JP6916414B2 - Light emission control device, imaging device and lighting device - Google Patents

Description

The present invention relates to a light emission control device, an image pickup device, and a lighting device.

A flash photography system is known in which a strobe device is made to emit light by wireless control to take a picture (see Patent Document 1). In Patent Document 1, the light emission amount is transmitted from the camera to the strobe device by the light amount setting communication, and the light emission timing is transmitted by the light emission trigger communication. The problems of Patent Document 1 are to secure a response to a user's operation in a wireless communication system, to perform a synchronous operation of a plurality of devices at an accurate time, and to reliably perform a synchronous operation even if there is a disturbance. It is difficult to achieve both because of the high technical hurdles.

Japanese Unexamined Patent Publication No. 2010-185961

The light emission control device according to the first aspect of the present invention performs communication using light or communication using radio waves to each of a plurality of light emitting device groups including at least one light emitting device for photographing assistance. The determination unit that determines whether to perform communication and the light emitting device group that is determined by the determination unit to perform communication using light are controlled so as to perform communication using light, and the determination unit is used. It is provided with a control unit that controls the light emitting device group determined to perform communication using radio waves so as to perform communication using radio waves.
The imaging device according to the second aspect of the present invention includes a light emission control device according to the first aspect and an imaging unit that captures an image by an optical system.
The lighting device according to the third aspect of the present invention has the first light emitting unit for the first light emitting unit and the second light emitting unit for the photographing assist different from the first light emitting unit. A first communication unit having a function of transmitting an instruction regarding light emission of the second light emitting unit and an optical communication type wireless function of receiving an instruction regarding light emission of the first light emitting unit by communication using light emitted from the unit. A function of transmitting an instruction regarding light emission of the third light emitting unit to a device having a third light emitting unit for photographing assistance different from that of the first light emitting unit by communication using radio waves, and the first light emitting unit. A second communication unit having a radio wave communication type wireless function for receiving an instruction regarding light emission is provided, and the first communication unit transmits an instruction to make the second light emitting unit emit light at time T, and the second communication is performed. The unit transmits an instruction to make the third light emitting unit emit light at the time T.
The image pickup device according to the fourth aspect of the present invention is an image pickup device connected to the illumination device according to the third aspect, and captures an image pickup element that captures an image of a subject and outputs a signal, and an image pickup device that captures the image of the subject. The first sensitivity of the image pickup element is set based on the signal output from the image pickup element, and the sensitivity of the image pickup element is set to the first sensitivity in the image pickup accompanied by the provisional light emission that determines the amount of light emission of the illumination device during shooting. Based on the setting unit that can switch between the first control set to and the second control that sets the sensitivity of the image pickup element to a predetermined second sensitivity in the imaging accompanied by the provisional light emission, and the setting in the setting unit. A setting unit that sets the first light amount based on the image pickup with the provisional light emission based on the first control or the second light amount based on the image pickup with the temporary light emission based on the second control as the light emission amount of the lighting device. And.

It is a figure which illustrates the structure of the photographing system by 1st Embodiment. It is a block diagram which illustrates the structure of a camera, a master radio adapter, a remote radio adapter, and an electronic flash device. It is a figure explaining radio wave communication. It is a figure which illustrates the light emission timing at the time of multi-lamp photography. It is a figure which illustrates the communication packet. It is a figure which illustrates the detail of the data in the monitor light emission activation packet. It is a figure which illustrates the detail of the data in this light emission activation packet. It is a figure which illustrates the detail of the data in a light emission gain packet. It is a figure which illustrates the detail of the data in a light emission timing packet. It is a flowchart which illustrates the flow of a shooting process. It is a figure which illustrates the light emission timing at the time of multi-lamp photography. It is a flowchart which illustrates the flow of a shooting process. It is a figure which illustrates the structure of the photographing system by 2nd Embodiment. It is a block diagram which illustrates the structure of a camera, a master wireless adapter, a remote light adapter, and an electronic flash device. It is a figure which illustrates the light emission timing at the time of multi-lamp photography. It is a flowchart explaining the flow of the photographing process by 2nd Embodiment. It is a flowchart explaining the flow of the camera processing by the 3rd Embodiment. It is a flowchart explaining the flow of the camera processing by the 3rd Embodiment.

(First Embodiment)
FIG. 1 is a diagram illustrating the configuration of a photographing system according to the first embodiment. The imaging system of FIG. 1 includes a camera 30 equipped with both a master wireless adapter 10 and an electronic flash device 20, an electronic flash device 20A equipped with a remote wireless adapter 10A, and an electronic flash equipped with a remote wireless adapter 10B. It is a multi-lamp flash photographing system composed of a device 20B, an electronic flash device 20C equipped with a remote wireless adapter 10C, and an electronic flash device 20D equipped with a remote wireless adapter 10D.

The electronic flash device 20 and the electronic flash devices 20A to 20D each have a camera mounting leg that fits into an accessory shoe of the camera 30. In the example of FIG. 1, the electronic flash device 20 is directly attached to the camera 30 by the camera mounting legs, and the electronic flash devices 20A to 20D are attached to the remote wireless adapters 10A to 10D by the camera mounting legs, respectively.
The remote wireless adapters 10A to 10D may be built in the electronic flash devices 20A to 20D, the master wireless adapter 10 may be built in the camera 30, or the remote wireless adapter 10 may be built in the electronic flash device 20. You may let me. Further, at least one of the camera 30, the electronic flash device 20, 20A to 20D may have the function of an optical adapter described later.

The master wireless adapter 10 is attached to, for example, a connection terminal (not shown) on the side surface of the camera 30. The remote wireless adapters 10A to 10D each have an accessory shoe that fits with the camera mounting legs of the electronic flash devices 20A to 20D. Electronic flash devices 20A to 20D are attached to the accessory shoes of the remote wireless adapters 10A to 10D.

The electronic flash device 20 mounted on the camera 30 communicates with the camera 30 by wire via a terminal (not shown) provided on the accessory shoe. The master wireless adapter 10 mounted on the side surface of the camera 30 communicates with the camera 30 by wire via a connection terminal (not shown).

The master wireless adapter 10 performs wireless communication by radio waves with the remote wireless adapter 10A, the remote wireless adapter 10B, the remote wireless adapter 10C, and the remote wireless adapter 10D.

The remote wireless adapter 10A and the electronic flash device 20A communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote wireless adapter 10A. The remote wireless adapter 10B and the electronic flash device 20B communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote wireless adapter 10B. The remote wireless adapter 10C and the electronic flash device 20C communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote wireless adapter 10C. The remote wireless adapter 10D and the electronic flash device 20D communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote wireless adapter 10D.

The configuration of FIG. 1 is a multi-flash photography system composed of one camera 30 and five electronic flash devices 20, 20A to 20D, and the electronic flash device 20 and the electronic flash device 20A are group A. , The case where the electronic flash device 20B is group B, the electronic flash device 20C is group C, and the electronic flash device 20D is group D is illustrated. The total number of electronic flash devices does not have to be five, and may be one or a plurality. Further, the number of electronic flash devices constituting each group and the number of groups may be changed as appropriate.
Furthermore, a multi-lamp flash photography system is configured in which the electronic flash devices 20A to 20D that perform radio wave communication are used as the shooting auxiliary light source without using the electronic flash device 20 directly connected to the accessory shoe of the camera 30 as the shooting auxiliary light source. May be good.

FIG. 2 is a block diagram illustrating the configurations of the camera 30, the master wireless adapter 10, the electronic flash device 20, the remote wireless adapter 10A, and the electronic flash device 20A. In the first embodiment, since the master wireless adapter 10 and the remote wireless adapter 10A have the same circuit configuration, the blocks common to both wireless adapters will be described with the same reference numerals.

Further, although not shown in FIG. 2, the configuration of the remote wireless adapter 10B and the electronic flash device 20B, the configuration of the remote wireless adapter 10C and the electronic flash device 20C, and the configuration of the remote wireless adapter 10D and the electronic flash device 20D are omitted. Are the same as the configurations of the remote wireless adapter 10A and the electronic flash device 20A, respectively.

<Electronic flash device>
In FIG. 2, the electronic flash device 20 and the electronic flash device 20A each include a light emitting tube 201 such as a xenon tube, a light emitting control circuit 202, a CPU 203, a temperature detection unit 204, and a battery remaining amount detection unit 205, respectively. .. The CPU 203 controls the light emission of the arc tube 201 while performing wired communication with the CPU of the connected external device (CPU 105 of the remote wireless adapter 10A or CPU 306 of the camera 30).

The light emission control circuit 202 includes a high voltage charging circuit and stores energy required for discharge light emission. The light emission control circuit 202 controls the discharge time of the stored energy based on the instruction from the CPU 203 to discharge the light emitting tube 201 at a predetermined light emission amount (target light emission amount). The target light emission amount is transmitted from the external device to the CPU 203.

The light emission control circuit 202 sends ready information to the CPU 203 when the stored energy reaches a predetermined value. The light emission control circuit 202 does not send ready information when the stored energy is less than a predetermined value. In general, the predetermined value for transmitting ready information is a value less than the maximum storage capacity of energy.

The battery remaining amount detecting unit 204 detects the voltage of a battery (not shown) provided in the electronic flash device 20 (20A), and the remaining battery level is less than the remaining amount required to discharge and emit light from the arc tube 201 ( When the battery voltage is equal to or less than the predetermined voltage value), the battery warning information is sent to the CPU 203. The battery remaining amount detection unit 205 does not send the battery warning information when the remaining battery amount exceeds the required remaining amount.

<Wireless adapter>
The master wireless adapter 10 and the remote wireless adapter 10A include an antenna 101, a communication circuit 102, and a CPU 105, respectively. The CPU 105 performs wired communication with the CPU of the connected external device (CPU 203 of the electronic flash device 20A or CPU 306 of the camera 30), and also controls radio wave communication with another wireless adapter. conduct.

The communication circuit 102 performs radio wave communication with another wireless adapter via the antenna 101 in response to an instruction from the CPU 105.

<Camera>
The camera 30 includes a photographing lens 301, a shutter 302, an image sensor 303, a photometric sensor 304, a shutter drive device 305, a CPU 306, an operating member (including a release switch) 307, a memory 308, and a display unit 309. , Equipped with.

The photographing lens 301 forms a subject image on the image pickup surface of the image pickup element 303. The shutter 302 is opened and closed controlled by the shutter driving device 305. The photometric sensor 304 outputs a photometric signal according to the intensity of the incident light. The CPU 306 controls the sensitivity of the image sensor 303, the opening time of the shutter 302, and the aperture value of an aperture (not shown) by performing a predetermined exposure calculation based on the photometric signal. The CPU 306 also performs dimming control for the electronic flash devices 20 and 20A to 20D based on the output signal from the photometric sensor 304.

The operation member 307 includes a release switch, a menu switch, an operation dial, and the like, and sends an operation signal corresponding to various operations to the CPU 306. The image sensor 303 photoelectrically converts the subject image and outputs an image signal. The image signal output from the image sensor 303 is subjected to predetermined image processing by the CPU 306. The image processing includes contour enhancement processing, interpolation processing, white balance adjustment processing, and the like. The image signal after image processing is recorded on a recording medium 350 such as a memory card.

The memory 308 stores information transmitted from an electronic flash device used in combination with the camera 30 (for example, a guide number for a minimum light emission amount, a guide number for a maximum light emission amount, and the like).

The display unit 309 is composed of, for example, a liquid crystal display provided on the back surface of the body of the camera 30, and displays a captured image, an operation menu screen, an information display screen, and the like.

<Multi-lamp shooting>
When performing multi-flash photography, the CPU 306 of the camera 30 detects the pressing operation (shooting instruction) of the release switch (operation member 307) by the photographer and starts the release sequence processing. Then, a light emission instruction is sent to the master wireless adapter 10 and the electronic flash device 20 via wired communication.

Prior to the shooting instruction, it is assumed that radio wave communication has been established between the master wireless adapter 10 and the remote wireless adapters 10A to 10D (that is, the electronic flash devices 20A to 20D). For example, the master wireless adapter 10 automatically detects the remote wireless adapters 10A to 10D requesting a wireless connection, makes wireless connections individually, and assigns an ID for recognizing each remote wireless adapter to give the master wireless. Radio communication is established between the adapter 10 and each of the remote wireless adapters 10A to 10D.

Further, among the electronic flash devices 20 and the electronic flash devices 20A to 20D corresponding to the remote wireless adapters 10A to 10D for which radio wave communication has been established, the electronic flash devices to be light-emitting targets are designated in advance by the operation by the photographer. It shall be. Further, it is assumed that the group allocation of the electronic flash device 20 and the electronic flash devices 20A to 20D is also designated in advance by the operation by the photographer.

-Wired communication between the camera and the master wireless adapter-
The communication between the camera 30 (CPU 306) and the master wireless adapter 10 (CPU 105) is wired communication. This wired communication is led by the camera 30 and is appropriately performed as needed.

In communication between the camera 30 and the master wireless adapter 10, the camera 30 usually transmits commands and data to the master wireless adapter 10, and the master wireless adapter 10 that receives the commands returns (acks) to the camera 30. The commands include those for the electronic flash device 20A, those for the electronic flash device 20B, those for the electronic flash device 20C, and those for the electronic flash device 20D.

-Wired communication between the camera and the electronic flash device-
Further, the communication between the camera 30 (CPU 306) and the electronic flash device 20 (CPU 203) is also a wired communication. This wired communication is also led by the camera 30 and appropriately performed as needed.

In the communication between the camera 30 and the electronic flash device 20, the camera 30 usually transmits a command and data to the electronic flash device 20, and the electronic flash device 20 that receives the command returns (acks) to the camera 30. The commands include those for the electronic flash device 20.

-Communication between master wireless adapter and remote wireless adapter-
Communication between the master wireless adapter 10 and the remote wireless adapter 10A, the master wireless adapter 10 and the remote wireless adapter 10B, the master wireless adapter 10 and the remote wireless adapter 10C, and the communication between the master wireless adapter 10 and the remote wireless adapter 10D are radio communication, respectively. Is. FIG. 3 is a diagram illustrating radio wave communication performed by the master wireless adapter 10 with the remote wireless adapter 10A (remote wireless adapter 10B, remote wireless adapter 10C, or remote wireless adapter 10D).

The frequency of occurrence of radio wave communication per remote wireless adapter is the same as the frequency of occurrence of communication between the camera 30 and the master wireless adapter 10. That is, after the wired communication between the camera 30 and the master wireless adapter 10, radio wave communication is performed between the master wireless adapter 10 and each remote wireless adapter without delay.

For communication between the master wireless adapter 10 and the remote wireless adapter 10A (10B, 10C or 10D), the master wireless adapter 10 typically transmits the above commands and data to the remote wireless adapter 10A (10B, 10C or 10D). Upon receiving this, the remote wireless adapter 10A (10B, 10C or 10D) replies (acks) to the master wireless adapter 10. The command includes one for the electronic flash device 20A (20B, 20C or 20D) attached to the remote wireless adapter 10A (10B, 10C or 10D) of the communication partner.

-Communication between remote wireless adapter and electronic flash device-
The communication between each remote wireless adapter 10A (10B, 10C or 10D) and the electronic flash device 20A (20B, 20C or 20D) is wired communication. This wired communication is performed immediately after each remote wireless adapter 10A (10B, 10C or 10D) communicates with the master wireless adapter 10 by radio wave communication with the corresponding electronic flash device.

Communication between the remote wireless adapter 10A (10B, 10C or 10D) and the electronic flash device 20A (20B, 20C or 20D) is typically the electronic flash device 20A supported by the remote wireless adapter 10A (10B, 10C or 10D). The above command and data are transmitted to (20B, 20C or 20D), and the electronic flash device 20A (20B, 20C or 20D) that receives the command and data replies (acks) to the remote wireless adapter 10A (10B, 10C or 10D). The commands include those for the electronic flash device 20A (20B, 20C or 20D) mounted on the remote wireless adapter 10A (10B, 10C or 10D).

<Light emission timing during multi-flash photography (1)>
The light emission timings of the electronic flash devices 20 and 20A to 20D will be described with reference to FIG. FIG. 4 is a diagram illustrating the timing when TTL (through the lens) dimming control is performed in multi-flash photography in which imaging auxiliary light is emitted from the electronic flash devices 20 and 20A to 20D.

Explain the rough time schedule of light emission. When the release switch (operation member 307) is pressed (shooting instruction), the CPU 306 of the camera 30 starts the release sequence process at time t0.

In the release sequence processing at the time of TTL dimming control in the first embodiment, the camera 30 (CPU306) receives an instruction from the CPU 306 before the shutter driving device 305 opens and drives the shutter 302 (before the main shooting exposure). Each of the electronic flash devices 20 and 20A to 20D is made to perform the monitor light emission (preliminary light emission before the main light emission) four times in order in the group unit at the time t1, t3, t5, t7. In the monitor light emission, the electronic flash devices 20 and 20A to 20D emit light at the target light emission amount (target monitor light emission amount) at the time of each monitor light emission.

The photometric sensor 304 of the camera 30 is controlled so as to receive the reflected light from the subject in accordance with the timing of the four monitor emissions (photometry). The CPU 306 calculates the target light emission amount (target main light emission amount) of the electronic flash devices 20 and 20A to 20D at the time of main light emission by performing arithmetic processing based on the light measurement signal output from the light measurement sensor 304.

An example of calculation of the target main emission amount is as follows. The photometric signal output from the photometric sensor 304 in a state where neither the electronic flash device 20 and the 20A to 20D emit light, and the electronic flash device (in this example, the electronic flash device 20 and the electronic flash device 20A) constituting Group A. The target main light emission amount of group A is calculated based on the difference between the light measurement signal output from the light measurement sensor 304 in the state where the monitor emits light.

Similarly, for group B, group C, and group D, the metering signal output from the photometric sensor 304 in a state where the electron flashing devices 20 and 20A to 20D are not emitted, respectively, and the electronic flashing devices (this) constituting each group. In the example, the target main emission amount of each group is based on the difference between the light emission signal output from the photometric sensor 304 in the state where the electronic flash device 20B, the electronic flash device 20C, or the electronic flash device 20D) emits light from the monitor. Is calculated.

At time t10 when the shutter 302 is fully opened, the CPU 306 causes the electronic flash devices 20 and 20A to 20D to emit light at substantially the same time (main shooting exposure). In the main light emission, the electron flash devices 20 and 20A to 20D emit light at their respective target main light emission amounts.

Hereinafter, the light emission timings of the electronic flash devices 20 and 20A to 20D will be described in detail.
<Instruction to monitor light emission for all groups>
The camera 30 (CPU306), which has started the release sequence processing at time t0, broadcasts a monitor light emission activation command to all the remote wireless adapters 10A to 10D via the master wireless adapter 10 by radio wave communication. The radio wave communication during the release sequence processing repeats one-way transmission a plurality of times (for example, 10 times) without requesting a reply (ack) from each of the remote wireless adapters 10A to 10D.

The reason for repeating this multiple times is that in the case of radio communication where communication conditions are poor (for example, an environment with a lot of electromagnetic noise or an environment with large interference with radio waves transmitted by other communication devices), each time it is transmitted. It is based on the idea that it is preferable to increase the probability of being received on the receiving side by repeating the transmission a plurality of times rather than waiting for a reply (ack) and confirming whether or not the reception is received on the receiving side.
The camera 30 (CPU 306) further transmits a monitor light emission activation command to the electronic flash device 20 of the group A by wire communication.

The monitor light emission activation command in the first embodiment includes the group to be monitored light emission and its light emission order, the monitor light emission timing (light emission start time) of the first monitor light emission group, and the monitor light emission interval between the groups. T (interval time) and the target monitor emission amount of each electronic flash device 20 and 20A to 20D are included. The target monitor light emission amount is a predetermined value (about one hundredth of the main light emission amount).

<Group A monitor flash>
The group A remote wireless adapter 10A that has received the monitor light emission activation command transmits the monitor light emission activation command to the connected electronic flash device 20A by wire communication. The electron flash device 20A of this example is the first group A that emits light from the monitor. Therefore, the electronic flash device 20A performs monitor light emission at the target monitor light emission amount at time t1 corresponding to the monitor light emission timing (light emission start time = td1).

On the other hand, the group A electronic flash device 20 that has received the monitor light emission activation command performs monitor light emission at the target monitor light emission amount at time t1 corresponding to the monitor light emission timing (light emission start time = td1).

The camera 30 (CPU 306) performs a photometric process from time t1 while the monitor emits light, and causes the above arithmetic process for group A to be performed after the monitor emits light (Gr.A arithmetic process). By this arithmetic processing, the target main emission amount of the electronic flash devices 20 and 20A is calculated.
The light emission start time to be included in the monitor light emission start command is determined so that the timing of the metering process and the timing of the monitor light emission are matched.

<Group B monitor flash>
The group B remote wireless adapter 10B that has received the monitor light emission start command transmits the monitor light emission start command to the connected electronic flash device 20B by wire communication. The electronic flash device 20B of this example is the second group B that emits light from the monitor. Therefore, the electronic flash device 20B sets the target monitor light emission amount at the time t3 when the monitor light emission interval T (interval time) between the groups elapses from the time t1 corresponding to the monitor light emission timing (light emission start time = td1). The monitor emits light.

The camera 30 (CPU 306) performs the photometric processing while the monitor light emission is performed from the time t3, and causes the above calculation processing targeting the group B to be performed after the monitor light emission (Gr.B calculation processing). By this arithmetic processing, the target main light emission amount of the electronic flash device 20B is calculated.
The light emission start time and the monitor light emission interval T to be included in the monitor light emission start command are determined so as to match the timing of the photometric processing with the timing of the monitor light emission.

<Group C monitor flash>
The group C remote wireless adapter 10C that has received the monitor light emission start command transmits the monitor light emission start command to the connected electronic flash device 20C by wire communication. The electronic flash device 20C of this example is the third group C that emits light from the monitor. Therefore, the electronic flash device 20C emits light from the target monitor at time t5 when the monitor light emission interval T (interval time) × 2 between the groups elapses from the time t1 corresponding to the monitor light emission timing (light emission start time = td1). The monitor emits light by the amount.

The camera 30 (CPU 306) performs a photometric process from time t5 while the monitor emits light, and causes the above arithmetic process for group C to be performed after the monitor emits light (Gr.C arithmetic process). By this arithmetic processing, the target main light emission amount of the electronic flash device 20C is calculated.
The light emission start time and the monitor light emission interval T to be included in the monitor light emission start command are determined so as to match the timing of the photometric processing with the timing of the monitor light emission.

<Group D monitor flash>
The group D remote wireless adapter 10D that has received the monitor light emission start command transmits the monitor light emission start command to the connected electronic flash device 20D by wire communication. The electron flash device 20D of this example is the fourth group D that emits light from the monitor. Therefore, the electronic flash device 20D emits light from the target monitor at time t7 when the monitor light emission interval T (interval time) × 3 between the groups elapses from the time t1 corresponding to the monitor light emission timing (light emission start time = td1). The monitor emits light by the amount.

The camera 30 (CPU 306) performs a photometric process from time t7 while the monitor emits light, and causes the above arithmetic process for group D to be performed after the monitor emits light (Gr.D arithmetic process). By this arithmetic processing, the target main light emission amount of the electronic flash device 20D is calculated.
The light emission start time and the monitor light emission interval T to be included in the monitor light emission start command are determined so as to match the timing of the photometric processing with the timing of the monitor light emission.

The camera 30 (CPU 306) performs a predetermined total calculation process in preparation for the main shooting exposure at time t8, following the calculation process for the group D.

<Instruction for this light emission to all groups>
At time t9 after the total calculation processing, the camera 30 (CPU306) broadcasts the light emission activation command to all the remote wireless adapters 10A to 10D via the master wireless adapter 10 by radio wave communication. Since it is radio wave communication during release sequence processing, one-way transmission without requesting a reply (ack) from each remote wireless adapter 10A to 10D is repeated a plurality of times (for example, 10 times).
The camera 30 (CPU 306) further transmits the main light emission activation command to the electronic flash device 20 of the group A by wire communication.

The main light emission activation command in the first embodiment includes the main light emission timing (light emission start time = td2) and the target main light emission amounts of the electronic flash devices 20 and 20A to 20D.

The remote wireless adapters 10A to 10D that have received the main light emission activation command transmit the main light emission activation command to the connected electronic flash devices 20A to 20D by wire communication.

<Main emission of all groups A to D>
The electronic flash devices 20A to 20D and the electronic flash device 20 that have received the main light emission activation command each perform the main light emission at the target main light emission amount at the time t10 corresponding to the main light emission timing (light emission start time = td2). .. The light emission start time = td2 to be included in the main light emission start command is determined so as to match the timing when the shutter 302 is fully opened (the start of the main shooting exposure) and the timing of the main light emission.

<Communication packet>
In the first embodiment, the following communication packets are generated and transmitted in the above-mentioned communication. FIG. 5 is a diagram illustrating a communication packet, which conforms to a digital communication format. In FIG. 5, the “preamble” 4a is data corresponding to the run-up portion transmitted at the beginning of the communication, and the carrier detection, AGC, and phase of the receiving wireless adapter (for example, the remote wireless adapter 10A to the remote wireless adapter 10D) are used. Used for reference detection. When the wireless adapter on the receiving side detects the "preamble" 4a, it enables the subsequent reception of the signal. A fixed bit pattern such as 0, 0, 0, 0 ... Is set in the "preamble" 4a.

The "SFD (Start of Frame Delimiter)" 4b is synchronization data added to the head portion of the packet following the "playable" 4a, and is also called "SYNC". “SFD” 4b is a pattern for detecting the start of a packet, and is usually 1 byte (or 2 bytes). Since the standard "SFD" 4b is defined in advance by the communication method, reception is performed only when the signal received and decoded by the receiving wireless adapter within the predetermined reception period matches the standard "SFD" 4b. Subsequent reception is enabled on the wireless adapter on the side.

“Flame lens” 4c is data indicating the communication data capacity (number of bytes), and means the amount of information in the packet. After detecting "SFD" 4b, the wireless adapter on the receiving side decodes the number of data indicated by "Flame lens" 4c and ends one reception.

The "command" 4f is data representing a control command for invoking the process. For example, data representing the main light emission activation command is added as a "command" 4f to the communication packet (referred to as the main light emission activation packet) for which the master wireless adapter 10 transmits the main light emission activation command described above. Further, data representing the monitor light emission activation command is added as a "command" 4f to the communication packet (referred to as the monitor light emission activation packet) for which the master wireless adapter 10 transmits the monitor light emission activation command described above.

In the first embodiment, in addition to the monitor light emission activation packet and the main light emission activation packet, a search activation packet, a light emission gain packet, a light emission timing packet, and a light emission confirmation packet are prepared. The search activation packet is a communication packet in which the master wireless adapter 10 transmits a command (connection request inquiry command) for requesting a wireless connection request from the remote wireless adapter 10A to the remote wireless adapter 10D. The light emission gain packet is a communication packet in which the master wireless adapter 10 transmits a command for instructing a target light emission amount in monitor light emission or main light emission. The light emission gain packet does not include information on the light emission timing (light emission start time).

The light emission timing packet is a communication packet in which the master wireless adapter 10 transmits a command for instructing a light emission timing (light emission start time) in monitor light emission or main light emission. The light emission timing packet does not include information on the target light emission amount. The light emission confirmation packet is a communication packet in which the master wireless adapter 10 transmits a command for obtaining post-light emission information (post-light emission information inquiry command) to the remote wireless adapter 10A to the remote wireless adapter 10D.

In the case of a communication packet that does not send a control command, "command" 4f is omitted. For example, in the report packet for the remote wireless adapter 10A to the remote wireless adapter 10D to transmit the report data as post-light emission information to the master wireless adapter 10, the "command" 4f is omitted. The reported data includes, for example, data indicating whether or not the main emission was so-called full emission. Full light emission means that all of the stored energy is discharged to emit light.

The "destination ID" 4g includes the IDs of the remote wireless adapter 10A to the remote wireless adapter 10D for executing the command defined in the "command" 4f, or the ID of the master wireless adapter 10 for transmitting the report packet. ..

Here, IDs are individually assigned to the master wireless adapter 10 and the remote wireless adapters 10A to 10D (for example, M, A, B, C, D), and the wireless adapters are uniquely assigned by these individual IDs. Can be identified.
When a plurality of devices exist in the same group, individual IDs such as A1, A2, ... Are assigned. Further, instead of the individual ID, an ID for designating all devices (referred to as all device ID, for example, 0 (zero)) may be specified. All device IDs are suitable, for example, when all of the remote wireless adapters 10A to 10D are designated as execution targets of the "command" 4f.

The wireless adapter on the side receiving the communication packet is a control command defined in "command" 4f when its own individual ID is included in "destination ID" 4g or when all device IDs are included. Recognize that you are the execution target of, or that you are the destination of the report data.

The "data" 4h can include, for example, group information, mode information, time information, light emission amount information, and the like as data corresponding to the "command" 4f. The group information is information about the above groups A to D. The mode information is information indicating an operation mode.

The time information is information indicating the time from the output of the synchronization signal to the start of processing. As described above, in the first embodiment, "SFD" 4b is used as synchronization data. Then, the timing at which the electronic flash device 20 and the camera 30 start the process and the timing at which the electronic flash devices 20A to 20D start the process are synchronized as follows.

The CPU 306 of the camera 30 on the transmitting side sends the generated communication packet to the CPU 105 of the master wireless adapter 10. The CPU 105 of the master wireless adapter 10 reads and analyzes the communication packet from the beginning in parallel with the wireless transmission of the communication packet by the communication circuit 102, and detects that the reading of "SFD" 4b as synchronization data is completed. The time specified in the above time information is measured based on the time point. The CPU 105 outputs a signal indicating the start of processing to the camera 30 (CPU 306) when the designated time is clocked.

The CPU 105 of the remote wireless adapter 10A on the receiving side reads and analyzes the communication packet received by the communication circuit 102 from the beginning, and uses the time when it detects that the reading of "SFD" 4b as the synchronization data is completed is used as a reference. , Time the time specified in the above time information. The CPU 105 outputs a signal indicating the start of processing to the electronic flash device 20A (CPU 203) when the designated time is clocked.

As a result, with the completion of reading the "SFD" 4b of the communication packet as a time reference, the timing at which the electronic flash device 20 and the camera 30 start processing and the timing at which the electronic flash devices 20A to 20D start processing are determined. Can be synchronized between. Further, even when a plurality of electronic flash devices 20A to 20D exist, the CPU 203 of each electronic flash device 20A to 20D can start the process at the same timing, so that the process between the electronic flash devices 20A to 20D can be started. The start timing can be synchronized with high accuracy.

When one-way transmission that does not request a reply (ack) is repeated a plurality of times, the receiving side does not repeat the process corresponding to the same command. Further, there is no difference in the timing of the processing performed by the receiving side between the case where the receiving side receives the first transmission and starts the command processing and the case where the receiving side receives the second and subsequent transmissions and starts the command processing. As described above, the time information included in the "data" 4h is different each time the number of transmissions is increased.

The luminescence amount information is information indicating the target luminescence amount for each group.

FIG. 6 is a diagram illustrating details of “data” 4h in the monitor light emission activation packet. The group information 61 indicates the group to be light-emitting on the monitor and the light-emitting order of the group. In the case of this example, the order is group A, group B, group C, and group D. The time information 62 is the monitor light emission timing (light emission start time = td1) of the first monitor light emitting group, and is represented by the time based on the reading completion time of the above-mentioned “SFD” 4b. The time information 63 indicates the monitor light emission interval T (interval time) between the groups.

The light emission amount information 64 indicates the target monitor light emission amount of the group A, the target monitor light emission amount of the group B, the target monitor light emission amount of the group C, and the target monitor light emission amount of the group D. When there are a plurality of electronic flash devices in group A, the target monitor light emission amount of group A is the target monitor light emission amount of A1, the target monitor light emission amount of A2, and so on. The target monitor emission amount is continued in the order of individual IDs.

FIG. 7 is a diagram illustrating the details of the “data” 4h in the main light emission activation packet. The group information 71 indicates a group to be light-emitting. The time information 72 is the main light emission timing (light emission start time = td2), and is represented by a time based on the reading completion time of the above-mentioned “SFD” 4b. The mode information 73 indicates whether it is a TTL mode in which the light emission amount is determined by the TTL dimming control method described above, or a manual light emission mode in which light is emitted at a fixed light emission amount.

The light emission amount information 74 indicates the target main light emission amount of group A, the target main light emission amount of group B, the target main light emission amount of group C, and the target main light emission amount of group D. When there are a plurality of electronic flash devices in group A, the target main light emission amount of group A is the target main light emission amount of A1, the target main light emission amount of A2, and so on. The target main emission amount follows in the order of individual IDs.

FIG. 8 is a diagram illustrating the details of the “data” 4h in the emission gain packet. The group information 81, like the group information 71, indicates a group to be light-emitting. The mode information 82, like the mode information 73, indicates a light emitting mode. The light emission amount information 83 indicates the target main light emission amount of each of the electronic flash devices 20 and 20A to 20D, similarly to the light emission amount information 74.

FIG. 9 is a diagram illustrating details of “data” 4h in the light emission timing packet. The group information 91, like the group information 71, indicates a group to be light-emitting. The time information 92 has the same light emission timing (light emission start time = td2) as the time information 72, and is represented by a time based on the time when the above-mentioned “SFD” 4b has been read.

<Explanation of flowchart>
FIG. 10 is a flowchart illustrating the flow of a shooting process in which the CPU 306 of the camera 30 detects and starts a pressing operation (shooting instruction) of the release switch (operating member 307) by the photographer. In step S10 of FIG. 10, the CPU 306 transmits a monitor light emission activation command from the master wireless adapter 10 and also transmits a monitor light emission activation command (monitor light emission activation packet) to the electronic flash device 20 to proceed to step S20 (FIG. 4). Time t0).

Based on the monitor light emission activation packet, the electronic flash devices 20A to 20D and the electronic flash device 20 start the monitor light emission process after the lapse of the time specified in the time information described above.

In step S20, the CPU 306 starts the metering process after the lapse of the time specified in the time information described above, and proceeds to step S30. In step S30, the CPU 306 starts the calculation process of the target main light emission amount and proceeds to step S40. In step S40, the CPU 306 determines whether or not the monitor light emission has ended. Based on the "data" 4h in the monitor light emission activation packet, the CPU 306 determines affirmatively in step S40 and proceeds to step S50 when the monitor light emission has been completed in all the groups targeted for the monitor light emission. If the monitor light emission has not been completed in all the groups that are the targets of the monitor light emission, the CPU 306 negatively determines step S40 and returns to step S20. When returning to step S20, the CPU 306 starts the metering process in accordance with the monitor light emission of the remaining groups.

In step S50, the CPU 306 starts the comprehensive calculation process and proceeds to step S60 (time t8 in FIG. 4). In step S60, the CPU 306 initiates an exposure sequence. Specifically, the shutter drive device 305 starts the front curtain traveling of the shutter 302, and the process proceeds to step S70.

In step S70, the CPU 306 transmits the main light emission activation command from the master wireless adapter 10 and also transmits the main light emission activation command to the electronic flash device 20 to proceed to step S80 (time t9 in FIG. 4). This light emission activation command is transmitted in accordance with the so-called X-on timing.

The electronic flash devices 20A to 20D and the electronic flash devices 20 start the processing of the main light emission after the lapse of the time specified by the time information described above. The main light emission is performed at time t10 in FIG. 4 when the shutter 302 is fully opened.

In step S80, the CPU 306 reads an image signal from the image sensor 303 at the timing when the trailing curtain running of the shutter 302 by the shutter drive device 305 starts (time t11 in FIG. 4), performs predetermined image processing, and proceeds to step S90. move on.

In step S90, the CPU 306 records the image signal after the image processing on a recording medium 350 such as a memory card, and ends a series of shooting processes.

<Light emission timing when shooting with multiple lights (Part 2)>
The timing (No. 1) at the time of multi-lamp shooting described above has been described by taking so-called front curtain synchronization as an example when the main light emission activation command is transmitted in accordance with the end of traveling (X on timing) of the front curtain of the shutter 302.
The timing (No. 2) at the time of multi-lamp shooting is a case where the rear curtain of the shutter 302 is started to run based on the photographer's operation such as valve shooting or time shooting, and the exposure time when the shutter 302 is open. Will be described by taking as an example the case of so-called rear curtain synchronization in which the main light emission activation command is transmitted so as to perform the main light emission before the start of running of the rear curtain, which is longer than the above predetermined time (for example, 0.1 second to 1 second). ..
Even in bulb photography and time photography, the exposure time during which the shutter 302 is open is predetermined to be shorter than a predetermined time (for example, 0.1 second to 1 second), and the traveling of the front curtain of the shutter 302 is completed. When sending the main light emission activation command at the same time, the main light emission timing (light emission start time = td2) and the target book of each electronic flash device 20 and 20A to 20D, as in the timing at the time of multi-lamp shooting (No. 1). Use this light emission activation command including the light emission amount.

FIG. 11 is a diagram illustrating the timing when TTL (through the lens) dimming control is performed in multi-flash photography in which imaging auxiliary light is emitted from the electronic flash devices 20 and 20A to 20D. Since the time t0 to the time t8 are the same as in the case of FIG. 4, the description thereof will be omitted.

<Instruction of target emission amount for all groups>
At time t9 after the total calculation processing, the camera 30 (CPU306) broadcasts the emission gain packet to all the remote wireless adapters 10A to 10D via the master wireless adapter 10 by radio wave communication. Since it is radio wave communication during release sequence processing, one-way transmission without requesting a reply (ack) from each remote wireless adapter 10A to 10D is repeated a plurality of times (for example, 10 times).
The camera 30 (CPU 306) further transmits a light emission gain packet to the group A electronic flash device 20 by wire communication.

The emission gain packet includes the target emission amount of each electron flash device 20 and 20A to 20D. The remote wireless adapters 10A to 10D that have received the light emission gain packet transmit the light emission gain packet to the electronic flash devices 20A to 20D to which they are connected by wire communication.

The electron flash devices 20A to 20D and the electron flash device 20 that have received the light emission gain packet each set the target main light emission amount and wait for the light emission timing packet.
Since the light emission gain packet does not include information on the light emission timing (light emission start time), the amount of information is smaller than that of the main light emission activation packet. Therefore, the length of the transmission time is shorter than that of the main light emission activation packet. In the example of FIG. 11, the main shooting exposure is started at the time t10a when the shutter 302 is fully opened.

<Light emission instruction for all groups>
When the photographer detects that the release switch (operating member 307) has been pressed, the camera 30 (CPU306) emits light to all the remote wireless adapters 10A to 10D via the master wireless adapter 10 at time t10b. Broadcast the timing packet by radio communication. Since it is radio wave communication during release sequence processing, one-way transmission without requesting a reply (ack) from each remote wireless adapter 10A to 10D is repeated a plurality of times (for example, 10 times).
The camera 30 (CPU 306) further transmits a light emission timing packet to the group A electronic flash device 20 by wire communication. Further, the CPU 306 instructs the shutter drive device 305 to start the rear curtain running of the shutter 302.

The remote wireless adapters 10A to 10D that have received the light emission timing packet transmit the light emission timing packet to the connected electronic flash devices 20A to 20D by wire communication.

The electronic flash devices 20A to 20D and the electronic flash device 20 that have received the light emission timing packet each perform the main light emission at the target main light emission amount at the time t10c corresponding to the light emission timing (light emission start time = td3).
Since the light emission timing packet does not include information on the target light emission amount, the amount of information is smaller than that of the main light emission activation packet. Therefore, since the length of the transmission time is shorter than that of the main light emission activation packet, the photographer releases the release switch (operation member 307) as compared with the case where the main light emission activation packet is transmitted at time t10b. Therefore, the time from the start of the rear curtain running of the shutter 302 (the end of the main shooting exposure) can be shortened.

The shutter drive device 305 starts the rear curtain running of the shutter 302 at time t11 after the main light emission.

<Explanation of flowchart>
FIG. 12 is a flowchart illustrating the flow of a shooting process in which the CPU 306 of the camera 30 detects and starts a pressing operation (shooting instruction) of the release switch (operating member 307) by the photographer.
Since steps S10 to S60 are the same as in FIG. 10, the description thereof will be omitted.

In step S60 of FIG. 12, the CPU 306 initiates an exposure sequence. Specifically, the shutter drive device 305 starts the front curtain traveling of the shutter 302, and the process proceeds to step S70A.

In step S70A, the CPU 306 transmits a light emission gain packet from the master wireless adapter 10 and also transmits a light emission gain packet to the electronic flash device 20 to proceed to step S70B (time t9 in FIG. 11).

In step S70B, the CPU 306 determines whether or not the pressing operation of the release switch (operating member 307) by the photographer has been released. When the pressing operation is released, the CPU 306 positively determines step S70B and proceeds to step S70C. If the pressing operation is not released, the CPU 306 determines negatively in step S70B and repeats the determination process.
In the case of time shooting, instead of determining the release of the release switch (operation member 307), the release switch (operation member 307) is determined to be pressed again.

In step S70C, the CPU 306 transmits a light emission timing packet from the master wireless adapter 10 and also transmits a light emission timing packet to the electronic flash device 20 to proceed to step S80 (time t10b in FIG. 11).

The electronic flash devices 20A to 20D and the electronic flash devices 20 perform the main light emission after the lapse of the light emission start time = td3 specified in the time information described above, that is, at the time t10c in FIG.

In step S80 of FIG. 12, the CPU 306 reads an image signal from the image sensor 303 and performs predetermined image processing at the timing when the trailing curtain running of the shutter 302 by the shutter drive device 305 starts (time t11 in FIG. 11). The process proceeds to step S90. Since the processing after step S90 is the same as that in FIG. 10, the description thereof will be omitted.

According to the first embodiment described above, the following effects can be obtained.
(1) The photographing system that functions as a light emission control device is the main light emission activation packet including information on the light emission amount of the electronic flash devices 20A to 20D and information on the light emission timing of the electronic flash devices 20A to 20D, and the electronic flash devices 20A to 20D. A light emission gain packet containing information on the light emission amount of the electronic flash devices 20A to 20D and not including information on the light emission timing of the electronic flash devices 20A to 20D, and a light emission amount of the electronic flash devices 20A to 20D including information on the light emission timing of the electronic flash devices 20A to 20D. The master wireless adapter 10 that transmits at least one of the light emission timing packets containing no information to the electronic flash devices 20A to 20D, and at least one of the main light emission activation packet, the light emission gain packet, and the light emission timing packet depending on the shooting conditions. It has a CPU 306 that controls the master wireless adapter 10 so as to transmit to the electronic flash devices 20A to 20D. For example, depending on whether or not the shooting conditions are suitable for transmitting the target main light emission amount 74 and the main light emission timing 72 at one time, transmission of the main light emission activation packet effective for reducing the number of communications, and light emission gain packet and light emission. Since the timing packet and the transmission that is sent separately are used properly, the number of communications can be reduced. If the number of communications is reduced, power consumption can be reduced.

(2) The CPU 306 of the camera 30 is used in the case of front curtain synchronized shooting, and in the case of rear curtain synchronized shooting and the exposure time is predetermined and the exposure time is shorter than the predetermined time (for example, the exposure time when the shutter 302 is open). This emission activation packet is transmitted to the camera 30 side), so that the number of communications can be reduced.

(3) When the CPU 306 of the camera 30 determines the end of the exposure based on the rear curtain synchronized shooting and the exposure time longer than the predetermined time, and the rear curtain synchronized shooting and the operation by the photographer (for example, valve shooting, time). (Shooting) is made to transmit the light emission gain packet and the light emission timing packet separately. Since the shooting conditions for separate transmission are limited, the number of communications can be reduced as compared with the case where the light emission gain packet and the light emission timing packet are always transmitted separately.
Further, it is longer than the time from the operation by the photographer until the electronic flash devices 20A to 20D emit the main light emission by sending the main light emission activation packet including both the target main light emission amount 74 and the main light emission timing 72 as control information. The time from the operation by the photographer to the transmission of the light emission timing packet including the main light emission timing 92 as the control information until the electronic flash devices 20A to 20D actually emit light is shorter. This is because the light emission timing packet (see FIG. 9) has a smaller amount of data than the main light emission activation packet (see FIG. 7).

(4) The CPU 306 of the camera 30 uses the light emission timing packet including the light emission timing as control information to include "time for the electronic flash devices 20 and 20A to 20D to start light emission processing and synchronization data as reference for the start time". Includes SFD "4b and. The CPU 306 can synchronize the timing of the main light emission processing and the end of the exposure by, for example, determining the time to start the rear curtain running of the shutter 302 based on the synchronization data of the light emission timing packet.

(5) Since the camera 30 includes a CPU 306 that determines the end time of exposure based on the time when "SFD" 4b as synchronous data is read from the light emission timing packet, the timing of the main light emission process and the end of exposure can be determined. It can be synchronized accurately. Specifically, when a signal is output from the CPU 105 of the master wireless adapter 10 that has completed reading the “SFD” 4b as synchronous data, the CPU 306 starts the trailing curtain running of the shutter 302 with reference to this signal.

(6) The electronic flash devices 20 and 20A to 20D include a light emitting tube 201 that emits illumination light, remote wireless adapters 10A to 10D that receive control information, and both a target light emission amount and a main light emission timing as control information. When the light emission activation packet is received by the remote wireless adapters 10A to 10D, the light emission gain packet including the target main light emission amount as control information and the light emission timing packet including the main light emission timing as control information are received by the remote wireless adapter 10A to 10D. Since the CPU 203 that emits light from the arc tube 201 is provided when the packet is received, the main emission can be appropriately performed by any method. In this way, it contributes to the reduction of the number of communications.

The following modifications are also within the scope of the invention, and one or more of the modifications can be combined with the above-described embodiment.
(Modification 1-1)
In the above description, the example in which the monitor light emission is performed once in each group has been described, but the monitor light emission may be repeated twice or more. The CPU 306 of the camera 30 performs the arithmetic processing after the monitor emits light before performing the comprehensive arithmetic processing on the group determined that the photometric amount by the photometric sensor 304 is small and the S / N ratio of the data indicating the photometric value is poor. The target monitor light emission amount specified in the light emission amount information 64 (FIG. 6) is made larger than the previous time, and the monitor light emission activation packet is generated and transmitted again. That is, the CPU 306 causes the master wireless adapter 10 to transmit the second monitor light emission activation command, and also transmits the second monitor light emission activation command to the electronic flash device 20.

Further, the CPU 306 of the camera 30 targets the group whose photometric amount by the photometric sensor 304 is large and overflows the photometric range in the arithmetic processing after the monitor emits light, and before performing the comprehensive arithmetic processing, the light emission amount information 64 (FIG. 6). The target monitor emission amount specified in) is made smaller than the previous time, and the monitor emission activation packet is generated and transmitted again. That is, the CPU 306 causes the master wireless adapter 10 to transmit the second monitor light emission activation command, and also transmits the second monitor light emission activation command to the electronic flash device 20.

When it is determined that the proper metering results have been obtained for all the groups by repeating the monitor flashing only for the groups for which the proper metering results have not been obtained at the time of the first monitor flashing, the CPU 306 performs the above-mentioned comprehensive calculation processing. Proceed to.

At this time, it is conceivable to transmit individually for each group as in the conventional technique, but in this case, it is necessary to perform communication from the "preamble" 4a on the master wireless adapter 10 side each time, which is time consuming. Loss occurs. However, in the modified example 1-1, as shown in FIG. 6, the order of the groups to be emitted, the start time, the interval time, and the emission amount information are collectively specified by one monitor emission activation packet, so that the time is temporal. It prevents loss from occurring.

According to the modified example 1-1, since the control information having different processing start times is transmitted even at the time of the second monitor light emission, it is not necessary to transmit each processing start time. As a result, the number of communications can be reduced.

(Modification 1-2)
As the light emission timing (No. 2) at the time of multi-flash photography, the rear curtain synchro in which the main light emission is performed before the start of running of the rear curtain in bulb photography and time photography has been described as an example. The control according to FIGS. 11 and 12 can be applied not only to bulb photography and time photography but also to the case of stopping long-time exposure. The long exposure is, for example, an exposure of 30 seconds, 1 minute, or more. Although the photographer has started shooting with a predetermined main shooting exposure time in advance, the photographer performs a predetermined operation (for example, operating a stop switch (not shown)) in order to stop the shooting before the expiration of the main shooting exposure time. ..

When the CPU 306 detects the stop operation of the long-time exposure, it instructs the shutter drive device 305 to start the trailing curtain running of the shutter 302 at the time t10b in FIG. 11, and transmits a light emission timing packet to all the electronic flash devices. Let me.
As described above, even when the long-time exposure of, for example, 30 seconds or more is forcibly terminated in the middle of the exposure after the start, the rear curtain synchronized photography can be appropriately performed by switching to the second instruction method described above.

(Modification 1-3)
In the above description, by using "SFD" 4b as the synchronization data, the timing at which the camera 30 and the electronic flash device 20 start processing and the timing at which the electronic flash devices 20A to 20D start processing are matched (synchronization). To take). That is, the CPU 105 of the remote wireless adapter 10A on the receiving side analyzes the communication packet received from the master wireless adapter 10 on the transmitting side, and starts processing based on the time when the completion of reading the above "SFD" 4b is detected. Time the time. Instead, the time when the communication packet is received from the master wireless adapter 10 on the transmitting side may be used as a reference.

That is, in the modification 1-3, when the CPU 105 of the remote wireless adapter 10A on the receiving side starts timing from the time when the communication packet is received from the master wireless adapter 10 and the time specified in the above time information elapses. To start the process. Even in the configuration of the modification 1-3, the timing when the camera 30 and the electronic flash device 20 start the process and the timing when the electronic flash devices 20A to 20D start the process can be matched (synchronized).
Further, in the above-described embodiment, an example in which the electronic flash devices 20A to 20E are controlled by using the CPU 306 provided in the camera 30 and the master wireless adapter 10 provided in the camera 30 has been described, but the present invention is limited to this. It's not something. For example, the function of the CPU 306 and the function of the master wireless adapter 10 may be provided in the electronic flash device 20. In this case, the electron flash device 20 can control the electron flash devices 20A to 20D. For example, the electronic flash device 20 includes information on the light emission amount of the electronic flash devices 20A to 20D and information on the light emission timing of the electronic flash devices 20A to 20D, and information on the light emission amount of the electronic flash devices 20A to 20D. A light emission gain packet that includes information about the light emission timing of the electronic flash devices 20A to 20D, and a light emission that includes information about the light emission timing of the electronic flash devices 20A to 20D and does not include information about the light emission amount of the electronic flash devices 20A to 20D. At least one of the timing packets can be transmitted to the electronic flash devices 20A to 20D.

(Modification 1-4)
In the above description, an example of outputting a photometric signal according to the intensity of incident light by a photometric sensor 304 provided separately from the image sensor 303 has been described. However, the camera 30 does not necessarily have to include the photometric sensor 304 separately from the image sensor 303. In the case of a camera that does not have a dedicated photometric sensor, the image sensor 303 outputs a photometric signal according to the intensity of the incident light. The same applies to the second embodiment and the third embodiment.

(Second Embodiment)
FIG. 13 is a diagram illustrating the configuration of the photographing system according to the second embodiment. In the second embodiment, a wireless adapter for radio communication (master wireless adapter 10, remote wireless adapter 10D, remote wireless adapter 10E) and an optical adapter for wireless optical communication (remote optical adapter 110A, remote optical adapter 110B) ) Is mixed. In a multi-flash photography system in which different communication methods exist, it is necessary to control the light emission so that the timing of starting light emission does not deviate between the case where the light emission instruction is given by radio wave communication and the case where the light emission instruction is given by optical communication.
The light emission control in such a case will be described below.

The multi-flash imaging system in FIG. 13 is equipped with a camera 30 equipped with both a master wireless adapter 10 and an electronic flash device 20, an electronic flash device 20A equipped with a remote light adapter 110A, and a remote light adapter 110B. It is composed of an electronic flash device 20B, an electronic flash device 20D equipped with a remote wireless adapter 10D, and an electronic flash device 20E equipped with a remote wireless adapter 10E.

The electronic flash device 20 and the electronic flash devices 20A, 20B, 20D, 20E each have a camera mounting leg that fits into the accessory shoe of the camera 30. In the example of FIG. 13, the electronic flash device 20 is directly attached to the camera 30 by the camera mounting legs, and the electronic flash devices 20A and 20B are attached to the remote optical adapters 110A and 110B by the camera mounting legs, respectively. Further, the electronic flash devices 20D and 20E are attached to the remote wireless adapters 10D and 10E by the camera mounting legs, respectively.

In the first embodiment and the second embodiment described above, the electronic flash device 20 may include a master optical adapter (not shown). The master optical adapter includes, for example, a light receiving sensor (not shown), a detection circuit (not shown), and a CPU (not shown). This CPU can perform wired communication with the CPU 203 of the electronic flash device 20, and can also perform optical wireless communication with the remote optical adapters 110A and 110B.
In the first embodiment and the second embodiment described above, at least one of the camera 30, the electronic flash devices 20, 20A to 20D (electronic flash devices 20, 20A to 20E) functions as a master optical adapter. And an optical adapter having a function with a remote optical adapter.
In the first embodiment and the second embodiment described above, at least one of the camera 30, the electronic flash devices 20, 20A to 20D (electronic flash devices 20, 20A to 20E) functions as a master wireless adapter. And may have a wireless adapter having a function with a remote wireless adapter.
In the first embodiment and the second embodiment described above, at least one of the camera 30, the electronic flash devices 20, 20A to 20D (electronic flash devices 20, 20A to 20E) has an optical adapter (master light). An adapter (at least one of the adapter and the remote optical adapter) and a wireless adapter (at least one of the master wireless adapter and the remote wireless adapter) may be provided.
In the first embodiment and the second embodiment described above, the optical adapter (at least one of the master optical adapter and the remote optical adapter) and the wireless adapter (at least one of the master wireless adapter and the remote wireless adapter) are the cameras 30. , 20A to 20D (electronic flashing devices 20, 20A to 20E) may be built in at least one of the electronic flashing devices 20, 20A to 20D, or the camera 30, the electronic flashing devices 20, 20A to 20D (electronic flashing devices 20, 20A). ~ 20E) may be detachably provided from at least one.

The master wireless adapter 10 is attached to a connection terminal (not shown) on the side surface of the camera 30 as in the case of the first embodiment. The remote optical adapters 110A and 110B and the remote wireless adapters 10D and 10E have accessory shoes that fit into the camera mounting legs of the electronic flash devices 20A, 20B, 20D and 20E, respectively. The electronic flash devices 20A and 20B are attached to the accessory shoes of the remote optical adapters 110A and 110B, and the electronic flash devices 20D and 20E are attached to the accessory shoes of the remote wireless adapters 10D and 10E.

The electronic flash device 20 mounted on the camera 30 communicates with the camera 30 by wire via a terminal (not shown) provided on the accessory shoe. The master wireless adapter 10 mounted on the side surface of the camera 30 communicates with the camera 30 by wire via a connection terminal (not shown).

The master wireless adapter 10 performs wireless communication by radio waves with the remote wireless adapter 10D and the remote wireless adapter 10E.

The remote optical adapter 110A and the electronic flash device 20A communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote optical adapter 110A. The remote optical adapter 110B and the electronic flash device 20B communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote optical adapter 110B.

The remote wireless adapter 10D and the electronic flash device 20D communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote wireless adapter 10D. The remote wireless adapter 10E and the electronic flash device 20E communicate by wire via a terminal (not shown) provided in the accessory shoe of the remote wireless adapter 10E.

The configuration of FIG. 13 is a multi-flash photography system composed of one camera 30 and five electronic flash devices 20, 20A, 20B, 20D, and 20E, and the electronic flash device 20 and the electronic flash device 20A. Is group A, the electronic flash device 20B is group B, the electronic flash device 20D is group D, and the electronic flash device 20E is group E.

The multi-flash photography system is configured so that, for example, three groups (group A, group B, and group C) can be provided as a group of remote optical adapters that perform optical communication. In this example, group A and group B are used.

Further, the multi-flash photography system is configured so that, for example, three groups (group D, group E, and group F) can be provided as a group of remote wireless adapters that perform radio wave communication. Of these, group D and group E are used in this example.

The total number of electronic flash devices does not have to be five, and may be one or two or more. Further, the number of electronic flash devices constituting each group and the number of groups may be changed as appropriate.

In the second embodiment, an example will be described in which the electronic flash device 20 is used as a light source for optical communication for sending signals to the remote optical adapters 110A and 110B, and is not used for photographing (that is, an auxiliary light source for photographing).
The electronic flash device 20 may be used as a light source for optical communication for sending signals to the remote optical adapters 110A and 110B, and may also be used for photography (that is, an auxiliary light source for photography).

FIG. 14 is a block diagram illustrating the configurations of the camera 30, the master wireless adapter 10, the electronic flash device 20, the remote light adapter 110A, and the electronic flash device 20A among the configurations illustrated in FIG. In the second embodiment, since the configuration of the remote optical adapter 110A is different from that of FIG. 3 described in the first embodiment, the remote optical adapter 110A will be mainly described.

The configurations of the camera 30, the master wireless adapter 10, the electronic flash device 20, and the electronic flash device 20A in FIG. 14 are the same as those in FIG. 3, and thus the description thereof will be omitted.
Further, since the electron flash device 20B, the electron flash device 20D, and the electron flash device 20E in FIG. 13 all have the same configuration as the electron flash device 20A, the description thereof will be omitted. Further, since the remote wireless adapter 10D and the remote wireless adapter 10E both have the same configuration as the remote wireless adapter 10A described above, the description thereof will be omitted.

<Remote optical adapter>
The remote optical adapter 110A of FIG. 14 includes a light receiving sensor 103, a detection circuit 104, and a CPU 105. The CPU 105 performs wired communication with the CPU of the connected external device (CPU 203 of the electronic flash device 20A), and also performs optical communication with the electronic flash device 20 on the camera 30 side.

The optical communication refers to communication in which a light emission instruction is sent by light from the electronic flash device 20 on the camera 30 side so that the electronic flash device 20A emits light at a predetermined timing.

The light receiving sensor 103 receives the modulated light (optical pulse train) transmitted from the electron flash device 20 as a light emission instruction, and sends a photoelectric conversion signal to the detection circuit 104. The detection circuit 104 decodes the photoelectrically converted pulse train and sends it to the CPU 105. The CPU 105 sends a light emission instruction detected by the detection circuit 104 to the CPU 203 of the electronic flash device.

<Multi-lamp shooting>
When performing multi-flash photography, the CPU 306 of the camera 30 detects the pressing operation (shooting instruction) of the release switch (operation member 307) by the photographer and starts the release sequence processing. Then, a light emission instruction is sent to the master wireless adapter 10 and the electronic flash device 20 via wired communication.

Prior to the shooting instruction, it is assumed that radio wave communication has been established between the master wireless adapter 10 and the remote wireless adapters 10D and 10E (that is, the electronic flash devices 20D and 20E). For example, the CPU 306 of the camera 30 assigns the remote wireless adapter 10D to the group D and the remote wireless adapter 10E to the group E as a group of the remote wireless adapters to be light-emitting by the operation by the photographer. The master wireless adapter 10 makes a wireless connection with the remote wireless adapters 10D and 10E, respectively, and establishes radio communication between the master wireless adapter 10 and the remote wireless adapters 10D and 10E.

Similarly, the CPU 306 of the camera 30 assigns the remote optical adapter 110A to the group A and the remote optical adapter 110B to the group B as a group of the remote optical adapters to be light-emitting by the operation by the photographer. In this way, it is assumed that the electronic flash device to be light-emitting and the grouping thereof are specified in advance.

Among the groups designated as described above, the communication between the group D and the group E in which the master wireless adapter 10 communicates by radio waves is the same as in the case of the first embodiment. Therefore, the optical communication between the electronic flash device 20 and the group A and the group B will be mainly described.

-Remote optical adapter communication-
The electronic flash device 20 performs optical communication with the remote optical adapter 110A and the remote optical adapter 110B as follows. The electronic flash device 20 emits modulated light toward the remote optical adapter 110A and the remote optical adapter 110B by blinking the arc tube 201, for example. The pulse train of the modulated light includes, for example, group information as a light emission instruction, light emission type information, and light emission amount information.

The group information is information indicating a group to be emitted. In the case of this example, information indicating group A or group B in optical communication is included. The light emission type information is information indicating monitor light emission or main light emission. The light emission amount information is information indicating the light emission amount.

The frequency of occurrence of optical communication is the same as the frequency of occurrence of light emission instructions issued by the camera 30. That is, optical communication is performed from the electronic flash device 20 on the camera 30 side to each remote optical adapter each time the monitor emits light or the main light is emitted.

<Light emission timing when shooting multiple lights>
The light emission timings of the electronic flash devices 20 and 20A, 20B, 20D, and 20E will be described with reference to FIG. FIG. 15 is a diagram illustrating the timing when TTL dimming control is performed in the multi-flash photography system according to the second embodiment.

Explain the rough time schedule of light emission. When the release switch (operation member 307) is pressed (shooting instruction), the CPU 306 of the camera 30 starts the release sequence process at time t0.

In the release sequence processing at the time of TTL dimming control in the second embodiment, the camera 30 (CPU306) receives an instruction from the CPU 306 before the shutter driving device 305 opens and drives the shutter 302 (before the main shooting exposure). Each of the electronic flash devices 20A, 20B, 20D, and 20E is made to perform the monitor light emission (preliminary light emission before the main light emission) four times in order in the group unit at the time t1, t3, t5, and t7. In the monitor light emission, the electronic flash devices 20 and 20A, 20B, 20D, and 20E emit light at the target light emission amount (target monitor light emission amount) at the time of each monitor light emission.

The photometric sensor 304 of the camera 30 is controlled so as to receive the reflected light from the subject in accordance with the timing of the four monitor emissions (photometry). The CPU 306 calculates the target light emission amount (target main light emission amount) of the electronic flash devices 20A, 20B, 20D, and 20E at the time of main light emission by performing arithmetic processing based on the light measurement signal output from the light measurement sensor 304. The calculation of the target main emission amount is the same as in the case of the first embodiment.

At time t10 when the shutter 302 is fully opened, the CPU 306 causes the electronic flash devices 20A, 20B, 20D, and 20E to emit light at substantially the same time (main shooting exposure). In the main light emission, the electron flash devices 20A, 20B, 20D, and 20E emit light at their respective target main light emission amounts.

Hereinafter, the light emission timings of the electronic flash devices 20 and 20A, 20B, 20D, and 20E will be described in detail.
<Instruction of monitor light emission to group A performing optical communication>
The camera 30 (CPU306), which has started the release sequence processing at time t0, transmits a monitor light emission instruction to the remote optical adapter 110A of the group A via the electronic flash device 20 by optical communication.

The monitor light emission instruction to the group A includes the instruction to the group A, the monitor light emission, and the target monitor light emission amount. As described above, the target monitor light emission amount is a predetermined value (about one hundredth of the main light emission amount).

<Group A monitor flash>
The group A remote optical adapter 110A that has received the monitor light emission instruction transmits the monitor light emission instruction to the connected electronic flash device 20A by wire communication. The electronic flash device 20A that has received the monitor light emission instruction performs monitor light emission at the target monitor light emission amount at time t1. The time from the time t0 when the electronic flash device 20A receives the monitor light emission instruction to the time t1 when the monitor light is emitted is called a light emission start time (= td1).

The camera 30 (CPU 306) performs a photometric process from time t1 while the monitor emits light, and causes the above arithmetic process for group A to be performed after the monitor emits light (Gr.A arithmetic process). By this arithmetic processing, the target main light emission amount of the electronic flash device 20A is calculated.
The timing at which the camera 30 (CPU 306) starts the photometric processing is after the elapse of the light emission start time (td1) after transmitting the monitor light emission instruction to the group A.

<Instruction of monitor light emission to group B performing optical communication>
At time t2, the camera 30 (CPU 306) transmits a monitor light emission instruction to the remote optical adapter 110B of the group B via the electronic flash device 20 by optical communication. The time t2 is a time that goes back by the light emission start time (td1) from the time t3 at which the monitor light emission interval T (the interval time) between the groups elapses from the time t1.

The monitor light emission instruction to the group B includes the instruction to the group B, the monitor light emission, and the target monitor light emission amount. As described above, the target monitor light emission amount is a predetermined value (about one hundredth of the main light emission amount).

<Group B monitor flash>
The group B remote optical adapter 110B that has received the monitor light emission instruction transmits the monitor light emission instruction to the connected electronic flash device 20B by wire communication. The electronic flash device 20B that has received the monitor light emission instruction performs monitor light emission at the target monitor light emission amount at time t3.

The camera 30 (CPU 306) performs the photometric processing while the monitor light emission is performed from the time t3, and causes the above calculation processing targeting the group B to be performed after the monitor light emission (Gr.B calculation processing). By this arithmetic processing, the target main light emission amount of the electronic flash device 20B is calculated.
The timing at which the camera 30 (CPU 306) starts the photometric processing is after the elapse of the light emission start time (td1) after transmitting the monitor light emission instruction to the group B.

<Instruction of monitor light emission to group D and group E that perform radio wave communication>
On the other hand, the camera 30 (CPU306) that started the release sequence processing at time t0 broadcasts a monitor light emission activation command to the remote wireless adapter 10D and the remote wireless adapter 10E via the master wireless adapter 10 at time t0 by radio communication. do. The radio wave communication during the release sequence processing repeats one-way transmission a plurality of times (for example, 10 times) without requesting a reply (ack) from each of the remote wireless adapters 10D and 10E.

<Group D monitor flash>
The monitor light emission of the remote wireless adapter 10D of the group D that performs radio wave communication is the same as in the case of the first embodiment. That is, the remote wireless adapter 10D that has received the monitor light emission activation command transmits the monitor light emission activation command to the connected electronic flash device 20D by wired communication. The electron flash device 20D of this example is the third group D that emits light from the monitor. Therefore, the electronic flash device 20D has a target monitor light emission amount at a time t5 when the monitor light emission interval T (interval time) × 2 between the groups elapses from the time t1 corresponding to the light emission timing of the first electronic flash device 10A. The monitor emits light with.

The camera 30 (CPU 306) performs a light measurement process from time t5 while the monitor emits light, and causes the above arithmetic process for the group D to be performed after the monitor emits light (Gr.D arithmetic process). By this arithmetic processing, the target main light emission amount of the electronic flash device 20D is calculated.
The light emission start time and the monitor light emission interval T to be included in the monitor light emission start command are determined so as to match the timing of the photometric processing with the timing of the monitor light emission.

<Group E monitor flash>
The monitor light emission of the remote wireless adapter 10E of the group E that performs radio wave communication is also the same as in the case of the first embodiment. That is, the remote wireless adapter 10E that has received the monitor light emission activation command transmits the monitor light emission activation command to the connected electronic flash device 20E by wired communication. The electronic flash device 20E of this example is the fourth group E that emits light from the monitor. Therefore, the electronic flash device 20E performs monitor light emission at the target monitor light emission amount at time t7 when the monitor light emission interval T (interval time) × 3 between the groups has elapsed from time t1.

The camera 30 (CPU 306) performs a photometric process from time t7 while the monitor emits light, and causes the above arithmetic process for the group E to be performed after the monitor emits light (Gr.E arithmetic process). By this arithmetic processing, the target main light emission amount of the electronic flash device 20E is calculated.
The light emission start time and the monitor light emission interval T to be included in the monitor light emission start command are determined so as to match the timing of the photometric processing with the timing of the monitor light emission.

The camera 30 (CPU 306) performs a predetermined total calculation process in preparation for the main shooting exposure at time t8, following the calculation process for the group E.

<Instruction of main light emission to group A and group B that perform optical communication>
At time t9 after the total calculation processing, the camera 30 (CPU306) transmits the main light emission instruction to the remote optical adapter 110A of the group A and the remote optical adapter 110B of the group B via the electronic flash device 20 by optical communication, respectively. do.

The main light emission instruction includes instructions for group A and group B, main light emission, and each target main light emission amount.

<Main emission of group A and group B>
The group A remote optical adapter 110A that has received the light emission instruction transmits the light emission instruction to the connected electronic flash device 20A by wire communication. Further, the group B remote optical adapter 110B that has received the main light emission instruction transmits the main light emission instruction to the connected electronic flash device 20B by wire communication.

The electron flash device 20A and the electron flash device 20B that have received the main light emission instruction store energy required for discharge light emission in the light emission control circuit 202, and wait for the main light emission trigger. At time t10, the camera 30 (CPU306) transmits the main light emission trigger to the remote optical adapter 110A of the group A and the remote optical adapter 110B of the group B via the electronic flash device 20 by optical communication. For example, the light emitting trigger causes the light emitting tube 201 to pulse light once with a small amount of light (for example, about one hundredth of the main light emitting amount).

The group A remote optical adapter 110A that has received the light emission trigger transmits the light emission trigger to the connected electronic flash device 20A by wire communication. Further, the group B remote optical adapter 110B that has received the light emission trigger transmits the light emission trigger to the connected electronic flash device 20B by wire communication.

The electron flash device 20A and the electron flash device 20B that have received the main light emission trigger perform the main light emission at their respective target main light emission amounts.

<Instructions for main light emission to groups D and E that perform radio wave communication>
On the other hand, at time t9 after the comprehensive calculation processing, the camera 30 (CPU306) further broadcasts the light emission activation command to the remote wireless adapter 10D and the remote wireless adapter 10E via the master wireless adapter 10 by radio wave communication. Since it is radio wave communication during release sequence processing, one-way transmission without requesting a reply (ack) from each remote wireless adapter 10D or 10E is repeated a plurality of times (for example, 10 times).

The main light emission activation command includes the main light emission timing (light emission start time from time t9 to time t10 = td2) and the target main light emission amount of each of the electronic flash devices 20D and 20E.

Remote wireless adapter 10D that received this flash activation command. The 10E transmits the main light emission activation command to the connected electronic flash devices 20D and 20E by wire communication, respectively.

<Main emission of group D and group E>
Upon receiving the main light emission activation command, the electronic flash device 20D and the electronic flash device 20E each perform the main light emission at the target main light emission amount at the time t10 corresponding to the main light emission timing (light emission start time = td2). The light emission start time = td2 to be included in the main light emission start command is determined so as to match the timing when the shutter 302 is fully opened (the start of the main shooting exposure) and the timing of the main light emission.
The timing of the main light emission trigger transmitted by the camera 30 (CPU 306) via the electronic flash device 20 is determined to correspond to the light emission start time = td2 included in the main light emission start command. As a result, the main light emission timings of the groups A and B in which the light emission instruction is given by optical communication and the main light emission timings of the groups D and E in which the light emission instruction is given by radio wave communication are aligned.

<Explanation of flowchart>
FIG. 16 is a flowchart illustrating a flow of shooting processing according to the second embodiment. When the CPU 306 of the camera 30 detects the pressing operation (shooting instruction) of the release switch (operating member 307) by the photographer, the CPU 306 starts the process according to the flowchart of FIG.

In step S1 of FIG. 16, the CPU 306 determines whether or not the communication methods are mixed. When the photographing system includes a wireless adapter that performs radio wave communication and a wireless adapter that performs optical communication, the CPU 306 positively determines step S1 and proceeds to step S2. When the imaging system does not have a wireless adapter for optical communication, the CPU 306 determines in denial of step S1 and proceeds to step S10 in FIG. 10, according to the first embodiment in which only the wireless adapter for radio wave communication exists. Perform the same process.
If the photographing system has only a wireless adapter for optical communication, the CPU 306 performs the processes after step S3, which will be described later.

In step S2, the CPU 306 causes the master wireless adapter 10 to transmit a monitor light emission activation command (monitor light emission activation packet) as radio wave communication processing, and proceeds to step S3 (time t0 in FIG. 15).

Based on the monitor light emission activation packet, the electronic flash devices 20D and 20E start the monitor light emission process after the lapse of the time specified in the time information described above (in this example, during the process of step S7 described later).

In step S3, the CPU 306 transmits a monitor light emission activation command to the electronic flash device 20 as an optical communication process, and proceeds to step S4 (time t0 in FIG. 15). The electronic flash device 20 emits modulated light with a monitor light emission instruction from the light emitting tube 201 based on the monitor light emission activation command.
Based on the monitor light emission instruction, the monitor light emission processing is started by the electronic flash devices 20A and 20B.

In step S4, the CPU 306 starts the metering process and proceeds to step S5. In step S5, the CPU 306 starts the calculation process of the target main emission amount and proceeds to step S6. In step S6, the CPU 306 determines whether or not the monitor light emission by optical communication has ended. When the monitor light emission is completed in the groups A and B, which are the targets of the monitor light emission, the CPU 306 positively determines step S6 and proceeds to step S7. If the monitor light emission has not been completed in the group A and the group B, which are the targets of the monitor light emission, the CPU 306 negatively determines the step S6 and returns to the step S3. When returning to step S3, the CPU 306 repeats the metering process in accordance with the monitor light emission of the remaining groups.

In step S7, the CPU 306 starts the metering process after the lapse of the time specified in the time information described above, and proceeds to step S8. In step S8, the CPU 306 starts the calculation process of the target main light emission amount and proceeds to step S9. In step S9, the CPU 306 determines whether or not the monitor light emission by radio wave communication has ended. When the monitor light emission is completed in the groups D and E, which are the targets of the monitor light emission, the CPU 306 positively determines step S9 and proceeds to step S50 in FIG.

On the other hand, if the monitor light emission has not been completed in the groups D and E, which are the targets of the monitor light emission, the CPU 306 determines that step S9 is negative and returns to step S7. When returning to step S7, the CPU 306 repeats the metering process in accordance with the monitor light emission of the remaining groups.

When the process proceeds to step S50 in FIG. 10, the CPU 306 performs the process described with reference to FIG. 10, but in step S70, the following process is performed. That is, the CPU 306 transmits the main light emission activation command to the electronic flash device 20 as optical communication processing, and broadcasts the main light emission activation command to the remote wireless adapters 10D and 10E via the master wireless adapter 10 as radio wave communication processing. (Time t9 in FIG. 15).
As a result, the electronic flash device 20 emits the modulated light on which the main light emission instruction is placed from the light emitting tube 201 based on the main light emission activation command.

Further, the CPU 306 transmits the main light emission trigger to the electronic flash device 20 as an optical communication process (time t10 in FIG. 15). The electronic flash device 20 causes the arc tube 201 to pulse light with a small amount of light based on the present light emission trigger.

By the above-described processing, the electronic flash devices 20A, 20B, 20D and 20E perform the main light emission at time t10 in FIG. 15 when the shutter 302 is fully opened.

According to the second embodiment described above, the following effects can be obtained.
(1) The photographing system that functions as a light emission control device performs optical communication using light to each of a plurality of electronic flash devices 20A, 20B, 20D, and 20E groups including at least one electronic flash device. The CPU 306, which determines whether to perform radio wave communication using radio waves, and the group, which is determined by the CPU 306 to perform optical communication using light, are controlled to perform optical communication using light, and the CPU 306 is used. It has a CPU 306 that controls the group determined to perform radio wave communication using radio waves so as to perform radio wave communication using radio waves. As a result, when a group that performs radio wave communication and a group that performs optical communication coexist, it is possible to appropriately transmit control information for the electronic flash devices 20A, 20B, 20D, and 20E.

(2) The photographing system is an electronic flash device 20 that transmits the first control information by optical communication using light to a group determined to perform optical communication using light by the CPU 306, and radio waves by the CPU 306. Since it has a master radio adapter 10 that transmits the second control information by radio wave communication using radio waves to the group determined to perform radio wave communication using radio waves, it is possible to perform optical communication with the group that performs radio wave communication. When the group to perform is mixed, the control information for the electronic flash devices 20A, 20B, 20D, and 20E can be appropriately transmitted.

(3) The first control information and the second control information include a shooting auxiliary light emission instruction for the electronic flash devices 20A, 20B, 20D, and 20E, and the CPU 306 of the camera 30 receives the shooting instruction and then the electronic flash. The first control information is transmitted from the device 20 and the second control information is transmitted from the master wireless adapter 10. As a result, when a group that performs optical communication and a group that performs radio wave communication coexist, it is possible to appropriately transmit light emission instructions to the electronic flash devices 20A, 20B, 20D, and 20E.

(4) The CPU 306 of the camera 30 causes the electronic flash device 20 to transmit the first control information instructing the monitor light emission, and then causes the master wireless adapter 10 to transmit the second control information instructing the monitor light emission. By first transmitting the first control information to the group that communicates by optical communication, it is possible to allow time from the monitor light emission to the main light emission. As a result, for example, when the electronic flash device 20 that transmits the first control information emits the main light, the vacant time is set to the storage time of the energy required for the main light emission in the light emission control circuit 202 of the electronic flash device 20. It is convenient to use.

(5) The master wireless adapter 10 repeatedly transmits the second control information by radio wave communication a plurality of times (for example, 10 times). It is possible to increase the probability that control information will be received on the receiving side in an environment with poor communication conditions (for example, an environment with a lot of electromagnetic noise or an environment with a large amount of interference with radio waves transmitted by other communication devices). can. In addition, it has a judgment unit for determining the communication state, and when it is determined that the communication state is worse than the predetermined threshold value (more environmental noise than the predetermined threshold value), it is determined that the communication state is worse than the predetermined threshold value. The number of times the second control information is transmitted may be increased as compared with the case where the second control information is not transmitted.

(6) The CPU 306 of the camera 30 detects the electronic flash devices 20D and 20E that accept the communication by the master wireless adapter 10 from the electronic flash devices 20A, 20B, 20D and 20E, and radio waves the detected electronic flash devices 20D and 20E. It is a group that communicates using. As a result, the setting work can be reduced as compared with the case where the photographer manually performs all the settings.
Further, the CPU 306 has a group having an electronic flash device capable of only optical communication, a group having an electronic flash device capable of only radio wave communication, and an electronic flash device capable of optical communication and radio wave communication (optical communication only). If there is a group that does not have an electronic flash device that can only perform radio wave communication or an electronic flash device that can only perform radio wave communication, the group that has an electronic flash device that can only perform optical communication is determined as a group that performs communication using light. Then, after determining the group having an electronic flash device capable of only radio wave communication as a group performing communication using radio waves, the group having an electronic flash device capable of optical communication and radio wave communication is used for communication using light. It may be determined as a group to perform or a group to perform communication using radio waves.
Further, the CPU 306 may detect that the electronic flash device capable of only optical communication and the electronic flash device capable of only radio wave communication are set in the same group by the photographer, and may display a warning.

The following modifications are also within the scope of the invention, and one or more of the modifications can be combined with the above-described embodiment.
(Modification 2-1)
In the second embodiment, an example has been described in which an electronic flash device for which a light emission instruction is given by radio wave communication is determined by an operation by a photographer. The CPU 306 of the camera 30 may automatically make the above determination. The CPU 203 of the electronic flash device requests a wireless connection to the master wireless adapter 10 via a remote wireless adapter, for example, when the power is turned on. This request includes information indicating the existence of the self (electronic flash device) and the set group. The group is determined in advance by the photographer's operation.

The CPU 306 of the camera 30 recognizes that the electronic flash device (remote wireless adapter) that has requested the wireless connection is a group capable of radio wave communication, gives a light emission instruction to this group by radio wave communication, and does not give a light emission instruction by optical communication. I will do it.
On the other hand, the CPU 306 gives a light emission instruction by optical communication to a group of electronic flash devices (remote optical adapters) that are determined to give a light emission instruction by optical communication by an operation by the photographer, and emits light instruction by radio wave communication. I will not do it.

(Modification 2-2)
A remote dual-compatible adapter having both a radio wave communication function of the remote wireless adapter and an optical communication function of the remote optical adapter may be provided, and an electronic flash device may be attached to the remote dual-compatible adapter. The electronic flash device attached to the remote compatible adapter can accept both a light emission instruction by radio wave communication and a light emission instruction by optical communication. In the modification 2-2, the CPU 306 of the camera 30 usually gives a light emission instruction to the electronic flash device attached to the remote compatible adapter by radio wave communication.

That is, the electronic flash device according to the modified example 2-2 has a light emitting tube 201 that emits an auxiliary light for photography, a remote compatible adapter that communicates control information including a light emission instruction of the auxiliary light for photography, and a radio wave. Even when the CPU 203 is received by both remote compatible adapters that communicate by communication method and the light emitting tube 201 is made to emit light when the light emission instruction by radio wave communication is received by the remote dual compatible adapter, the light emission instruction by optical communication is remote. It includes a CPU 203 that emits light from the arc tube 201 when received by both compatible adapters.

For example, the communication environment may be poor due to radio wave interference, and the remote compatible adapter may not be able to correctly receive the light emission instruction by radio wave communication. However, according to the modification 2-2, even if the light emission instruction is to be received by radio wave communication, it is possible to emit light by triggering the light emission by another electronic flash device. That is, the remote compatible adapter receives the light emitted by the other electronic flash device and transmits it to the electronic flash device as a light emission trigger. As a result, it is possible to cause light emission even when the light emission instruction by radio wave communication is not normally transmitted.

Contrary to the above, even if the light emission instruction is to be received by optical communication, the light may be emitted when the light emission instruction by radio wave communication is received. As a result, it is possible to emit light even when the light emission instruction is not normally transmitted, such as when the pulsed light of optical communication does not reach.
Further, in the above-described embodiment, an example in which the electronic flash devices 20A to 20E are controlled by using the CPU 306 provided in the camera 30 and the master wireless adapter 10 provided in the camera 30 has been described, but the present invention is limited to this. It's not something. For example, the function of the CPU 306 and the function of the master wireless adapter 10 may be provided in the electronic flash device 20. In this case, the electron flash device 20 can control the electron flash devices 20A to 20E. For example, it is decided that the electronic flash device 20 controls a group determined to perform optical communication using light to perform optical communication using light, and performs radio wave communication using radio waves. It is possible to perform radio wave communication using radio waves to other groups.

(Third Embodiment)
In the third embodiment, an example of calculation of the target main emission amount performed by the CPU 306 of the camera 30 will be described. As described above, the CPU 306 calculates the target light emission amount (target main light emission amount) at the time of the main light emission of the electronic flash device based on the photometric signal output from the photometric sensor 304.

In order to make the explanation easy to understand, the case where the electronic flash device 20 mounted on the camera 30 is used in the photographing system of FIG. 1 will be described.

For example, the shooting scene is as follows. The photographer shoots the main subject under a night background (for example, the moon, illuminations, etc.) that is brighter than the main subject (for example, a person). At this time, the electronic flash device 20 is made to emit light as an auxiliary light for photographing. Here, the main subject refers to a subject within the range of the luminous flux of the illumination light emitted by the electronic flash device 20, that is, a subject whose exposure can be controlled by the shooting auxiliary light. The background refers to a subject that the luminous flux emitted by the electronic flash device 20 does not reach, that is, a subject that cannot be exposed by the shooting auxiliary light.

The camera 30 has a first exposure mode that not only controls the main subject to the proper exposure but also makes the background as close to the proper exposure as possible, and a second exposure mode that exclusively controls the main subject to the proper exposure (for example, the first shooting mode). It is configured so that it can be switched between (mode) in which the background is properly exposed compared to when it is set. In the third embodiment, for example, the exposure mode changeover switch constituting the operation member 307 switches between the first exposure mode and the second exposure mode.

<Explanation of flowchart>
In FIGS. 17 and 18, the CPU 306 of the camera 30 starts by detecting an on operation of the main switch (307) by the photographer (a half-press operation of the release switch (operation member 307) or an icon tap operation may be performed). It is a flowchart which illustrates the flow of the camera processing to make. When the CPU 306 is in the ON state, the processing according to FIGS. 17 and 18 is repeated. In step S210 of FIG. 17, the CPU 306 starts the shooting preparation operation, performs photometric processing, and proceeds to step S220. Specifically, the area sensor 304 is made to perform the accumulation process in a state where the electron flash device 20 does not emit light.

In step S220, the CPU 306 performs arithmetic processing as follows. That is, based on the output signal from the area sensor 304 obtained in step S210, the field brightness BV due to the background light is calculated using the following equation (1).
BV = Log2 (Vo) + BvConst …… (1)
In the above equation (1), Log2 () is a function that returns the logarithm of the argument with 2 as the base. Vo is a value obtained by A / D converting the output of the area sensor 304 in step S210, and is a value proportional to the amount of light. Vo takes a value of 0 to 1023, for example. BvConst is a constant term for calculating the luminance value.

In step S230, the CPU 306 determines whether or not it is in the first exposure mode. When the CPU 306 has been switched to the first exposure mode, it determines affirmatively in step S230 and proceeds to step S240, and when it has been switched to the second exposure mode, it negatively determines step S230 and proceeds to step S290.

In step S240, the CPU 306 determines the first imaging sensitivity and proceeds to step S250. The first imaging sensitivity SVPre1 is calculated by the following equation (2).
SVPre1 = AV + TV-BV-SvOfs …… (2)
In the above equation (2), AV is an aperture value at the time of shooting, and the unit system is APEX. Further, the TV is set to the shutter second time at the time of shooting, and the unit system is APEX. Further, the BV is the field brightness BV due to the background light calculated by the above equation (1), and the unit system is APEX. SvOfs is a value that is added to the imaging sensitivity when shooting with an electronic flash device, and is determined depending on a fixed value or the shooting mode setting, sync mode, initial setting sensitivity, and flash device used set by the user. do.

In step S290, the CPU 306 determines the second imaging sensitivity and proceeds to step S250. The second imaging sensitivity SVPre2 is calculated by the following equation (3).
SVPre2 = SVConst …… (3)
In the above equation (3), SVConst is a fixed value or a value preset by the photographer and does not depend on the field brightness BV.

In step S250, the CPU 306 determines whether or not there is a shooting instruction. When the CPU 306 detects the pressing operation (shooting instruction) of the release switch (operating member 307), it positively determines step S250 and proceeds to step S260, and detects the pressing operation (shooting instruction) of the release switch (operating member 307). If not, step S250 is negatively determined and the process ends.

In step S260, the CPU 306 transmits a monitor light emission instruction to the electronic flash device 20 and proceeds to step S270. As a monitor light emission instruction, for example, the monitor light emission activation packet described above is sent. As a result, the electronic flash device 20 starts the monitor light emission after the lapse of the time specified by the time information described above.

In step S270, the CPU 306 performs photometric processing and proceeds to step S280. Specifically, the area sensor 304 is made to perform the accumulation process after the lapse of the time specified by the time information described above. As a result, the area sensor 304 receives the reflected light from the subject in accordance with the timing of the monitor emission.

In step S280, the CPU 306 performs arithmetic processing as follows to determine the provisional main emission amount GNTemp. That is, it is calculated by the following equation (4) based on the output signal from the area sensor 304 obtained in step S270.
GNTemp = -Log2 (PreVo) -SV + GNConst ... (4)
In the above equation (4), GNTemp is an APEX unit system in which the guide number is logarithmic. PreVo is a value obtained by A / D converting the output of the area sensor 304 when the monitor light is emitted in step S270. SV is the imaging sensitivity determined in step S240 or S290. GNConst is a constant for calculating the amount of light emitted depending on the area sensor 304 and the photographing lens 301.

In step S300 of FIG. 18, the CPU 306 determines whether or not it is in the first exposure mode. When the CPU 306 has been switched to the first exposure mode, it determines affirmatively in step S300 and proceeds to step S310, and when it has been switched to the second exposure mode, it negatively determines step S300 and proceeds to step S370.

In step S310, the CPU 306 controls the change of the first imaging sensitivity. First, the CPU 306 calculates the maximum value ΔSVMax of the increase width of the imaging sensitivity by the following equation (5) so that the amount of change in the imaging sensitivity does not exceed the background light exposure.
ΔSVMax = AV + TV-BV-SVPre1 …… (5)
In the above equation (5), AV is the aperture value at the time of shooting, TV is the shutter second time setting at the time of shooting, and the unit system is APEX in each case. BV is the field brightness BV due to the background light calculated by the above equation (1), and the unit system is APEX. Further, SVPre1 is the first imaging sensitivity calculated by the above equation (2), and the unit system is APEX.

Next, the CPU 306 determines the change amount ΔSV of the imaging sensitivity by the following equation (6).
ΔSV = GNMin-GNTemp …… (6)
In the above equation (6), GNMin is the minimum amount of light emitted from the electronic flash device 20, and is an APEX unit system in which the guide number is logarithmically used. The guide number of the minimum light emission amount is transmitted in advance from the electronic flash device 20 to the CPU 306 by wire communication. GNTemp is a provisional emission amount calculated by the above equation (4).

When the ΔSV calculated by the above equation (6) is larger than the ΔSVMax calculated by the above equation (5), the CPU 306 replaces the ΔSV with the ΔSVMax. The CPU 306 further calculates the imaging sensitivity SV used for photographing by the following equation (7), and proceeds to step S320.
SV = SVPre1 + ΔSV …… (7)
In the above equation (7), SVPre1 is the first imaging sensitivity calculated by the above equation (2), and the unit system is APEX.

The imaging sensitivity SV calculated by the above equation (7) raises the sensitivity in the shooting preparation state so as to make the exposure of the background light appropriate, and controls the main light emission amount of the electronic flash device 20 as much as possible. The imaging sensitivity is such that it is minimized within. For example, in the case of shooting a person with a night view as the background, control is performed to bring both the night view of the background that the light flux emitted by the electronic flash device 20 does not reach and the person that the light flux emitted by the electronic flash device 20 reaches to approach the proper exposure. be able to.

In step S370 in which the above-mentioned step S300 is negatively determined and the process proceeds, the CPU 306 controls the change of the second imaging sensitivity. When the provisional emission amount GNTemp satisfies the following equation (8), the CPU 306 calculates the sensitivity change amount ΔSV by the following equation (9) so as to increase the imaging sensitivity.
GNTemp> GNMax …… (8)
ΔSV = GNMax-GNTemp …… (9)
In the above equations (8) and (9), GNMax is the maximum amount of light emitted from the electron flash device 20, and is an APEX unit system in which the guide number is logarithmic. The guide number of the maximum light emission amount is transmitted in advance from the electronic flash device 20 to the CPU 306 by wire communication.

The CPU 306 calculates the maximum value ΔSVMax of the increase width of the imaging sensitivity by the following equation (10) so that the amount of change in the imaging sensitivity does not exceed the background light exposure.
ΔSVMax = AV + TV-BV-SVPre2… (10)
In the above equation (10), AV is the aperture value at the time of shooting, TV is the shutter second time setting at the time of shooting, and the unit system is APEX in each case. BV is the field brightness BV due to the background light calculated by the above equation (1), and the unit system is APEX. Further, SVPre2 is the second imaging sensitivity calculated by the above equation (3), and the unit system is APEX.

When the ΔSV calculated by the above equation (9) is larger than the ΔSVMax calculated by the above equation (10), the CPU 306 replaces the ΔSV with the ΔSVMax.

On the other hand, when the provisional main emission amount GNTemp satisfies the following equation (11), the CPU 306 calculates the sensitivity change amount ΔSV by the following equation (12) so as to lower the imaging sensitivity.
GNTemp <GNMin …… (11)
ΔSV = GNMin-GNTemp …… (12)
In the above equations (11) and (12), GNMin is the minimum amount of light emitted from the electron flash device 20. As described above, the guide number of the minimum light emission amount is transmitted in advance from the electronic flash device 20 to the CPU 306 by wire communication.

The CPU 306 calculates the imaging sensitivity SV used for photographing by the following equation (13) regardless of whether the imaging sensitivity is increased or decreased, and proceeds to step S320.
SV = SVPre2 + ΔSV …… (13)
The imaging sensitivity SV calculated by the above equation (13) is, for example, an imaging sensitivity that maximizes the main light emission amount of the electronic flash device 20 within the control range as much as possible, and does not consider the exposure of the background light. Therefore, the imaging sensitivity SV calculated by the above equation (13) is lower than the imaging sensitivity SV calculated by the above equation (7). For example, in the case of shooting a person with a night view as a background, the person to which the light flux emitted by the electronic flash device 20 reaches can be controlled to an appropriate exposure, but the background to which the light flux emitted by the electronic flash device 20 does not reach is underexposed. In some cases.

In step S320, the CPU 306 performs arithmetic processing as follows to change the provisional light emission amount GNTemp. That is, the main emission amount guide number GN at the time of shooting is calculated by the following equation (14) in correspondence with the change amount ΔSV of the imaging sensitivity calculated and changed in step S310 or step S370.
GN = Power√2 (GNTemp-ΔSV) …… (14)
In the above equation (14), Power√2 () is a function that returns the argument power of √2.

In step S330, the CPU 306 initiates an exposure sequence. Specifically, the shutter drive device 305 starts the front curtain traveling of the shutter 302, and the process proceeds to step S340.

In step S340, the CPU 306 transmits the main light emission instruction to the electronic flash device 20 and proceeds to step S350. As the main light emission instruction, for example, the above-mentioned main light emission activation packet is sent. As a result, the electronic flash device 20 starts the main light emission after the lapse of the time specified by the time information described above.

In step S350, when the rear curtain running of the shutter 302 by the shutter drive device 305 starts, the CPU 306 reads an image signal from the image sensor 303, performs predetermined image processing, and proceeds to step S360.

In step S360, the CPU 306 records the image signal after the image processing on a recording medium 350 such as a memory card, and ends a series of shooting processes.

According to the third embodiment described above, the following effects can be obtained.
(1) The camera 30 uses a CPU 306 capable of setting at least one of a first exposure mode and a second exposure mode, and a shooting auxiliary light in the first exposure control when the CPU 306 is set to the first exposure mode. When the CPU 306 is set to the second exposure mode, the exposure of the previous shooting is controlled, and when the CPU 306 is set to the second exposure mode, the CPU 306 that controls the exposure of the shooting using the shooting auxiliary light with the second exposure control different from the first exposure control is used. Have. This enables exposure control of the camera with a high degree of freedom. For example, in the first exposure control, the CPU 306 sets the first sensitivity to control the exposure, and in the second exposure mode, the CPU 306 sets a second sensitivity different from the first sensitivity to control the exposure. As a result, it is possible to shoot with a plurality of different exposures.

(2) The CPU 306 of the camera 30 controls the exposure so that the main subject and the background are closer to the proper exposure when the first exposure mode is set than when the second exposure mode is set. .. As a result, it is possible to shoot with a plurality of different exposures. note that. The CPU 306 may control the exposure so that the background is not closer to the proper exposure when the second exposure mode is set than when the first exposure mode is set.

(3) The CPU 306 of the camera 30 sets at least one of the first exposure mode and the second exposure mode based on the operation by the photographer. It is possible to shoot with multiple exposures according to the photographer's intention.

(4) When the CPU 306 of the camera 30 determines the main light emission amount at the time of the main light emission in the first exposure mode based on the reflected light amount when the electronic flash device 20 that emits the shooting auxiliary light emits the monitor light before the main light emission. By setting the first sensitivity to, the amount of this light emission is minimized in the control range. Since the first sensitivity can be raised to a high level by minimizing the amount of this light emission, it is possible to bring the background to which the shooting auxiliary light does not reach close to the proper exposure. Further, in the first exposure mode, the main light emission amount may be reduced as compared with the case where the second exposure mode is set, and the sensitivity may be increased as compared with the case where the second exposure mode is set. This is because the background to which the shooting auxiliary light does not reach can be brought closer to the proper exposure as compared with the case where the second exposure mode is set.

(5) When the CPU 306 of the camera 30 determines the main light emission amount at the time of the main light emission in the second exposure mode based on the reflected light amount when the electronic flash device 20 that emits the shooting auxiliary light emits the monitor light before the main light emission. By setting the second sensitivity to, the amount of this light emission is maximized in the control range. By maximizing the amount of this light emission, it is possible to bring the main subject to which the shooting auxiliary light reaches closer to the proper exposure. For example, in the first exposure mode, the first light emission amount and the first sensitivity at the time of the main light emission are determined based on the reflected light amount when the electronic flash device 20 emits light from the monitor, and in the second exposure mode, the electronic flash device 20 When the second light emission amount and the second sensitivity at the time of the main light emission are determined based on the reflected light amount when the 20 emits light from the monitor, the first light emission amount is preferably lower than the second light emission amount. .. Moreover, it is preferable that the first sensitivity is higher than the second sensitivity.

(6) Since the CPU 306 of the camera 30 acquires the information of the control range (guide number of the minimum light emission amount and the guide number of the maximum light emission amount) from the electronic flash device 20 and determines the first sensitivity or the second sensitivity. Control can be appropriately performed according to the capability of the electronic flash device 20.

(7) The CPU 306 of the camera 30 sets the first sensitivity in the first exposure mode to be higher than the sensitivity in the shooting preparation state. As a result, the background to which the shooting auxiliary light does not reach can be brought closer to the proper exposure.
Further, for example, the second shooting mode may be a mode in which the background is properly exposed as compared with the case where the first shooting mode is set, and the second shooting mode is set to the first shooting mode. The main subject may not be properly exposed as compared with the case where the main subject is properly exposed, and the main subject may be properly exposed in the second shooting mode as in the case where the first shooting mode is set.
Further, for example, in the second shooting mode, the background may not be properly exposed as compared with the landscape shooting mode for shooting a landscape, or the main subject may be properly exposed as compared with the landscape shooting mode. However, the background may be properly exposed as compared with the portrait mode in which a person is photographed, or the main subject may not be as compared with the portrait mode.

The following modifications are also within the scope of the invention, and one or more of the modifications can be combined with the above-described embodiment.
(Modification 3-1)
In the third embodiment, switching between the first exposure mode in which the main subject is controlled to the proper exposure and the background is as close to the proper exposure as possible and the second exposure mode in which the main subject is exclusively controlled to the proper exposure is switched. , The exposure mode changeover switch constituting the operation member 307 is operated to switch. Instead, the CPU 306 may automatically switch between the first exposure mode and the second exposure mode in conjunction with the shooting scene mode.

The CPU 306 switches to the first exposure mode when the night view portrait mode is selected as the shooting scene mode. In the night view portrait mode, the above switching is performed based on the idea that it is preferable to control the person and the background to an appropriate exposure. Further, when the portrait mode is selected as the shooting scene mode, the mode is switched to the second exposure mode. This is because in the portrait mode, it is preferable to control the person to an appropriate exposure.

Further, the CPU 306 switches to the first exposure mode when the slow sync mode is selected as the shooting scene mode. In the slow sync mode, the above switching is performed based on the idea that it is preferable that the background also approaches the proper exposure.

Furthermore, the CPU 306 switches to the second exposure mode when the normal sync mode is selected as the shooting scene mode. In the normal sync mode, the above switching is performed based on the idea that the background exposure is not taken into consideration.

(Modification example 3-2)
Switching between the first exposure mode and the second exposure mode is performed when the electronic flash device built in the camera emits light and when the electronic flash device 20 configured to be externally attached to the camera 30 as described above emits light. You may switch with. The CPU 306 switches to the first exposure mode when, for example, emits light from the electronic flash device built in the camera, and when the external electronic flash device 20 (including the case where remote emission control is performed by radio wave communication or optical communication) emits light. 2 Switch to exposure mode.

Generally, since the electronic flash device built in the camera has a small light emission amount guide number, the above switching is performed based on the idea that the sensitivity for increasing the imaging sensitivity may be changed.

(Modification example 3-3)
The switching between the first exposure mode and the second exposure mode may be switched between the case of shooting with a multi-flash photography system and the case of shooting with one light (single light). The CPU 306 switches to the second exposure mode when shooting with, for example, a multi-flash flash photographing system, and switches to the first exposure mode when shooting with one light.

Generally, in the case of a multi-flash photography system in which exposure is controlled by illumination light emitted by a plurality of electronic flash devices, the above switching is performed based on the idea that the imaging sensitivity is not desired to be changed by the camera.

(Modification example 3-4)
The switching between the first exposure mode and the second exposure mode may be switched using the image recognition result. For example, the CPU 306 switches to the first exposure mode when it detects illumination or the like on the background of the main subject, and switches to the second exposure mode when it does not detect illumination or the like on the background. If there is illumination in the background, the above switching is performed based on the idea that it is preferable that the background also approaches the proper exposure.

Image recognition for detecting illumination or the like from the background of the main subject can be performed based on, for example, an image obtained by the photometric sensor 304. When the camera 30 is not provided with a photometric sensor 304 different from the image sensor 303, illumination or the like may be detected from the background based on the preview image before shooting obtained by the image sensor 303.

(Modification example 3-5)
When switching between the first exposure mode and the second exposure mode using the image recognition result, the switching may be performed according to the ratio of the main subject to the screen. For example, the CPU 306 switches to the second exposure mode when the area ratio of the person of the main subject to the screen is small, and switches to the first exposure mode when the area ratio of the person of the main subject to the screen is not small. Generally, when the person is small (the background is wide), the photographer has an intention to take a picture of the background as well. Therefore, the above switching is performed based on the idea that it is preferable that the background is also close to the proper exposure.

As described above, the CPU 306 of the camera 30 switches between the first exposure mode and the second exposure mode according to the set shooting scene mode, and the first exposure mode and the second exposure mode are set depending on whether or not the slow sync mode is set. It is set to multi-exposure shooting mode, which switches between the first exposure mode and the second exposure mode depending on whether the shooting auxiliary light is emitted from the electronic flash device built in the camera or from the external electronic flash device 20. The first exposure mode and the second exposure mode are switched depending on whether or not the subject is set, the first exposure mode and the second exposure mode are switched based on the recognition result of the object in the background of the main subject, and the main subject is the screen. The usability of the camera 30 can be improved by switching between the first exposure mode and the second exposure mode based on the ratio of the first exposure mode to the second exposure mode.

Although various embodiments and modifications have been described above, the present invention is not limited to these contents. Other aspects conceivable within the scope of the technical idea of the present invention are also included within the scope of the present invention.

10 ... Master wireless adapter 10A, 10B, 10C, 10D, 10E ... Remote wireless adapter 20, 20A, 20B, 20C, 20D, 20E ... Electronic flash device 30 ... Camera 72, 92 ... Main emission timing 74, 83 ... Target main emission Quantity 101 ... Antenna 102 ... Communication circuits 105, 203, 306 ... CPU
110A, 110B ... Remote optical adapter 201 ... Light emitting tube 202 ... Light emission control circuit 302 ... Shutter 307 ... Operating member 308 ... Memory 309 ... Display unit 350 ... Recording medium

Claims (11)

A determination unit that determines whether to perform communication using light or communication using radio waves for each of a plurality of light emitting device groups including at least one light emitting device for shooting assistance.
It is possible to control the light emitting device group, which has been determined by the determination unit to perform communication using light, to perform communication using light, and to perform communication using radio waves by the determination unit. A control unit that controls the determined light emitting device group so as to perform communication using radio waves, and
A light emission control device comprising. In the light emission control device according to claim 1,
A first communication unit that transmits first control information by communication using light to the light emitting device group determined to perform communication using light by the determination unit.
A second communication unit that transmits second control information by communication using radio waves to the light emitting device group determined to perform communication using radio waves by the determination unit.
A light emission control device comprising. In the light emission control device according to claim 2,
Wherein the first control information and the second control information includes a light-emitting operation of the light for the imaging assist relative to the light emitting device,
The control unit is a light emitting control device that transmits the first control information from the first communication unit and the second control information from the second communication unit after receiving a shooting instruction. In the light emission control device according to claim 3,
The control unit is a light emission control device that transmits the first control information instructing preliminary light emission from the first communication unit, and then transmits the second control information instructing preliminary light emission from the second communication unit. In the light emission control device according to any one of claims 2 to 4.
The second communication unit is a light emission control device that repeatedly transmits the second control information a plurality of times. In the light emission control device according to any one of claims 2 to 5,
When the control unit detects that the light emitting device that accepts the communication by the second communication unit is included in the plurality of light emitting device groups, the control unit refers to the light emitting device group including the detected light emitting device. A light emission control device that controls communication using radio waves. In the light emission control device according to any one of claims 1 to 6.
A light emitting part that emits light to assist shooting,
A communication unit capable of at least one of communication using light and communication using radio waves,
It has a setting unit for setting to receive a control signal for controlling the light emitting unit by either communication using light or communication using radio waves.
Even when the control unit is set to receive the control signal by communication using light by the setting unit, when the control signal is received by communication using radio waves by the communication unit, the control unit may receive the control signal. A light emitting control device that controls the light emitting unit based on the control signal received by communication using radio waves. In the light emission control device according to any one of claims 1 to 6.
A light emitting part that emits light to assist shooting,
A communication unit capable of at least one of communication using light and communication using radio waves,
It has a setting unit for setting to receive a control signal for controlling the light emitting unit by either communication using light or communication using radio waves.
Even when the control unit is set to receive the control signal by communication using radio waves by the setting unit, when the control unit receives the control signal by communication using light by the communication unit, the control unit may receive the control signal. A light emission control device that controls the light emitting unit based on the control signal received by communication using light. The light emission control device according to any one of claims 1 to 8.
An imaging unit that captures images from the optical system and
An imaging device comprising. The first light emitting part for shooting assistance and
An instruction regarding light emission of the second light emitting unit is transmitted to a device having a second light emitting unit for photographing assistance different from the first light emitting unit by communication using the light emitted from the first light emitting unit. A first communication unit having an optical communication type wireless function for receiving an instruction regarding a function and light emission of the first light emitting unit, and a first communication unit.
A function of transmitting an instruction regarding light emission of the third light emitting unit and light emission of the first light emitting unit to a device having a third light emitting unit for photographing assistance different from the first light emitting unit by communication using radio waves. A second communication unit equipped with a radio communication type wireless function that receives instructions regarding
With
A lighting device that transmits an instruction to make the second light emitting unit emit light at time T by the first communication unit, and transmits an instruction to make the third light emitting unit emit light at time T by the second communication unit. An imaging device connected to the lighting device according to claim 10.
An image sensor that captures an image of the subject and outputs a signal,
The image pickup is performed in an image pickup accompanied by provisional light emission, in which an image of the subject is imaged, the first sensitivity of the image pickup element is set based on a signal output from the image pickup element, and the amount of light emitted by the lighting device is determined during shooting. A setting unit capable of switching between a first control for setting the sensitivity of the element to the first sensitivity and a second control for setting the sensitivity of the image sensor to a predetermined second sensitivity in imaging accompanied by the provisional light emission.
Based on the settings in the setting unit, the illumination is the first light amount based on the image pickup with the temporary light emission based on the first control, or the second light amount based on the image pickup with the temporary light emission based on the second control. A setting unit that sets the amount of light emitted by the device,
An imaging device comprising.

Images