JP6733176B2 - Control device, electronic device, control system, and imaging device - Google Patents

Description

The present invention relates to a control device, an electronic device , a control system, and an imaging device .

2. Description of the Related Art There is known a flash photography system in which a strobe device is caused to emit light by radio control to take a picture (see Patent Document 1). The conventional technology has a problem that it is difficult to accurately match the operation timing between different devices.

JP, 2013-115731, A

A control device according to a first aspect of the present invention communicates with an external device, and transmits a first signal indicating a first time and a second signal indicating a second time shorter than the first time, and a communication unit, When the communication unit transmits the first signal to the external device and receives a signal indicating that the time difference between the first time and the second time has elapsed from the external device, the image pickup device of the camera is initialized. And a processing unit that executes a shutter opening driving process.
In the electronic device according to the second aspect of the present invention, a communication unit that communicates with an external device, a timer unit that measures time, a first signal indicating a first time and a second signal indicating a time difference by the communication unit are the external device. When the second time is received by the communication unit, the second time is shorter than the first time by the time difference, and when the second time is measured by the time measurement unit, the communication unit sends a signal to the external device. The communication unit communicates with the camera, and the time difference is based on the time required to drive the shutter of the camera to open and the time required to initialize the image sensor of the camera. It is determined.
A third aspect of the present invention is an image pickup apparatus, wherein a communication unit that communicates with an electronic device mounted on the image pickup apparatus, and a first signal indicating a first time is transmitted to the electronic device by the communication unit. And a processing unit that executes processing when a second signal indicating that a second time shorter than the first time is timed is received from the electronic device.
A fourth aspect of the present invention is an electronic device mounted on an imaging device, the communication unit communicating with the imaging device, a timekeeping unit for timing, and a first signal indicating a first time by the communication unit, When a signal indicating a time difference is received from the imaging device, the time measuring unit measures a second time shorter than the first time by the time difference, and the time measuring unit measures the second time, And a control unit that causes the communication unit to transmit the second signal to the imaging device.
A fifth aspect of the present invention is a control system for transmitting and receiving control information between an imaging device having a timekeeping unit different from each other and an electronic device mounted on the imaging device, wherein The electronic device transmits a first signal indicating one hour, and after the electronic device receives the first signal and then measures a second time shorter than the first time by the electronic device, the second time is sent to the imaging device. After transmitting the second signal indicating that the time has been counted, the imaging device starts processing based on the timing measured by the imaging device after receiving the second signal.

It is a figure which illustrates the structure of the imaging system by one Embodiment. It is a block diagram which illustrates the composition of a camera, a master wireless adapter, an electronic flash device (illumination device), a remote wireless adapter, and a remote electronic flash device (remote illumination device). It is a figure explaining wireless communication. It is a figure which illustrates the light emission timing at the time of multi-flash photography. It is a figure explaining operation|movement performed from time t5 to time t9. It is a flow chart which illustrates the flow of imaging processing.

Hereinafter, embodiments for carrying out the invention will be described with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of an image capturing system according to an embodiment. The photographing system of FIG. 1 is a multi-flash photographing system including a camera 30 equipped with both a master wireless adapter 10 and an electronic flash device 20, and a remote electronic flash device 20A equipped with a remote wireless adapter 10A. is there.

In FIG. 1, the camera 30, the electronic flash device 20, and the master wireless adapter 10 are physically connected. On the other hand, the camera 30 and the remote electronic flash device 20A (and the remote wireless adapter 10A) are not physically connected to each other, and are arranged apart (separated) from each other. That is, this photographing system is a remote multi-flash flash photographing system.

In the present embodiment, the electronic flash device 20 and the remote electronic flash device 20A will be described as electronic flash devices having the same structure (having the same type or the same function) structurally. However, even if the electronic flash device 20 and the remote electronic flash device 20A do not necessarily have the same structure in structure, they may be combined with each other to provide a remote multi-flash flash photographing system if they have a communication function described later. May be configured.

Each of the electronic flash device 20 and the remote electronic flash device 20A has a mounting leg that is detachably mounted to an accessory shoe (not shown) of a well-known structure provided in the camera 30. Note that these mounting legs can be attached to and detached from an accessory shoe (not shown) of the remote wireless adapter 10A. In the example of FIG. 1, the mounting leg of the electronic flash device 20 is mounted on the accessory shoe of the camera 30, and the mounting leg of the remote electronic flash device 20A is mounted on the accessory shoe of the remote wireless adapter 10A.

In the present embodiment, the remote wireless adapter 10A is described as a device that can be attached to and detached from the remote electronic flash device 20A, but the remote wireless adapter 10A may have a structure incorporated in the remote electronic flash device 20A. Further, in the present embodiment, the master wireless adapter 10 is described as a device that can be attached to and detached from the camera 30, but the master wireless adapter 10 may be built in the camera 30.

The master wireless adapter 10 includes an electrical connection terminal (electrical contact). The camera 30 includes, for example, on its side surface, a connection terminal (an electrical contact (not shown)) that can be electrically connected to an electrical contact of the master wireless adapter 10. When the master wireless adapter 10 is attached to the camera 30, the electrical contacts of both are electrically connected.

The accessory shoe of the remote wireless adapter 10A also includes electrical contacts (not shown). An electrical contact is also provided on the mounting leg of the remote electronic flash device 20A, and when the remote electronic flash device 20A is attached to the remote wireless adapter 10A, the electrical contacts between the two are electrically connected.

The electronic flash device 20 mounted on the accessory shoe of the camera 30 is connected to the camera 30 via an electric contact (not shown) provided on the accessory shoe and an electric contact provided on a mounting leg of the electronic flash device 20. Wired communication is performed. The master wireless adapter 10 mounted on the side surface of the camera 30 performs wired communication with the camera 30 via the above-mentioned electrical contacts. Note that the camera 30 and the master wireless adapter 10 may not be physically connected. The camera 30 and the master wireless adapter 10 may perform wireless communication.

The master wireless adapter 10 performs wireless communication with the remote wireless adapter 10A. The remote wireless adapter 10A and the remote electronic flash device 20A perform wired communication via the accessory shoes of the remote wireless adapter 10A and the above-described electrical contacts provided on the mounting legs of the remote electronic flash device 20A.

The configuration of FIG. 1 is a remote multi-flash flash photographing system including one camera 30 and two electronic flash devices (electronic flash device 20, remote electronic flash device 20A). The total number of electronic flash devices need not be two, and may be any number as long as it is one or more. In addition, without using the electronic flash device 20 on the accessory shoe of the camera 30 (or, even if the electronic flash device 20 is mounted on the camera 30, setting is made such that the flash does not emit light), only the remote electronic flash device 20A is used for remote control. A flash photography system may be configured. Further, the remote multi-flash flash photographing system may be configured by using a plurality of remote electronic flash devices including the remote electronic flash device 20A.

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 remote electronic flash device 20A. In the present embodiment, since the master wireless adapter 10 and the remote wireless adapter 10A have the same circuit configuration, the same reference numerals are given to the blocks common to both wireless adapters in the description. Further, since the electronic flash device 20 and the remote electronic flash device 20A also have a common configuration (including the internal configuration) themselves, the same reference numerals are given to the internal blocks for description.

<Electronic flash device>
In FIG. 2, the electronic flash device 20 and the remote electronic flash device 20A each include an arc tube 201 such as a xenon tube, a light emission control circuit 202, and a CPU 203. The CPU 203 controls light emission of the light emitting tube 201 while performing wired communication with the CPU of the connected external device (the CPU 105 of the remote wireless adapter 10A or the CPU 306 of the camera 30). The multi-flash imaging system in the embodiment may be a steady light emitting device having an LED light instead of the electronic light emitting device 20 and the remote electronic light emitting device 20A.

The light emission control circuit 202 includes a main capacitor that stores electric charges (energy) necessary for discharge light emission, and a high-voltage charging circuit that performs a charging process on the main capacitor. The light emission control circuit 202 controls the discharge time of the stored energy based on an instruction from the CPU 203, thereby causing the arc tube 201 to perform discharge light emission with a desired light emission amount (target light emission amount). The target light emission amount is obtained from an external device provided separately from the electronic flash device 20 or the remote electronic flash device 20A (the camera 30 for the electronic flash device 20 and the camera 30 for the remote electronic flash device 20A). (From the mounted master wireless adapter 10) to the CPU 203 in the electronic flash device.

Specifically, in the case of the remote electronic flash device 20A, the information of the target light emission amount is generated by the camera 30 arranged apart from the remote electronic flash device 20A, and the generated information of the target light emission amount is It is transmitted from the master wireless adapter 10 to the CPU 203 in the remote electronic flash device 20A via the remote wireless adapter 10A. Further, in the case of the electronic flash device 20 physically connected to the camera 30 via the accessory shoe of the camera 30, the information on the target light emission amount generated by the camera 30 is the electric power of the mounting leg of the electronic flash device 20. It is transmitted from the camera 30 to the CPU 203 in the electronic flash device 20 through the contacts and the electrical contacts of the accessory shoe of the camera 30.

The light emission control circuit 202 sends ready information to the CPU 203 when the stored energy in the main capacitor has reached a predetermined value (a state in which the stored energy in the main capacitor has reached the capacity necessary for the light emitting operation and is ready to emit light). Is sent). The light emission control circuit 202 does not send ready information when the stored energy is less than a predetermined value.

<Wireless adapter>
The master wireless adapter 10 and the remote wireless adapter 10A each include an antenna 101, a communication circuit 102, and a CPU 105. The CPU 105 performs wired communication with the CPU of the external device (the CPU 203 of the electronic flash device 20A or the CPU 306 of the camera 30) that is physically connected to each of the wireless adapters 10 and 10A through electrical contacts. In addition to the above, it controls wireless communication with other wireless adapters.

The CPU 105 has a built-in timer circuit 105t, and is capable of measuring time based on its own clock signal. The CPU 105 of the master wireless adapter 10 and the CPU 105 of the remote wireless adapter 10A are composed of equivalent devices, and have the same time measurement accuracy. The communication circuit 102 performs wireless communication with another wireless adapter via the antenna 101 according to an instruction from the CPU 105.

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

The taking lens 301 forms a subject image on the imaging surface of the image sensor 303. The shutter 302 has a front curtain and a rear curtain (not shown), and the shutter drive device 305 controls the opening/closing of the shutter 302. The photometric sensor 304 outputs a photometric signal according to the intensity of 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 a diaphragm (not shown) by performing a predetermined exposure calculation based on the photometric signal.

Further, the CPU 306 also performs dimming control for the electronic flash device 20 and the remote electronic flash device 20A based on the output signal from the photometric sensor 304. The CPU 306 has a built-in timer circuit 306t and is capable of measuring time based on its own clock signal. Since the CPU 105, the CPU 203, and the CPU 306 are different CPUs, the timing accuracy of the CPU 306 is not necessarily the same as the timing accuracy of the CPU 105 of the master wireless adapter 10 and the remote wireless adapter 10A described above.

The operation member 307 includes a release switch, a menu switch, an operation dial, and the like, and sends operation signals 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 edge enhancement processing, interpolation processing, white balance adjustment processing, and the like. The image signal after the image processing is recorded in the recording medium 350 such as a memory card.

The memory 308 stores the information transmitted from the electronic flash device 20 and the remote electronic flash device 20A. 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.

The camera 30 may be a single-lens reflex type camera or a non-single-lens reflex type camera. In the case of a single-lens reflex type camera, a quick return mirror (not shown) (hereinafter simply referred to as a mirror) is provided between the taking lens 301 and the shutter 302. The light flux from the subject is guided to the image pickup element 303 by mirroring up the mirror during shooting. The light flux from the subject is guided to the finder optical system (not shown) by mirroring down the mirror after shooting.

<Multi-flash shooting>
When performing multi-flash flash photography, the CPU 306 of the camera 30 detects the pressing operation (shooting instruction) of the release switch 307 by the operator 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 by wired communication.

Note that it is assumed that wireless communication is established between the master wireless adapter 10 and the remote wireless adapter 10A (that is, the camera 30 and the remote electronic flash device 20A) prior to the shooting instruction. For example, the master wireless adapter 10 detects the remote wireless adapter 10A requesting wireless connection, performs wireless connection, and assigns an ID for recognizing the remote wireless adapter to the remote wireless adapter 10A. Wireless communication is established with the remote wireless adapter 10A.

Further, among the electronic flash device 20 and the remote electronic flash device 20A corresponding to the remote wireless adapter 10A that has established wireless communication, the electronic flash device that should emit light at the time of the next shooting can be operated by the operator before the shooting. It shall be specified in advance.

-Wired communication between camera and master wireless adapter-
Communication between the camera 30 (CPU 306) and the master wireless adapter 10 (CPU 105) is wired communication via the above-mentioned electrical contacts. This wired communication is led by the camera 30 and appropriately performed as needed.

In communication between the camera 30 and the master wireless adapter 10, normally, the camera 30 transmits a command and data to the master wireless adapter 10, and the master wireless adapter 10 that receives the command returns data (ack) to the camera 30. The commands and data include those for the remote electronic flash device 20A.

-Wired communication between the camera and the electronic flash device connected to the camera accessory shoe-
Further, communication between the camera 30 (CPU 306) and the electronic flash device 20 (CPU 203) is also performed by a plurality of electrical contacts (not shown) provided on the accessory shoe of the camera 30 and a mounting leg of the electronic flash device 20. Wired communication is performed through electrical contact between a plurality of electrical contacts (not shown) provided. Information communication is performed between the CPU 306 of the camera 30 and the CPU 203 of the electronic flash device 20, via the plurality of electrical contacts, for transmitting and receiving data such as the above-described target light emission amount and commands to be described later. The wired communication is also led by the camera 30 and appropriately performed as necessary.

In communication (wired communication) between the camera 30 and the electronic flash device 20, normally, the camera 30 transmits a command and data to the electronic flash device 20, and the electronic flash device 20 which receives the command and data returns to the camera 30 (ack). ) Do. The commands and data include information on the electronic flash device 20 (commands indicating monitor light emission or main light emission for the electronic flash device 20, data such as light emission amount during monitor light emission, target light emission amount during main light emission, etc.). However, it does not include commands or data for the remote electronic flash device 20A.

In the present embodiment, the monitor light emission operation (hereinafter, simply referred to as “monitor light emission”) is to measure the reflectance of a subject existing in the field (the shooting scene) that is about to be captured. In addition, it refers to a flash light emitting operation of emitting a small amount of light from the electronic flash device 20 or the remote electronic flash device 20A.

In the present embodiment, the main light emission operation (hereinafter, simply referred to as “main light emission”) means the electronic flash device 20 or the remote electronic flash device 20A in order to obtain a desired exposure (for example, proper exposure) of a subject. Is a flash light emitting operation of emitting a predetermined amount of light.

When the release operation is performed on the camera 30, the electronic flash device 20 and the remote electronic flash device 20A actually shoot the monitor light emission (actual shooting for recording the shot image on a recording medium such as a memory card). ) The control is performed so as to be performed prior to the above main light emission performed at the time of).

− Communication between master wireless adapter and remote wireless adapter −
Communication between the master wireless adapter 10 and the remote wireless adapter 10A is performed by wireless communication. FIG. 3 is a diagram illustrating wireless communication performed by the master wireless adapter 10 with the remote wireless adapter 10A. The frequency of wireless communication with the remote wireless adapter 10A is the same as the frequency of communication between the camera 30 and the master wireless adapter 10. That is, after wired communication between the camera 30 and the master wireless adapter 10, wireless communication is performed between the master wireless adapter 10 and the remote wireless adapter 10A without delay.

Normally, for communication of information between the master wireless adapter 10 and the remote wireless adapter 10A, the master wireless adapter 10 transmits the above command and data to the remote wireless adapter 10A, and the remote wireless adapter 10A which receives the command and data receives the master wireless adapter 10A. Reply to the adapter 10. The commands and data include those for the remote electronic flash device 20A attached to the remote wireless adapter 10A of the communication partner. However, in the wireless communication between the master wireless adapter 10 and the remote wireless adapter 10A during the release sequence described later, the remote wireless adapter 10A does not reply (ack) to the master wireless adapter 10 (the master wireless adapter 10 and the camera 30). Don't even ask for a reply). The communication operation during the release sequence will be described later.

− Communication between remote wireless adapter and remote electronic flash device −
The communication between the remote wireless adapter 10A and the remote electronic flash device 20A is wired communication via the electrical contacts provided to each other as described above. This wired communication is performed immediately after the remote wireless adapter 10A performs wireless communication with the master wireless adapter 10 and then with the corresponding remote electronic flash device 20A.

In wired communication between the remote wireless adapter 10A and the remote electronic flash device 20A, normally, the remote wireless adapter 10A transmits the above command and data to the corresponding electronic flash device 20A, and the remote electronic flash device 20A that receives the command and data receives the command and data. Reply to the remote wireless adapter 10A. The commands and data include those for the remote electronic flash device 20A attached to the remote wireless adapter 10A.

<Light emission timing during multi-flash shooting>
A schematic time schedule of light emission by the electronic flash device 20 and the remote electronic flash device 20A in the release sequence will be described. FIG. 4 is a diagram exemplifying the timing when performing TTL (through the lens) dimming control in remote multi-flash flash photography in which shooting auxiliary light is emitted from the electronic flash device 20 and the remote electronic flash device 20A.

When the operator (photographer) of the camera 30 performs a pressing operation (photographing instruction) of the release switch 307 of the camera 30, the CPU 306 of the camera 30 starts the release sequence process at time t0.

In the release sequence process at the time of TTL dimming control in the present embodiment, each electronic flash device (electronics) is operated before the shutter drive device 305 instructed by the CPU 306 drives the shutter 302 to open (that is, before the exposure of the main photographing). The flash device 20 and the remote electronic flash device 20A) are caused to perform a monitor light emission operation, and the camera 30 side performs a photometric operation so as to be linked to the monitor light emission operation.

First, at time t0, the camera 30 (CPU 306) issues a monitor light emission instruction (command A described later) to the electronic flash device 20. Based on this instruction (command A), the electronic flash device 20 emits monitor light at time t1.

Next, at time t2, the camera 30 (CPU 306) issues a monitor light emission instruction (command B described later) to the remote electronic flash device 20A. Based on this instruction (command B), the remote electronic flash device 20A emits monitor light at time t3. As described above, in the case of the present embodiment (when performing remote multi-flash flash photography using the electronic flash device 20 and the remote electronic flash device 20A), the monitor is executed twice in total during one release sequence process. The light is emitted. Note that the electronic flash device 20 and the remote electronic flash device 20A each emit the monitor light emission twice with the target light emission amount (target monitor light emission amount) at the time of monitor light emission.

The photometric sensor 304 of the camera 30 is controlled so as to receive the reflected light from each subject in synchronization with the above-described two monitor light emission timings (photometry). The CPU 306 performs known arithmetic processing (“arithmetic processing” subsequent to “photometry” in “camera processing” illustrated in FIG. 4) on the basis of the photometric signal output from the photometric sensor 304, whereby the electronic flash device 20 and The target amount of light emission at each main light emission of the remote electronic flash device 20A is calculated.

A calculation example of the target light emission amount (hereinafter, referred to as target main light emission amount) at the time of main light emission in the electronic flash device 20 is as follows. That is, the photometric signal output from the photometric sensor 304 in a state where neither the electronic flash device 20 and the remote electronic flash device 20A emit light, and the photometric signal output from the photometric sensor 304 in a state where the electronic flash device 20 emits monitor light. The target main light emission amount of the electronic flash device 20 is calculated on the basis of the difference between and.

Similarly, for the remote electronic flash device 20A, the photometric signal output from the photometric sensor 304 in a state where the electronic flash device 20 and the remote electronic flash device 20A are not emitted, and the photometric signal in a state where the remote electronic flash device 20A is emitting monitor light. Based on the difference from the photometric signal output from the sensor 304, the target main light emission amount of the remote electronic flash device 20A is calculated.

At time t8 when the shutter 302 is fully open, the CPU 306 causes the electronic flash device 20 and the remote electronic flash device 20A to perform main light emission at substantially the same time (exposure for main shooting). In the main light emission, the electronic flash device 20 and the remote electronic flash device 20A emit light with respective target main light emission amounts.

Hereinafter, the light emission timings of the electronic flash device 20 and the remote electronic flash device 20A in the remote multi-flash flash photographing operation will be described in detail with reference to FIG. FIG. 4 is an example of so-called front curtain synchronized photography in which main light emission is performed when the front curtain of the shutter 302 has finished traveling and the shutter 302 has been fully opened.

<Monitor emission instruction for all electronic flash devices>
At time t0, the camera 30 (CPU 306) that starts the release sequence process based on the release operation of the operator electronically outputs the command A (monitor light emission command A) generated by the CPU 306 at substantially the same timing (time t0). Transmit to flash device 20 via electrical contacts on the accessory shoe. This monitor light emission command A includes information indicating the target monitor light emission amount during the monitor light emission of the electronic flash device 20 and information indicating the monitor light emission timing (light emission start time td0 in FIG. 4). The target monitor light emission amount is a predetermined value that is determined in advance, and is a value that is about several hundredth of the main light emission amount.

At time t2, the camera 30 (CPU 306) transmits the command B (monitor light emission command B) generated by the CPU 306 to the master wireless adapter 10 via the electrical contact described above. The master wireless adapter 10 broadcasts the monitor light emission command B to the remote wireless adapter 10A by wireless communication. The master wireless adapter 10 does not request a reply (ack) from the remote wireless adapter 10A, as described above, because it is wireless communication during the release sequence process (the process shown in FIG. 4). That is, the communication in this case is one-way transmission (one-way communication). The master wireless adapter 10 repeats this broadcast transmission a plurality of times (for example, four times).
It should be noted that the number of repeated transmissions of the broadcast transmission is not limited to four, and may be set to any number of times.

Here, the reason why the above-described broadcast transmission is repeated a plurality of times is assumed to be an environment where the communication state is poor (for example, an environment where there is a lot of electromagnetic noise or an environment where interference with radio waves transmitted from other communication devices is large). In the case of communication, it is preferable to increase the probability of being received by the receiving side by repeating the transmission a plurality of times, rather than waiting for a reply (ack) after each transmission and checking whether or not the receiving side has received it. Based on the idea.

The contents contained in the monitor light emission command B transmitted to the remote wireless adapter 10A (remote electronic flash device 20A connected thereto) will be described. The monitor light emission command B includes information indicating the timing at which the remote electronic flash device 20A emits monitor light (light emission start time td1 in FIG. 4) and information indicating the target monitor light emission amount during monitor light emission of the remote electronic flash device 20A. include. The target monitor light emission amount is a predetermined value that is determined in advance, and is a value that is about several hundredth of the main light emission amount.

In the present embodiment, when the electronic flash device 20 emits monitor light, monitor light emission is prioritized prior to the remote electronic flash device 20A (see FIG. 4).

<Monitor light emission of the electronic flash device 20>
The electronic flash device 20 performs monitor light emission with the target monitor light emission amount at time t1 when the light emission start time td0 has elapsed from the reception of the monitor light emission command A (time t0). The camera 30 (CPU 306) performs photometric processing while monitor flash is being performed by the electronic flash device 20 from time t1, and causes the electronic flash device 20 to perform the above-described arithmetic processing after monitor flash (see FIG. 4). "Calculation" described). Through this calculation process, the target main light emission amount of the electronic flash device 20 is calculated.
The light emission start time td0 corresponds to the time from when the monitor light emission command A is sent from the camera 30 (CPU 306) to when the electronic flash device 20 starts monitor light emission.

<Monitor emission of remote electronic flash device 20A>
The remote wireless adapter 10A that receives the monitor light emission command B from the master wireless adapter 10 transmits the monitor light emission command B to the connected remote electronic flash device 20A by wire communication. The remote electronic flash device 20A performs monitor light emission at the target monitor light emission amount at time t3 when the light emission start time td1 has elapsed from the reception of the monitor light emission command B (time t2).

The camera 30 (CPU 306) performs photometric processing while the remote electronic flash device 20A is emitting monitor light from time t3, and then performs the above-described arithmetic processing for the remote electronic flash device 20A after monitor emission (FIG. "Arithmetic processing" described in 4). By this arithmetic processing, the target main light emission amount of the remote electronic flash device 20A is calculated.
The light emission start time (td1) corresponds to the time from when the monitor light emission command B is sent from the camera 30 (CPU 306) to when the remote electronic flash device 20A starts monitor light emission.

After the arithmetic processing, the camera 30 (CPU 306) performs a predetermined total arithmetic processing in preparation for the actual photographing exposure from time t4 (“total arithmetic processing” shown in FIG. 4).

<Instruction of main flash for electronic flash device 20 and remote electronic flash device 20A>
At time t5 after the comprehensive calculation process, the camera 30 (CPU 306) transmits the command C (main light emission command C) generated by the CPU 306 to the master wireless adapter 10 via the electrical contact described above. The master wireless adapter 10 broadcasts the main light emission command C to the remote wireless adapter 10A by wireless communication. Since the master wireless adapter 10 is wireless communication during the release sequence process, as described above, the one-way transmission that does not request a reply (ack) from the remote wireless adapter 10A is repeated a plurality of times (for example, four times).

At time t7, the camera 30 (CPU 306) transmits the main light emission command D to the electronic flash device 20 connected to the accessory shoe of the camera 30 by wire communication (via the electrical contact of the accessory shoe).

The contents included in the main light emission command C transmitted to the remote wireless adapter 10A (remote electronic flash device 20A connected thereto) will be described. The main light emission command C includes information indicating the timing at which the remote electronic flash device 20A performs main light emission (light emission start time td2 in FIG. 4) and information indicating the target main light emission amount during the main light emission of the remote electronic flash device 20A. include.

On the other hand, the main light emission command D transmitted to the electronic flash device 20 includes the target main light emission amount of the electronic flash device 20, but does not include information indicating the timing of main light emission. This is because the instruction of the main light emission timing to the electronic flash device 20 is given by the ON signal (also referred to as an X signal) of the synchro contact transmitted through the accessory shoe of the camera 30.

This ON signal of the synchro contact is a trigger transmitted from the master wireless adapter 10 by the CPU 306 of the camera 30 so that the main flash emission by the remote electronic flash device 20A and the main flash light by the electronic flash device 20 are performed at the same time. Generate based on signal. The trigger signal transmitted from the master wireless adapter 10 will be described later.

<Main Emission of Remote Electronic Flash Device 20A and Electronic Flash Device 20>
The remote wireless adapter 10A that has received the main light emission command C from the master wireless adapter 10 transmits the main light emission command C to the connected remote electronic flash device 20A by wire communication. The remote electronic flash device 20A performs main light emission at the target main light emission amount at time t8 when the light emission start time td2 has elapsed from the reception of the main light emission command C (time t5).

On the other hand, the electronic flash device 20 that has received the main flash command D at the time t7, as described above, performs the main flash based on the ON signal (X signal) of the synchro contact output from the camera 30 at the subsequent time t8.

In the present embodiment, the remote electronic flash device 20A and the electronic flash device 20 each perform main light emission after time t8 when the shutter 302 is fully opened and the charge accumulation for main shooting is started by the image sensor 303. The light emission start time td2 included in the main light emission command C by the camera 30 (CPU 306) and the timing of the ON signal (X signal) of the synchro contact output via the accessory shoe of the camera 30 are controlled as follows.

FIG. 5 is a diagram illustrating operations performed by the camera 30, the master wireless adapter 10, and the remote electronic flash device 20A from time t5 to time t9 in FIG. As described above, at time t5, the main light emission command C is transmitted from the camera 30 to the remote electronic flash device 20A via the master wireless adapter 10 and the remote wireless adapter 10A. The time information included in the main light emission command C is composed of time X (=light emission start time td2) and time Y.

The time Y takes into consideration, for example, the time required for the reset processing (processing for discharging unnecessary accumulated charges) for the image sensor 303, the time required for the opening drive of the shutter 302 (that is, the front curtain traveling time), and the margin time. It is the time peculiar to the camera 30, which is determined by. The first-curtain running time also takes into consideration the variation due to aging. The margin time also takes into consideration the difference in the timing accuracy between the timer circuit 306t of the CPU 306 and the timer circuit 105t of the CPU 105.

When the CPU 105 of the master wireless adapter 10 and the CPU 105 of the remote wireless adapter 10A each receive the main light emission command C from the camera 30 (CPU 306), the timer circuit 105t starts timing. The CPU 105 of the master wireless adapter 10 transmits a trigger signal to the camera 30 (CPU 306) at the time when the time (X-Y) is measured from the reception of the main light emission command C (time t5) (time t6B). For example, the time X and the time Y are 100 msec (time X) and 10 msec (time Y).

When the CPU 105 of the remote wireless adapter 10A measures the time X from the reception of the main light emission command C (time t5), the remote electronic flash device 20A starts the main light emission (time t8).
The time t8 when the remote electronic flash device 20A starts the main light emission is the time obtained by the time measurement by the timer circuit 105t of the remote wireless adapter 10A, and the time obtained by the time measurement by the CPU 105t of the master wireless adapter 10 having the same type of circuit. It matches t8.

On the other hand, when the CPU 306 of the camera 30 transmits the main light emission command C to the master wireless adapter 10 (time t5), at time t6, the energization (power supply) to the image sensor 303 is turned on, and the image sensor 303 is imaged. Make various settings. Further, when the camera 30 is a single-lens reflex type camera, the mirror-up drive for the mirror (not shown) is started, and the trigger signal transmitted from the master wireless adapter 10 is waited for.

At time t6B when the trigger signal is received from the master wireless adapter 10, the CPU 306 of the camera 30 starts the reset process for the image sensor 303, starts the accumulation process (exposure) after the reset process, and causes the shutter drive device 305 to release the shutter. The opening drive of 302 (that is, the leading curtain travel) is started. The reset process and the accumulation process are performed based on the timing signal generated by the timer circuit 306t. The CPU 306 of the camera 30 performs the reset process and the accumulation process of the image sensor 303 and the opening drive of the shutter 302 by the shutter drive device 305 during the time Y.

The CPU 306 of the camera 30 further causes the timer circuit 306t to start timing at time t6B when the trigger signal is received from the master wireless adapter 10. When the time Y is counted from the reception of the trigger signal (time t6B), the CPU 306 sends an ON signal (X signal) of the synchro contact to the electronic flash device 20 via the accessory shoe of the camera 30 (time t8). As a result, the electronic flash device 20 that has received the main light emission command D at time t7 starts main light emission. The CPU 306 of the camera 30 may send an ON signal (X signal) of the synchro contact to the electronic flash unit 20 via the accessory shoe of the camera 30 when the timer circuit 306t measures the time X.

The time t8 when the electronic flash device 20 starts the main light emission is the time obtained based on the time measurement by the timer circuit 306t of the CPU 306 of the camera 30. As described above, the timing accuracy of the timer circuit 306t of the CPU 306 and the timing accuracy of the timer circuit 105t of the CPU 105 of the master wireless adapter 10 and the remote wireless adapter 10A are not necessarily equal, but both timer circuits 306t and 105t are parallel. Only the time Y (for example, 10 msec) from time t6B to time t8 is measured.

That is, if both timer circuits 306t and 105t measure time X longer than time Y (for example, 100 msec) in parallel, start of main light emission by the electronic flash device 20 and remote electronic flash based on the respective time measurement results. Compared with the case where the main light emission by the device 20A is started, it is possible to suppress the time lag between the main light emission timings by the two electronic flash devices (20, 20A). When a concrete example is calculated with the timing accuracy of 15 ppm, a deviation of 150 μsec is expected when the time is 100 msec, but the deviation is 15 μsec when the time is 10 msec.

The above-described time Y is determined such that at least the reset process for the image sensor 303 and the opening drive of the shutter 302 (that is, the front curtain travel) are completed at time t8.

As described above, the main light emission by the electronic flash device 20 and the main light emission by the remote electronic flash device 20A are performed at time t8 after the shutter 302 is fully opened (that is, after the front curtain travels), and the shutter 302 is opened. In a time period (from the start of the front curtain running to the end of the rear curtain running), the accumulation process for the image sensor 303 is performed. Furthermore, the reset process for the image sensor 303 is performed immediately before the accumulation process. If the reset process is performed immediately before the accumulation process, a captured image in which the influence of noise is suppressed can be obtained.

In the present embodiment, if the CPU 306 of the camera 30 starts the reset process for the image sensor 303 or starts the opening drive of the shutter 302 with respect to the time (t8) when the main light emission is scheduled, Information on the time Y indicating whether the main light emission and the accumulation operation or the main light emission and the shutter fully open can be synchronized is determined in advance.

Based on this time Y, the CPU 306 performs the operation (main light emission by the remote electronic flash device 20A) performed at the timing measured by the timer circuit 105t of the master wireless adapter 10 and the timing measured by the timer circuit 306t of the camera 30. The timing of the operations (reset processing for the image pickup element 303, opening drive of the shutter 302, transmission of an ON signal of the synchro contact) performed in step 3 is controlled. The information of the time Y can be sent from the camera CPU 306 to the master wireless adapter 10 at the time of regular communication between the master wireless adapter 10 (CPU 105) and the camera 30 (CPU 306) or when the main light emission command C is transmitted. Information regarding the time X from the time when the main light emission command C is received to the time (t8) when the main light emission is scheduled is sent from the camera CPU 306 to the master wireless adapter 10 when the main light emission command C is transmitted.

<Explanation of flow chart>
FIG. 6 is a flowchart exemplifying the flow of a photographing process in which the CPU 306 of the camera 30 detects and starts the pressing operation (shooting instruction) of the release switch 307 by the operator. In step S10 of FIG. 6, the CPU 306 transmits the monitor light emission command A to the electronic flash device 20 (time t0 in FIG. 4), and proceeds to step S20. In step S20, the CPU 306 starts photometry processing while the electronic flash device 20 performs monitor light emission based on the command A (time t1 in FIG. 4) and proceeds to step S30.

In step S30, the CPU 306 starts arithmetic processing and proceeds to step S40. In step S40, the CPU 306 determines whether the monitor light emission operation has ended. When the communication with the CPU 306 is established and the monitor light emission command is transmitted to all the electronic flash devices designated in advance, the CPU 306 makes an affirmative decision in step S40 and the operation proceeds to step S50. If there is an electronic flash device that has not transmitted the monitor light emission command, the CPU 306 makes a negative determination in step S40 and returns to step S10.

After returning to step S10, the CPU 306 transmits the monitor light emission command B to the master wireless adapter 10 (time t2 in FIG. 4) and proceeds to step S20. The monitor light emission command B transmitted to the master wireless adapter 10 is immediately transmitted from the master wireless adapter 10 to the remote electronic flash device 20A via the remote wireless adapter 10A. In step S20, the CPU 306 starts photometry processing while the remote electronic flash device 20A performs monitor light emission based on the command B (time t3 in FIG. 4) and proceeds to step S30. Subsequent processing of steps S30 and S40 is similar to that described above.

In step S50, the CPU 306 starts the total calculation process and proceeds to step S60 (time t4 in FIG. 4). In step S60, the CPU 306 starts the exposure sequence. Specifically, the mirror-up drive is started, and further, 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 causes the master wireless adapter 10 to transmit the main light emission command C (time t5 in FIG. 4) and also transmits the main light emission command D to the electronic flash device 20 and proceeds to step S80 (time in FIG. 4). t7). Further, the CPU 306 transmits an X signal for turning on the synchro contact to the electronic flash device 20 at time t8 in FIG.

The remote electronic flash device 20A starts main light emission at time t8 based on the light emission start time td2 (=time X) included in the main light emission command C. Further, the electronic flash device 20 starts main light emission at time t8 based on turning on of the synchro contact. As a result, main light emission is performed at time t8 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 and performs a predetermined image process at the timing (time t9 in FIG. 4) when the trailing curtain traveling of the shutter 302 by the shutter drive device 305 ends (step S90). move on.

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

According to the above-mentioned embodiment, the following effects can be obtained.
(1) The control device mounted on the camera 30 includes a CPU 306 that communicates with the master wireless adapter 10, a timer circuit 306t that counts time, a CPU 306 that executes reset processing for the image sensor 303, and a timer circuit 306t. And a CPU 306 for controlling communication. Then, the CPU 306 causes the master wireless adapter 10 to transmit at least the time X (=light emission start time td2) indicating the time t8, and indicates that the master wireless adapter 10 has measured the time t6B before the time t8. When the trigger signal is received by the CPU 306, the CPU 306 is caused to start, for example, reset processing for the image sensor 303.
Since the camera 30 starts reset processing for the image sensor 303, for example, starting from the trigger signal at time t6B timed on the master wireless adapter 10 side, the reset processing on the camera 30 side is timed on the master wireless adapter 10 side. The operation performed based on the performed time (for example, main light emission by the remote electronic flash device 20A) is not too early or too late, and can be performed at an appropriate synchronized timing.

(2) The CPU 306 mounted on the camera 30 causes the CPU 306 to transmit time information indicating the time difference between the time t8 and the time t6B (that is, the time Y) from the CPU 306 to the master wireless adapter 10. Thereby, in consideration of the time Y peculiar to the camera 30, for example, the reset process on the camera 30 side is performed based on the time measured on the master wireless adapter 10 side (for example, main light emission by the remote electronic flash device 20A). ) Can be performed at an appropriate timing.

(3) When the CPU 306 installed in the camera 30 receives a trigger signal indicating that the master wireless adapter 10 has clocked the time (XY), the CPU 306 performs processing of the camera 306 as camera 30 side processing. Since the reset process of the image sensor 303 of the camera 30 and the opening drive of the shutter 303 are performed, the reset process and the open drive of the camera 30 are performed based on the time measured by the master wireless adapter 10 side (for example, a remote electronic device). This can be performed at an appropriate timing in synchronization with the main light emission by the flash device 20A.

(4) When the CPU 306 mounted on the camera 30 receives the trigger signal indicating that the time t6B is timed by the master wireless adapter 10, the CPU 306 tells the CPU 306 the time difference between the time t8 and the time t6B (that is, The time Y) is timed, and when the time Y is timed by the CPU 306, the ON signal of the synchro contact for the electronic flash device 20 that emits the auxiliary light for photographing is generated. As a result, the electronic flash device 20 is caused to perform main light emission at an appropriate timing in synchronization with an operation (for example, main light emission by the remote electronic flash device 20A) performed based on the time measured on the master wireless adapter 10 side. be able to.

(5) The CPU 306 mounted on the camera 30 calculates the time difference between the time t8 and the time t6B (that is, the time Y), the time required to drive the shutter 302 open, the time required to reset the image sensor 303, and Since it is determined based on the open drive and the margin time for the reset process, it is appropriate to synchronize with the operation (for example, the main light emission by the remote electronic flash device 20A) performed based on the time measured on the master wireless adapter 10 side. At a timing, the electronic flash device 20 can be caused to emit main light.

(6) When the CPU 306 mounted on the camera 30 causes the CPU 306 to transmit the time information to the master wireless adapter 10, the CPU 306 causes the CPU 306 to up-drive the mirror of the camera 30 as a pre-process. It is possible to appropriately perform an operation that should be performed before an operation (for example, main light emission by the remote electronic flash device 20A) performed based on the time measured by the adapter 10 side.

(7) Since the CPU 306 mounted on the camera 30 determines the time t8 based on the time required to drive the mirror of the camera 30 up and the time required to set the image sensor 303, on the master wireless adapter 10 side. It is possible to appropriately perform the operation that should be performed before the operation performed based on the time measured (for example, main light emission by the remote electronic flash device 20A).

(8) The master wireless adapter 10 includes a CPU 105 that communicates with the camera 30, a timer circuit 105t that counts time, a timer circuit 105t, and a CPU 105 that controls communication. When the CPU 105 receives the time information indicating the time difference between the time t8 and the time t8 and the time t6B (that is, the time Y) transmitted from the camera 30, the CPU 105 causes the timer circuit 105t to detect the time difference from the time t8. The time t6B immediately before is timed, and the trigger signal is transmitted from the CPU 105 to the camera 30 when the time t6B is timed by the timer circuit 105t.
As a result, the camera 30 can start a reset process or the like for the image sensor 303, for example, starting from the time (trigger signal) measured on the master wireless adapter 10 side. That is, the reset process on the camera 30 side is not too early or too late for the operation (for example, main light emission by the remote electronic flash device 20A) performed based on the time measured by the master wireless adapter 10 side, and is synchronized. It becomes possible to perform it at an appropriate timing.

(9) The time difference between the time t8 and the time t6B transmitted from the camera 30 (that is, the time Y) is the time required to drive the shutter 302 of the camera 30 and the time required to reset the image sensor 303 of the camera 30. And a margin time for the above-mentioned opening drive and reset processing. As a result, the reset process and the open drive on the camera 30 side are performed at appropriate timings synchronized with the operation (for example, main light emission by the remote electronic flash device 20A) performed based on the time measured on the master wireless adapter 10 side. It is possible to make it.

(10) The time t8 transmitted from the camera 30 is determined based on the time required to drive the mirror of the camera 30 up and the time required to set the image sensor 303. As a result, the camera 30 side can appropriately perform an operation that should be performed before an operation (for example, main light emission by the remote electronic flash device 20A) performed based on the time measured by the master wireless adapter 10 side. become.

(11) The CPU 105 of the master wireless adapter 10 further transmits information to the remote electronic flash device 20A that emits shooting auxiliary light, and the CPU 105 uses the timer circuit 105t after the time information transmitted from the camera 30 is received by the CPU 105. Information for causing the remote electronic flash device 20A to emit light when the time t8 is measured is transmitted from the CPU 105 to the remote electronic flash device 20A (remote wireless adapter 10A). Accordingly, when the time t8 is clocked by the timer circuit 105t after the CPU 105 receives the time information transmitted from the camera 30, that is, based on the time clocked by the master wireless adapter 10, the remote electronic flash device 20A operates. Main light emission is performed.

(12) In the control system in which the control information is transmitted and received between the camera 30 and the master wireless adapter 10 which have different timing accuracy, the camera 30 transmits time information indicating the time t8 to the master wireless adapter 10 to transmit the master wireless adapter 10. 10 transmits a trigger signal to the camera 30 when the master wireless adapter 10 measures the time t6B preceding the time t8 after receiving the time information, and the camera 30 receives the trigger signal and then measures the timing measured by the camera 30. The master wireless adapter 10 starts reset processing or the like for the image sensor 303 based on the timing measured by the master wireless adapter 10 after transmitting the trigger signal, for example, the remote electronic flash device 20A (remote wireless adapter). The main light emission is performed according to 10A).
As a result, the reset process and the like on the camera 30 side and the operation (for example, main light emission by the remote electronic flash device 20A) performed based on the time measured on the master wireless adapter 10 side are performed at appropriate timings synchronized with each other. be able to.

The following modifications are also within the scope of the present invention, and one or more modifications can be combined with the above-described embodiment.
(Modification 1)
The CPU 306 of the camera 30 may send the information of the time X and the time Y to the master wireless adapter 10, or the CPU 306 of the camera 30 may send the information of the time t6B in advance. The master wireless adapter 10 may receive the information at time t6B and transmit the trigger signal to the camera 30 (CPU 306) at time t6B.

(Modification 2)
In the present embodiment, when the electronic flash device 20 emits the monitor light, the monitor flash light is emitted prior to the other remote electronic flash device 20A (see FIG. 4). The timing of the monitor light emission operation of (1) and the monitor light emission operation of the remote electronic flash device 20A) may be reversed.

(Modification 3)
In the present embodiment, the monitor light emission command B and the main light emission command C transmitted to the remote electronic flash device 20A are generated by the CPU 306 of the camera 30, but these commands should be generated by a device other than the camera 30. May be. For example, the master wireless adapter 10 may have a function of generating these commands.

(Modification 4)
The present embodiment is particularly suitable when the light emission start time td2 (=time X) from the time t5 when the main light emission command is transmitted to the time t8 when the main light emission is scheduled is sufficiently longer than the time Y. .. Therefore, in the remote electronic flash device 20A, when it is necessary to lengthen the time from the time t2 when the monitor light emission command B is transmitted to the time t3 when the monitor light emission is scheduled (the light emission start time td1 is extended), the monitor The control at the time of light emission may be controlled similarly to the case of the main light emission.

For example, as the time information included in the monitor light emission command B, a time P (=light emission start time td1') indicating the time t3 and a time Q are included. The time Q is, for example, a time unique to the camera 30, which is determined in consideration of the time required for the reset processing (processing for discharging unnecessary accumulated charges) for the photometric sensor 304 and the margin time. The allowance time may also take into consideration the difference in the timing accuracy between the timer circuit 306t of the CPU 306 and the timer circuit 105t of the CPU 105.

When the CPU 105 of the master wireless adapter 10 and the CPU 105 of the remote wireless adapter 10A each receive the monitor light emission command B from the camera 30 (CPU 306) (time t2), the timer circuit 105t starts timing. The CPU 105 of the master wireless adapter 10 transmits a trigger signal to the camera 30 (CPU 306) at a time prior to time t3 (that is, when the time (P-Q) is measured from time t2). For example, the time P and the time Q are 40 msec (time P) and 10 msec (time Q).

The CPU 105 of the remote wireless adapter 10A causes the remote electronic flash device 20A to start the monitor light emission when the time P is counted from the reception of the monitor light emission command B (time t2). On the other hand, when the CPU 306 of the camera 30 receives the trigger signal from the master wireless adapter 10, the CPU 306 starts the reset process for the photometric sensor 304 and starts the accumulation process (photometry) after the reset process. The reset process is performed based on the timing signal generated by the timer circuit 306t.

According to the modified example 4, when the monitor electronic emission is performed by the remote electronic flash device 20A, the reset process for the photometric sensor 304 can be performed immediately before the photometric process, and the photometric process can be appropriately performed.

(Modification 5)
The present embodiment can be applied to the case where the exposure start timings of the plurality of cameras 30 are desired to be aligned. For example, the shooting command is transmitted from the master wireless adapter 10 (and the master camera 30) to the remote wireless adapter 10A (and the remote camera 30). The shooting command includes time X indicating the shooting time as time information. When there are a plurality of remote cameras 30, the longest time X is adopted.

The time Y is transmitted from the master camera 30 to the master wireless adapter 10 and from the remote camera 30 to the remote wireless adapter 10A. The time Y is required, for example, for the time required for the reset process (the process for discharging unnecessary accumulated charges) for the image sensor 303 of each camera 30 and for the opening drive of the shutter 302 of each camera 30 (that is, the front curtain travel time). It is a time unique to each camera 30, which is determined in consideration of the time and the margin time. The first-curtain running time also takes into consideration the variation due to aging. The allowance time also takes into consideration the difference in the timing accuracy between the timer circuit 306t of the CPU 306 of each camera 30 and the timer circuit 105t of the CPU 105 of the external device.

When the master wireless adapter 10 (and the master camera 30) that is the master transmits a shooting command to the remote wireless adapter 10A (and the remote camera 30) that is a remote, the timer circuit 105t starts timing. The CPU 105 of the master wireless adapter 10 transmits a trigger signal to the master camera 30 (CPU 306) at the time when the time (X-Y) is counted from the transmission of the shooting command. For example, the time X and the time Y are 100 msec (time X) and 8 msec (time Y).

When receiving the shooting command, the CPU 105 of the remote wireless adapter 10A that is remote causes the timer circuit 105t to start timing. The CPU 105 of the remote wireless adapter 10A transmits a trigger signal to the remote camera 30 (CPU 306) at the time when the time (X-Y) is counted from the reception of the shooting command. For example, the time X and the time Y are 100 msec (time X) and 12 msec (time Y).

After transmitting the shooting command, the CPU 306 of the master camera 30 turns on the power supply (power supply) to the image sensor 303, and makes various settings for the image sensor 303 for imaging. Further, when the camera 30 is a single-lens reflex type camera, the mirror-up drive for the mirror (not shown) is started, and the trigger signal transmitted from the master wireless adapter 10 is waited for.

When the CPU 306 of the master camera 30 receives the trigger signal from the master wireless adapter 10, the CPU 306 starts the reset process for the image sensor 303, starts the accumulation process (exposure) after the reset process, and causes the shutter drive device 305 to shutter the shutter. The opening drive of 302 (that is, the leading curtain travel) is started.

After receiving the shooting command, the CPU 306 of the remote camera 30 turns on the power supply (power supply) to the image sensor 303, and makes various settings for the image sensor 303 for imaging. Further, when the camera 30 is a single-lens reflex type camera, the mirror-up drive for the mirror (not shown) is started, and the trigger signal transmitted from the remote wireless adapter 10A is waited for.

When the CPU 306 of the remote camera 30 receives the trigger signal from the remote wireless adapter 10A, it starts the reset process for the image sensor 303, starts the accumulation process (exposure) after the reset process, and causes the shutter drive device 305 to release the shutter. The opening drive of 302 (that is, the leading curtain travel) is started.
According to the fifth modification described above, the exposure start timings of the plurality of cameras 30 can be aligned.

In the above description, the embodiment and the plurality of modified examples have been described, but an apparatus (camera or electronic flash device) may be configured by appropriately combining the configurations described in the embodiment and the modified examples.

10... Master wireless adapter 10A... Remote wireless adapter 20... Electronic flash device 20A... Remote electronic flash device 30... Camera 102... Communication circuits 105, 203, 306... CPU
105t, 306t... Timer circuit 302... Shutter 303... Imaging element

Claims (18)

A communication unit that communicates with an external device and transmits a first signal indicating a first time and a second signal indicating a second time shorter than the first time;
When the communication unit transmits the first signal to the external device and receives a signal indicating that the time difference between the first time and the second time has elapsed from the external device, the image pickup device of the camera And a processing unit that executes initialization processing and shutter opening drive processing. The control device according to claim 1,
Equipped with a timekeeping unit that keeps time
The control unit, wherein the processing unit executes a process during the second time period by the time counting unit after the communication unit receives a signal indicating that the time difference has elapsed. The control device according to claim 1,
Equipped with a timekeeping unit that keeps time
The said process part is a control apparatus which performs a process after the said 1st signal is transmitted by the said communication part, until the said 1st time is time-measured by the said time-measurement part. The control device according to claim 1,
The said control part is a control apparatus which emits the signal which lights the illumination device which emits imaging|photography auxiliary light, when the said 2nd time passes after the signal which shows that the said time difference has passed by the said communication part. The control device according to claim 1,
The said control part is a control apparatus which emits the signal which lights the illuminating device which emits imaging|photography auxiliary light, when the said 1st time passes after the said 1st signal is transmitted by the said communication part. The control device according to any one of claims 1 to 5,
A control device that determines the second time based on a time required to drive the shutter open, a time required to perform the initialization process, and a preparation time for the open drive and the initialization process. The control device according to any one of claims 1 to 6,
The said control part is a control apparatus which performs an up drive of the mirror of the said camera, when the said 1st signal is transmitted to the said external device by the said communication part. The control device according to claim 7,
A control device that determines the first time based on the time required to drive the mirror up and the time required to set the image sensor. A communication unit that communicates with an external device,
A timekeeping unit that keeps time,
When the first signal indicating the first time and the second signal indicating the time difference are received from the external device by the communication unit, the time measuring unit causes the time measuring unit to measure the second time shorter than the first time by the time difference, A control unit for transmitting a signal to the external device by the communication unit when the second time is measured by the time measuring unit,
The communication unit communicates with a camera, and the time difference is determined based on a time required for opening and driving a shutter of the camera and a time required for initialization processing of an image sensor of the camera. The electronic device according to claim 9,
The first time is an electronic device that is determined based on a time required to drive the mirror of the camera up and a time required to set the image sensor. The electronic device according to claim 9 or 10,
The communication unit communicates with a lighting device that emits shooting auxiliary light, and information for the lighting device to emit light after the first time elapses after receiving the first signal and the second signal. An electronic device for transmitting the light to the lighting device. An imaging device,
A communication unit that communicates with an electronic device mounted on the imaging device;
When the communication unit transmits a first signal indicating a first time to the electronic device and receives a second signal indicating that a second time shorter than the first time is timed from the electronic device, the processing is performed. An image pickup apparatus comprising: The image pickup apparatus according to claim 12 , wherein the processing section performs an image pickup element initialization process and a shutter open drive as the process. The imaging according to claim 12 or 13 , wherein the processing unit emits a signal to turn on a lighting device that emits shooting auxiliary light when the first time elapses after the first signal is transmitted by the communication unit. apparatus. An electronic device mounted on an imaging device,
A communication unit that communicates with the imaging device,
A timekeeping unit that keeps time,
When the communication unit receives the first signal indicating the first time and the signal indicating the time difference from the imaging device, the time measuring unit is caused to measure a second time shorter than the first time by the time difference, and the time measurement is performed. An electronic device comprising: a control unit that causes the communication unit to transmit a second signal to the imaging device when the second time is measured by a unit. The electronic device according to claim 15 , wherein the time difference is determined based on a time required to open and drive a shutter of the imaging device and a time required to initialize an imaging element of the imaging device. In a control system for transmitting and receiving control information between an image pickup apparatus having different timers and an electronic device mounted on the image pickup apparatus,
The imaging device transmits a first signal indicating a first time to the electronic device,
After receiving the first signal, the electronic device transmits a second signal indicating that the second time has been measured to the imaging device when the electronic device measures a second time shorter than the first time. ,
The control system, wherein the imaging device starts the process based on the timing measured by the imaging device after receiving the second signal. The control system according to claim 17 , wherein the image pickup apparatus performs an image pickup element initialization process and a shutter open drive as the process.

Images