arranged around the subject 300 and illuminate the subject 300 in response to an instruction from the camera 100. Each of these external flash devices 200a, 200b, and 200c includes a light emitting unit 201 for emitting a flash and a light receiving unit 202 for receiving a flash from the camera 100.

  Here, the external flash devices 200a, 200b, and 200c are grouped. Of the three external flash devices, the external flash device 200a is a group A flash device, the external flash device 200b is a group B flash device, and the external flash device 200c is a group C flash device.

  In such a configuration, each external flash device is controlled to emit light according to the signal flash light from the camera 100. In the example of FIG. 1, one external flash device belongs to one group, but a plurality of external flash devices may be assigned to one group. In this case, the same flash control is performed for the external flash devices belonging to the same group. As will be described in detail later, the light emission control here includes control of whether or not each external flash device can emit light and control of the amount of light emitted when each external flash device emits light.

  As shown in FIG. 1, lighting of the subject 300 can be performed by appropriately arranging a plurality of external flash devices. For example, in FIG. 1, the external flash devices 200a and 200b are arranged obliquely in front of the subject 300, and the direction of each light emitting unit 201 is set so as to emit a flash toward a ceiling (not shown). Further, the external flash device 200c is disposed diagonally to the right of the subject 300. In such an arrangement, the flash from the external flash devices 200a and 200b is bounced on the ceiling and irradiated to the subject, and the subject 300 is caused by the flash emission of the external flash device 200a due to the flash emission of the external flash device 200c. Shadows are canceled out.

  FIG. 2 is a diagram illustrating a detailed configuration of the camera 100. A camera 100 illustrated in FIG. 2 is a single-lens reflex camera in which a photographing optical system including an interchangeable lens 101 and a camera body 110 can be interchanged.

  The interchangeable lens 101 includes a photographing optical system 102, an optical system driving mechanism 103, a diaphragm mechanism 104, a diaphragm driving mechanism 105, and a lens drive control circuit 106.

  The photographing optical system 102 is an optical system for condensing a light beam from the subject 300 and forming a subject image on the image sensor 119 in the camera body 110. The optical system driving mechanism 103 drives the lens included in the photographing optical system 102 in the optical axis direction (the arrow A direction in the drawing). By driving the lens in the photographic optical system 102, the focus, zoom state, and the like of the photographic optical system 102 are adjusted.

  The aperture mechanism 104 adjusts the amount of light that enters the image sensor 119 via the imaging optical system 102. The aperture drive mechanism 105 performs opening / closing drive of the aperture mechanism 104.

  The lens drive control circuit 106 is configured to be able to communicate with the body drive control circuit 131 in the camera body 110 via the communication terminal 107 when the interchangeable lens 101 is attached to the camera body 110. The lens drive control circuit 106 controls the optical system drive mechanism 103 and the diaphragm drive mechanism 105 in accordance with the control of the body drive control circuit 131. The lens drive control circuit 106 holds lens information such as the type of the interchangeable lens 101 and the focal length information of the photographing optical system 102, and the communication terminal 107 when the interchangeable lens 101 is attached to the camera body 110. The lens information is also transmitted to the body drive control circuit 131 via the.

  The camera body 110 includes a quick return mirror 111, a mirror driving mechanism 112, a focusing screen 113, a pentaprism 114, a photometric sensor 115, a photometric processing circuit 116, a distance measuring sensor 117, and a distance measuring processing circuit 118. , Imaging device 119, imaging circuit 120, preprocessing circuit 121, data bus 122, SDRAM control circuit 123, SDRAM 124, image processing circuit 125, video signal output circuit 126, LCD panel driving circuit 127, LCD panel 128, recording medium control circuit 129, recording medium 130, body drive control circuit 131, flash memory control circuit 132, flash memory 133, various switches 134, mirror switch 135, and switch detection circuit. 136 and the input / output circuit 137 , A communication circuit 138, a flash control circuit 139, and a built-in flash 140.

  The quick return mirror 111 is configured by a half mirror at the center, and has a reflection state in which the quick return mirror 111 is inserted into a position on the optical axis of the photographing optical system 102 and in a retracted state retracted from the position on the optical axis. It is. When the camera 100 is in the normal state, the quick return mirror 111 is inserted at a position on the optical axis of the photographing optical system 102 (hereinafter referred to as a down position) as shown in FIG. ing. At this time, the quick return mirror 111 transmits a part of the light beam incident on the camera body 110 via the interchangeable lens 101 and reflects a part thereof. A sub mirror 111 a is provided on the back surface of the half mirror portion of the quick return mirror 111. The sub mirror 111a reflects the light beam that has passed through the quick return mirror 111. When the camera 100 shifts to the photographing state, as shown in FIG. 3B, the quick return mirror 111 is retracted from the position on the optical axis of the photographing optical system 102 (hereinafter referred to as an up position). Moved to the evacuation state. At this time, the light beam incident on the camera body 110 via the interchangeable lens 101 enters the image sensor 119. The mirror drive mechanism 112 drives the quick return mirror 111.

  The focusing screen 113 is disposed in the direction in which the quick return mirror 111 reflects the light beam, and the light beam reflected by the quick return mirror 111 forms an image. The pentaprism 114 sets the image of the subject formed on the focusing screen 113 as an erect image. An eyepiece optical system 114 a is arranged in the light emitting direction of the pentaprism 114. The user can observe the subject image formed on the focusing screen 113 and inverted by the pentaprism 114 through the eyepiece optical system 114a.

  The photometric sensor 115 is disposed in the vicinity of the pentaprism 114, receives a part of the light beam emitted from the pentaprism 114, and outputs a signal corresponding to the received light amount. The photometric processing circuit 116 calculates subject luminance from the output of the photometric sensor 115, and outputs the calculated subject luminance to the body drive control circuit 131 via the input / output circuit 137.

  The distance measuring sensor 117 is a phase difference AF type distance measuring sensor arranged in the direction in which the sub mirror 111a reflects the light beam. The distance measuring sensor 117 includes a pupil division optical system that divides the light beam reflected by the sub-mirror 111a into pupils, a pair of line sensors that extract each of the light beams divided by the pupil division optical system as electric signals, and the like. Has been. The distance measurement processing circuit 118 calculates the focus deviation amount of the photographing optical system 102 from the output of the distance measurement sensor 117, and outputs the calculated focus deviation amount to the body drive control circuit 131 via the input / output circuit 137.

  The image sensor 119 converts a light beam from a subject imaged via the photographing optical system 102 into an electric signal (image signal) by photoelectric conversion. The imaging circuit 120 controls driving of the imaging element 119 in accordance with an instruction from the body drive control circuit 131 via the input / output circuit 137. The preprocessing circuit 121 performs analog processing such as noise removal and amplification on the image signal read from the image sensor 119 via the imaging circuit 120, and further converts the analog processed image signal into a digital signal (image data). Process.

  The data bus 122 is a transfer path for transferring various data such as image data obtained by the preprocessing circuit 121 and image data processed by the image processing circuit 125.

  The SDRAM control circuit 123 controls writing and reading of data to and from the SDRAM 124. The SDRAM 124 having a function as a storage unit is a buffer memory for temporarily storing data obtained in the preprocessing circuit 121.

  The image processing circuit 125 reads the image data obtained in the preprocessing circuit 121 and stored in the SDRAM 124 and performs various image processing. This image processing includes white balance correction processing for correcting the color balance of the image, color correction processing for correcting the color of the image, gradation correction processing for correcting the gradation of the image, compression processing, and the like. The image processing circuit 125 also has a function as a calculation unit. That is, the image processing circuit 125 performs a process of creating a simulation image in a simulation mode described later.

  The video signal output circuit 126 reads the image data after image processing from the SDRAM 124, converts the read image data into a video signal, and outputs the video signal to the LCD panel drive circuit 127. The LCD panel drive circuit 127 drives the LCD panel 128 according to the video signal input from the video signal output circuit 126 and displays an image on the screen of the LCD panel 128. The LCD panel 128 is disposed on the back surface of the camera body 110, for example, and displays various images such as an image obtained by photographing and a screen for setting external flash devices 200a, 200b, and 200c described later.

  The recording medium control circuit 129 controls writing and reading of data to and from the recording medium 130. The recording medium 130 is a memory card configured to be detachable from the camera body 110, for example, and records the image data compressed by the image processing circuit 125.

  The body drive control circuit 131 having functions as a light emission control unit and a control unit is provided in the camera body 110 such as the mirror drive mechanism 112, the imaging circuit 120, and the flash control circuit 139 in accordance with a control program stored in the flash memory 133. The control of each part is performed. The body drive control circuit 131 is configured to operate in synchronization with the clock signal created by the clock circuit 131a.

  The flash memory control circuit 132 controls data writing to and reading from the flash memory 133. The flash memory 133 stores a control program read by the body drive control circuit 131, various setting values of the camera body 110, and the like.

  The various switches 134 are switches that change states in response to various operation members for operating the camera body 110. The various operation members include a power switch for turning on / off the power of the camera body 110, a release button for giving a camera execution instruction, a playback button for giving an image reproduction instruction, and a menu screen display. A menu button for giving an instruction, an input key as a first determination unit for making various camera settings, an INFO button for switching the display form of the LCD panel 128, and the like. The mirror switch 135 is a switch for detecting whether the quick return mirror 111 is in the inserted state or the retracted state. For example, the mirror switch 135 is in a high state (H) when the quick return mirror is in the retracted state, and is in a low state (L) when the quick return mirror is in the inserted state. The switch detection circuit 136 is a circuit that detects the states of the various switches 134 and the mirror switch 135 and notifies the body drive control circuit 131 of the detection results. In response to the signal from the switch detection circuit 136, the body drive control circuit 131 executes various controls.

  In response to an instruction from the body drive control circuit 131, the input / output circuit 137 outputs a signal for controlling the mirror drive mechanism 112 and the image pickup circuit 120, and processes the photometry processing circuit 116 and the distance measurement processing circuit 118. This is an interface circuit for inputting the result to the body drive control circuit 131.

  The communication circuit 138 is an interface circuit for performing communication between the lens drive control circuit 106 of the interchangeable lens 101 and the body drive control circuit 131 of the camera body 110.

  The flash control circuit 139 performs light emission control of the built-in flash 140 under the control of the body drive control circuit 131. The built-in flash 140 is composed of a light emitting unit composed of, for example, a xenon (Xe) tube, a light emitting circuit for causing the light emitting unit to emit light, and the like. The built-in flash 140 is a pop-up built-in flash that is normally housed in the camera body 110 and pops up as shown in FIG. 3B when flash light is emitted.

  Next, flash photography in the camera system according to the present embodiment will be described. As described above, in the present embodiment, the camera 100 can perform light emission control of the external flash devices 200a, 200b, and 200c. In addition, the user can set whether or not the external flash devices 200a, 200b, and 200c can emit light and the light emission amount in the camera 100. FIG. 4 is a diagram showing an example of a display of a setting screen for setting whether or not the external flash devices 200a, 200b, and 200c can emit light and the amount of light emitted.

  Here, the camera 100 uses a normal shooting mode that does not involve light emission control of the external flash devices 200a, 200b, and 200c, and a wireless flash control mode that involves light emission control of the external flash devices 200a, 200b, and 200c (hereinafter, this mode is referred to as RC. Mode). Here, switching between the normal photographing mode and the RC mode can be performed on a menu screen, for example.

  As shown in FIG. 4, in the normal shooting mode, every time the INFO button is operated, the display on the LCD panel 128 is switched between DSP1 and DSP2. On the other hand, in the RC mode, every time the INFO button is operated, the display on the LCD panel 128 is switched between DSP1, DSP2, and DSP3.

  In the display of the DSP 1, items that are often confirmed in normal shooting (in the example of FIG. 4, shooting mode, shutter speed, aperture value, date, ISO sensitivity, white balance setting, flash mode setting, image processing setting, Display of metering mode setting, ranging mode setting, AF / MF (manual focus) setting, single shooting / continuous shooting setting, current recording medium 130 type, image quality mode setting, number of remaining shots) Do. In the state where the DSP 1 is displayed, various settings can be changed with the input keys.

  Here, in the present embodiment, the flash mode includes a simulation mode (SYM). This simulation mode is a mode for displaying an image for confirming the effect of flash photography on the LCD panel 128. In addition, the flash mode includes, for example, a manual mode (M) for the user to set the light emission amount of each flash device, and an auto mode (AUTO) for automatically setting the light emission amount of each flash device on the camera 100 side. Etc. are included.

  The DSP 2 is in a state where the display of the LCD panel 128 is turned off. If the power consumption is saved or the light from the LCD panel 128 gets in the way when looking through the viewfinder, the display on the DSP 2 is used.

  The DSP 3 is a dedicated display when performing wireless flash photography. The DSP 3 is displayed only when the RC mode is selected from a menu screen (not shown). In the display of the DSP 3, slave flash setting for each group shown in FIG. 1 (in the example of FIG. 4, setting of the operation mode and flash light emission amount for each group), fast second time synchronized light emission (FP) on / off, Various operating conditions such as communication channels used for wireless communication during wireless flash photography can be displayed in a matrix, and various settings can be changed using input keys in the same manner as the DSP 1.

  Next, a simulation mode for confirming the effect of flash photography will be described. The operation in the simulation mode is performed when the flash mode is set to “SYM” indicating the simulation mode on the display of the DSP 1 as shown in FIG. On the display of the DSP 3, the operation mode of each group is fixed to “SYM” indicating the simulation mode. Further, at this time, the flash emission amount can be set. Note that the flash light emission amount set on the display of the DSP 3 is a light amount ratio between stationary light and each external flash device when an image for confirming a flash effect described later is created.

  When the release button is operated during such a simulation mode, a basic image necessary for creating an image for confirming the effect of flash photography (hereinafter referred to as a simulation image) is executed. After this photographing, a simulation image is created, and the created simulation image is displayed on the LCD panel 128 as shown in FIG. 6, for example. The user can select on the DSP 3 screen the settings of the external flash devices 200a, 200b, and 200c that can obtain a desired effect while viewing the simulation image. Thereafter, when the flash mode is set to the manual mode, the next wireless flash photographing is performed with the light emission amount (light quantity ratio) according to the setting selected during the simulation mode.

  FIG. 7 is a flowchart showing an operation when shooting an image necessary for creating a simulation image in the first embodiment. FIG. 8 is a timing chart relating to the operation of FIG.

  As described above, the operation of capturing an image necessary for creating the simulation image is executed when the release button is operated during the simulation mode. When it is detected that the release button has been turned on, the body drive control circuit 131 controls the mirror drive mechanism 112 to move the quick return mirror 111 to the up position (step S1). In addition, the body drive control circuit 131 sets the quick return mirror 111 in the retracted state, and at the same time controls the flash control circuit 139 to cause the built-in flash 140 to emit pulses, thereby causing the external flash devices 200a, 200b, and 200c to perform a simulation mode. Is transmitted (step S2). The data transmitted here includes data indicating that shooting for the simulation mode is started and a delay time for determining the light emission timing of each external flash device.

When the data from the camera 100 is recognized, the external flash devices 200a, 200b, and 200c set the light emission amount for simulation mode and the delay time for light emission. Here, the light emission amount is, for example, a fixed value common to each external flash device. Alternatively, a signal indicating the light emission amount of each external flash device may be added to the flash signal light when notifying the start of the simulation mode. Furthermore, a different delay time is set for each external flash device. Here, as an example, the delay time of the external flash device 200a to zero, and the delay time of the external flash device 200b and imaging frame rate _{t 1} of the imaging device 119, the delay time of the external flash device 200c and 2t _1. If the external flash unit is 4 or more, the external flash unit sets the delay time so delayed by t ₁ each increased by one.

  After the built-in flash 140 emits light, the body drive control circuit 131 determines whether the quick return mirror 111 has moved to the up position by determining whether the mirror switch (SW) 135 has become H (step S3). To do. Until the mirror switch 135 is switched from L to H, the body drive control circuit 131 stands by while making the determination in step S3.

  When it is detected in step S3 that the mirror switch 135 is switched from L to H and the quick return mirror 111 is in the retracted state, the body drive control circuit 131 stops the operation of the mirror drive mechanism 112 ( Step S4). Thereafter, the body drive control circuit 131 transmits a light emission start signal to the external flash devices 200a, 200b, and 200c by controlling the flash control circuit 139 to cause the built-in flash 140 to emit light in pulses (step S5). The external flash devices 200a, 200b, and 200c emit light after a predetermined delay time has elapsed after receiving the light emission start signal.

First, the external flash device 200a emits light when it receives a light emission start signal. In synchronization with this light emission, the body drive control circuit 131 controls the imaging circuit 120 to execute imaging of an image by the imaging element 119 and stores the image obtained by imaging in the SDRAM 124 (step S6). Here, the control of the exposure amount of the image sensor 119 uses, for example, an electronic shutter function of the image sensor 119. That is, when a predetermined exposure time shorter than the imaging frame rate t ₁ has elapsed, the charge accumulation in the imaging element 119 is terminated and the image signal is read from the imaging element 119.

After execution of imaging by the imaging device 119, the body drive control circuit 131 determines whether elapsed the time t ₁ corresponding to the imaging frame rate (step S7). Until the time t ₁ has elapsed, the body drive control circuit 131 waits while performing the determination in step S7. In the determination of step S7, the time _{t 1} has elapsed, the external flash unit 200b emits light. In synchronization with this light emission, the body drive control circuit 131 controls the imaging circuit 120 to perform imaging of an image by the imaging device 119 and stores the image obtained by imaging in the SDRAM 124 (step S8).

After execution of imaging by the imaging device 119, the body drive control circuit 131 determines whether elapsed the time t ₁ corresponding to the imaging frame rate (Step S9). Until the time t ₁ has elapsed, the body drive control circuit 131 waits while performing the determination of step S9. In the determination of step S9, the time _{t 1} has elapsed, the external flash unit 200c emits light. In synchronization with this light emission, the body drive control circuit 131 controls the imaging circuit 120 to execute imaging of an image by the imaging device 119 and stores the image obtained by imaging in the SDRAM 124 (step S10).

After execution of imaging by the imaging device 119, the body drive control circuit 131 determines whether elapsed the time t ₁ corresponding to the imaging frame rate (step S11). Until the time t ₁ has elapsed, the body drive control circuit 131 waits while performing the determination of step S11. In the determination of step S11, the time _{t 1} has elapsed, the body drive control circuit 131 stores the image obtained by the imaging by executing the captured image by the image pickup device 119 by controlling the imaging circuit 120 to SDRAM 124 ( Step S12).

  As shown in FIG. 8, in this embodiment, after receiving the light emission start signal of the built-in flash 140 by the camera 100, the external flash devices 200a, 200b, and 200c emit light sequentially. Further, imaging by the imaging element 119 is executed in synchronization with each light emission. Therefore, the steady light and the light from the external flash device 200a affect the image obtained in step S6, and the steady light and the light from the external flash device 200b affect the image obtained in step S8. The stationary light and the light from the external flash device 200c affect the image obtained in step S10, and only the stationary light affects the image obtained in step S12.

  Here, the image for creating the simulation image is taken only (number of external flash devices + 1) times. In this way, the method of this embodiment can be applied even if there are one or two external flash devices or four or more external flash devices.

  After execution of imaging by the image sensor 119, the body drive control circuit 131 controls the mirror drive mechanism 112 to control the mirror drive mechanism 112 and move the quick return mirror 111 to the down position (step S13). Thereafter, the body drive control circuit 131 determines whether or not the quick return mirror 111 has moved to the down position by determining whether the mirror switch (SW) 135 has become L (step S14). Until the mirror switch 135 is switched from H to L, the body drive control circuit 131 stands by while making the determination in step S14. When it is detected in step S14 that the mirror switch 135 is switched from H to L and the quick return mirror 111 is inserted, the body drive control circuit 131 stops the operation of the mirror drive mechanism 112 ( Step S15). Thus, one shooting sequence is completed.

  FIG. 9 is a flowchart illustrating an operation when displaying a simulation image. After capturing the image for creating the simulation image, the body drive control circuit 131 controls the video signal output circuit 126 to display the setting screen displayed until immediately before the release button is operated on the LCD panel 128 ( Step S21). The photographer designates the light emission amounts of the external flash devices 200a, 200b, and 200c on the screen of the DSP 3 shown in FIG. When the light emission amount is designated, the body drive control circuit 131 stores the light emission amount of each external flash device (step S22).

  After specifying the light emission amount, the photographer performs a determination operation using the input keys. At this time, the body drive control circuit 131 determines whether or not a determination operation has been performed (step S23). If the determination operation is not performed in step S23, the process returns to step S22, and the body drive control circuit 131 waits for the user to specify the light emission amount. On the other hand, when the determination operation is performed in the determination of step S23, the body drive control circuit 131 determines that the steady light only image obtained for the creation of the flash effect image from the light emission amount designated by the photographer. Based on the light quantity ratio with each flash emission image, the influence degree of the stationary light and each external flash device in the simulation image is calculated (step S24). For example, when the light emission amount is specified as in the DSP 3 in FIG. 5, the light amount ratio between the steady light only image, the external flash device 200 a light emission image, the external flash device 200 b light emission image, and the external flash device 200 c light emission image. Becomes 1/4: 1/4: 1/4: 1/4. In this case, the influence degree of the stationary light and each external flash device in the simulation image is 1/4.

  After calculating the influence degree, the body drive control circuit 131 causes the image processing circuit 125 to create a simulation image (step S25). In creating the simulation image, first, a difference image between each external flash emission image and the steady light only image is created, and the influence of the steady light in each external flash emission image is removed. Next, a simulation image is created by synthesizing the stationary light only image and the difference image in accordance with the degree of influence calculated in step S24. After creating the simulation image, the body drive control circuit 131 controls the video signal output circuit 126 to display the simulation image created in the image processing circuit 125 on the LCD panel 128 (step S26). At this time, if there is a portion that exceeds the appropriate exposure in the simulation image, the portion may be highlighted. As described above, the aperture value and shutter speed can be set on the DSP 1 screen. When the aperture value or shutter speed is changed, the ratio of the steady light in the simulation image is changed by creating the simulation image again.

  After displaying the simulation image, the photographer confirms whether or not the flash effect desired by the photographer is obtained by the simulation image displayed on the LCD panel 128. Then, when the desired flash effect is not obtained, an operation of returning by the input key is performed. Further, when a desired flash effect is obtained, an end operation is performed. The end operation of the simulation mode is a switching operation from the simulation mode to the manual mode.

  After the display of the simulation image, the body drive control circuit 131 determines whether or not a return operation has been performed by the photographer operating the input key (step S27). If it is determined in step S27 that a return operation has been performed, the process returns to step S22, and the body drive control circuit 131 waits for the user to specify the light emission amount. On the other hand, when the return operation is not performed in the determination of step S27, the body drive control circuit 131 determines whether or not the simulation mode end operation has been performed by the operation of the input key by the photographer (step S28). If it is determined in step S28 that the simulation mode end operation has not been performed, the process returns to step S27, and the body drive control circuit 131 determines again whether or not the return operation has been performed. On the other hand, when the simulation mode end operation is performed in the determination in step S28, the body drive control circuit 131 ends the simulation mode processing. At this time, the conditions for the presence or absence of light emission of the external flash devices 200a, 200b, and 200c specified in step S22 and the conditions for the respective light emission amounts are held. Thereafter, when wireless flash shooting is performed, shooting (main shooting) is performed under the held conditions.

  As described above, according to the first embodiment, an image necessary for creating a simulation image is captured only in one imaging sequence after the photographer operates the release button in the simulation mode. In this case, it is possible to quickly capture images necessary for creating a simulation image by continuously capturing images using the electronic shutter function, and as a result, wireless flash shooting can be performed quickly. is there.

  Here, in the present embodiment, since it is not considered that the built-in flash 140 emits light during wireless flash photography, only the built-in flash 140 emits light when taking an image necessary for creating a simulation image. No image is taken. However, when taking an image necessary for creating a simulation image, it is also possible to create a simulation image in which only the built-in flash 140 is imaged and the influence of the built-in flash 140 is taken into account.

  In addition, the camera in the first embodiment exemplifies a single-lens reflex camera. However, the method of the present embodiment can also be applied to a compact camera.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. In the first embodiment described above, an image for creating a simulation image is taken when the release button is operated in the simulation mode. This operation is particularly suitable when the image sensor 119 is not operating in the simulation mode. On the other hand, some recent digital cameras have a live view function (also referred to as a through image function). The live view function is a function of causing the image sensor 119 to continuously operate at a timing before photographing or the like, and displaying images sequentially obtained from the image sensor 119 by the continuous operation on the LCD panel 128. With such a function, a photographer can check a subject image without using an optical viewfinder. The second embodiment is a simulation mode suitable for the operation of such a live view function. The configuration of the camera system is the same as that shown in FIG.

  FIG. 10 is a timing chart showing an operation when shooting an image necessary for creating a simulation image in the second embodiment.

  As shown in FIG. 10, when the live view function is operated, the quick return mirror 111 is always moved to the up position. Therefore, the mirror switch 135 is always H. Further, the image sensor 119 is continuously operated in accordance with a predetermined imaging frame rate. Images sequentially obtained by this continuous operation are displayed on the LCD panel 128. If the release button is operated during the operation of the live view function, still image shooting is performed.

  Here, in the second embodiment, it is possible to switch to the simulation mode during the operation of the live view function. When the switching to the simulation mode is detected, the body drive control circuit 131 stops the image display on the LCD panel 128 (the operation of the image sensor 119), and then controls the flash control circuit 139 to control the built-in flash 140. Is transmitted to the external flash devices 200a, 200b, and 200c by pulse light emission. After data transmission, the body drive control circuit 131 resumes the operation of the live view function. Thereafter, after a predetermined time has elapsed (after counting a predetermined number of clock pulses for counting the imaging frame rate), the body drive control circuit 131 controls the flash control circuit 139 to cause the built-in flash 140 to emit pulses. A light emission start signal is transmitted to the external flash devices 200a, 200b, and 200c. In response to the light emission start signal, the external flash devices 200a, 200b, and 200c sequentially emit light. The body drive control circuit 131 extracts an image obtained via the image sensor 119 at a timing synchronized with each light emission and a timing immediately after that, and stores the extracted image in the SDRAM 124. A simulation image is created based on these four images. Processing after the creation of the simulation image is the same as that in the first embodiment.

  As described above, according to the second embodiment, when switching to the simulation mode during the operation of the live view function, a part of the images obtained from the series of images obtained during the operation of the live view function is displayed. Acquired as an image for creating a simulation image. In this case, it is not necessary to drive the quick return mirror as in the first embodiment, and an image for creating a simulation image can be obtained more rapidly than in the first embodiment.

  In addition, shooting of an image for creating a simulation image is executed by an operation different from the release operation. Therefore, in the second embodiment, still image shooting can be performed while the simulation image is displayed.

[Third Embodiment]
Next, a third embodiment of the present invention will be described. In the first embodiment described above, in the simulation mode, the photographer finds a desired condition while checking the simulation image and changing the light emission presence / absence condition and the light emission amount condition of the external flash device. It is. In contrast, in the third embodiment, the camera 100 automatically calculates optimum conditions. Hereinafter, such a simulation mode is referred to as an auto simulation mode. Note that the body drive control circuit 131 in the third embodiment also functions as a second determination unit.

  The operation in the auto simulation mode is performed when the flash mode is set to “Auto-SYM” indicating the auto simulation mode on the display of the DSP 1 as shown in FIG. Imaging of an image for creating a simulation image in the auto simulation mode is performed in the same manner as in the first or second embodiment described above. Therefore, the description is omitted here.

  For example, when wireless flash photography is performed using the external flash device 200a and the external flash device 200b, shadows appear on the right and left sides of the subject as shown in FIG. In the auto-simulation mode, the composition ratio of only the steady light image and each external flash light image (that is, the optimal light emission amount of each external flash device) so that the shadow caused by the light emission of the external flash device has a predetermined darkness. To create a simulation image. At this time, if the luminance difference in the specific area 400 including the contour of the subject 300 shown in FIG. 12 (the difference between the maximum luminance and the minimum luminance in the specific area 400) is larger than a predetermined threshold, the predetermined The light emission amount is determined by excluding a luminance difference portion larger than the threshold value. This is a situation in which the luminance of only a large portion of the luminance difference is enhanced by flash emission such as a backlight state. In such a case, the amount of light emitted from each external flash device is increased so as to increase the luminance of the entire image so that the contour difference is mostly saturated (so as not to be overexposed). Alternatively, the light emission amount of each external flash device may be increased to increase the brightness of the entire image by a predetermined value.

  Further, for example, as shown in FIG. 13A, the light emission amount of the external flash device 200a is too large and the shadow 500a generated by the light emission of the external flash device 200a is too dark, or as shown in FIG. 13C. When the light emission amount of the external flash device 200b is too large and the shadow 500b generated by the light emission of the external flash device 200b is too dark (when the shadow density differs greatly between the shadow 500a and the shadow 500b), Reduce the amount of light emitted from the external flash unit on the strong side (reduce the synthesis ratio). Further, as shown in FIG. 13B, even if the ratio of the light emission amount of the external flash device 200a and the light emission amount of the external flash device 200b is appropriate, the light emission amounts of the external flash device 200a and the external flash device 200b are the same. When the shadow generated around the subject 300 is too large due to being too large, the light emission amounts of both external flash devices are reduced.

  In this way, a simulation image having an optimum light emission amount is created. It should be noted that a plurality of simulation images may be created with a certain amount of difference in the amount of light emitted from each external flash device, and a photographer may select a desired image from the plurality of simulation images.

  As described above, according to the third embodiment, since the camera 100 automatically creates a simulation image with the optimum light emission amount and presents it to the photographer, the photographer does not need to finely adjust the light emission amount. It becomes. Further, by presenting a plurality of simulation images under different conditions, it is possible to reflect the intention of the photographer.

  The present invention has been described above based on the embodiments. However, the present invention is not limited to the above-described embodiments, and various modifications and applications are possible within the scope of the gist of the present invention. .

  Further, the above-described embodiments include various stages of the invention, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some configuration requirements are deleted from all the configuration requirements shown in the embodiment, the above-described problem can be solved, and this configuration requirement is deleted when the above-described effects can be obtained. The configuration can also be extracted as an invention.

It is a figure which shows the structure of the camera system which concerns on the 1st Embodiment of this invention. It is a figure which shows the detailed structure of the camera shown in FIG. It is a figure which shows the state of a quick return mirror. It is the figure which showed an example of the display of the setting screen for setting the light emission possibility of the external flash apparatus 200a, 200b, 200c, the light emission amount, etc. It is a figure which shows the setting screen of the state set to simulation mode. It is a figure which shows the example of a simulation image. It is a flowchart which shows about the operation | movement at the time of imaging | photography the image required for preparation of the simulation image in the 1st Embodiment of this invention. It is a timing chart which concerns on the operation | movement at the time of imaging | photography the image required for preparation of the simulation image in the 1st Embodiment of this invention. It is a flowchart shown about operation | movement at the time of displaying a simulation image. It is a timing chart which shows about operation at the time of photographing a picture required for creation of a simulation picture in a 2nd embodiment of the present invention. It is a figure which shows the setting screen of the state set to the auto simulation mode. It is a figure shown about a specific area | region. It is a figure for demonstrating auto simulation mode.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Camera, 101 ... Interchangeable lens, 102 ... Shooting optical system, 103 ... Optical system drive mechanism, 104 ... Diaphragm mechanism, 105 ... Diaphragm drive mechanism, 106 ... Lens drive control circuit, 107 ... Communication terminal, 110 ... Camera body, DESCRIPTION OF SYMBOLS 111 ... Quick return mirror, 112 ... Mirror drive mechanism, 113 ... Focusing screen, 114 ... Penta prism, 115 ... Photometry sensor, 116 ... Photometry processing circuit, 117 ... Distance measurement sensor, 118 ... Distance measurement processing circuit, 119 ... Image sensor , 120 ... imaging circuit, 121 ... pre-processing circuit, 122 ... data bus, 123 ... SDRAM control circuit, 124 ... SDRAM, 125 ... image processing circuit, 126 ... video signal output circuit, 127 ... LCD panel drive circuit, 128 ... LCD Panel, 129... Recording medium control circuit, 130... Recording medium, 131. Drive control circuit, 132 ... flash memory control circuit, 133 ... flash memory, 134 ... various switches, 135 ... mirror switch, 136 ... switch detection circuit, 137 ... input / output circuit, 138 ... communication circuit, 139 ... flash control circuit, 140: Built-in flash, 200a, 200b, 200c ... External flash device

Claims (11)

A plurality of light emitting devices that emit light to the subject;
A light emission control unit for individually controlling the light emission availability and the light emission amount of the plurality of light emitting devices;
An imaging unit that outputs the light flux from the subject as an image;
The imaging unit is controlled to operate continuously, and each of the plurality of light emitting devices emits light independently in synchronization with the operation of the imaging unit that is part of a series of sequences in which the imaging unit is continuously operated. A control unit for controlling the light emission control unit;
Saving an image output from the imaging unit when each of the plurality of light emitting devices emits light alone and an image output from the imaging unit when not emitting all of the plurality of light emitting devices. A storage unit;
A camera system comprising: A plurality of light emitting devices that emit light to the subject;
A light emission control unit for individually controlling the light emission availability and the light emission amount of the plurality of light emitting devices;
An imaging unit that outputs the light flux from the subject as an image;
In one imaging sequence, the imaging unit is operated in synchronization with each light emission while controlling the light emission control unit so that each of the plurality of light emitting devices emits light alone, and the plurality of light emitting devices are A control unit that operates the imaging unit while controlling the light emission control unit so as not to emit all light;
Saving a plurality of images output from the imaging unit when each of the plurality of light emitting devices emits light alone and an image output from the imaging unit when not emitting all of the plurality of light emitting devices. A storage unit to
A camera system comprising:   3. The light emitting device according to claim 1, wherein each of the plurality of light emitting devices emits light with a predetermined light emission amount or a light emission amount controlled by the light emission control unit when each emits light alone. Camera system.   2. The image processing apparatus according to claim 1, further comprising: an arithmetic unit that calculates an image corresponding to a case where a part or all of the plurality of light emitting devices are caused to emit light simultaneously based on the plurality of images stored in the storage unit. 4. The camera system according to any one of items 1 to 3.   The arithmetic unit further includes a plurality of images corresponding to a case where a condition for determining whether or not to emit a part or all of the plurality of light emitting devices or a condition for the amount of light emission of some or all of the plurality of light emitting devices is changed. The camera system according to claim 4, wherein the camera system is calculated. A first determining unit for determining one image from the plurality of images calculated by the arithmetic unit;
The light emission control unit is configured to determine whether each of the plurality of light emitting devices emits light and emit light according to the light emission availability condition and the light emission amount condition of each light emitting device corresponding to the image determined by the first determination unit. The camera system according to claim 5, wherein the amount is changed. Based on the luminance difference information of the specific area and the luminance information of the entire area in each of the plurality of images calculated by the arithmetic unit, the conditions for whether or not each of the plurality of light emitting devices can emit light and the conditions for the amount of light emission are determined. A second determining unit for determining;
The light emission control unit changes the light emission availability and the light emission amount of the plurality of light emitting devices according to the light emission availability condition and the light emission amount condition of each light emitting device determined by the second determination unit. The camera system according to claim 5.   When there is luminance difference information larger than a predetermined threshold in the luminance difference information of the specific area, the second determination unit excludes the luminance difference information larger than the predetermined threshold and each of the plurality of light emitting devices Determining whether or not to emit light, and determining the amount of light emission; determining whether or not each of the plurality of light emitting devices is capable of light emission and light emission amount so that the highest luminance portion in the entire region is saturated; The camera system according to claim 7, wherein a condition for determining whether or not each of the plurality of light emitting devices can emit light and a condition for the amount of light emission are determined so that the luminance increases by a predetermined value. It further has a predetermined operation member,
The camera system according to claim 1, wherein the control unit controls the imaging unit and the light emitting device when the predetermined operation member is operated.   The plurality of light-emitting devices include at least two of a light-emitting device built in the camera and a plurality of light-emitting devices arranged outside the camera. The camera system described in. An insertion state in which the light beam from the subject is inserted in front of the imaging unit and reflected so as not to be incident on the imaging unit, and a retraction in which the light beam from the subject is incident on the imaging unit by being retracted from the front of the imaging unit A reflective member having a state,
11. The camera system according to claim 2, wherein the one-time imaging sequence is a sequence from when the reflecting member transitions to the retracted state to transition to the insertion state. .

Images