JP6349650B2 - Camera and communication device - Google Patents

Description

The present invention relates to a camera and a communication device .

  A technique for controlling the light emission timing of an electronic flash device via wireless communication is known (see Patent Document 1). According to Patent Document 1, a master electronic flash device transmits a packet having a monitor light emission command to a remote electronic flash device, and the remote electronic flash device that receives the packet performs monitor light emission.

JP 2008-32909 A

  In the prior art, when the monitor light emission command wirelessly transmitted from the master side does not reach the remote side (it cannot be received by the remote electronic flash device side), the remote electronic flash device does not emit light.

A camera according to a first aspect of the invention includes a first light emitting device that emits light and a first light emitting device that includes a first light receiving unit that receives light, and a second light emitting device that includes a second light emitting unit that emits light. And a first signal for instructing to emit light from the first light-emitting unit, and the first signal from the first light-emitting unit. In the case where no light is emitted, light from the second light emitting unit is emitted from the first light receiving unit to emit light from the first light emitting unit by receiving light from the second light emitting unit at the first light receiving unit. And a control unit that outputs a second signal indicating a period of waiting for the communication device connected to the connection unit, wherein the control unit transmits the second signal before the first signal. Output to the communication device.
A communication device according to a second aspect of the invention includes a first light emitting unit that emits light and a first light emitting device that includes a first light receiving unit that receives light, and a second light emitting that includes a second light emitting unit that emits light. A communication unit that communicates with the device, a first signal for instructing to emit light from the first light emitting unit, and no light emitted from the first light emitting unit by the first signal in indicates a period awaiting the light from the second light emitting portion by said first light receiving portion in order to emit light from the first light emitting portion by receiving the light from said second light emitting portion by the first light receiving portion A control unit that inputs a second signal and outputs the second signal to the communication unit, and the control unit outputs the second signal to the communication unit before the first signal.

  According to the present invention, it is possible to improve the reliability when a light emission instruction is given wirelessly.

It is a figure which illustrates the structure of the imaging | photography system by one embodiment of this invention. It is a block diagram which illustrates the composition of a camera, a master wireless adapter, a remote wireless adapter, and an electronic flash device. It is a figure explaining the radio | wireless communication which a master radio | wireless adapter performs between remote radio | wireless adapters. It is a figure explaining the timing in the case of performing TTL light control in multi-flash photography.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating the configuration of an imaging system according to an embodiment of the present invention. The imaging system of FIG. 1 includes a camera 30 to which a master wireless adapter 10 and an electronic flash device 20 are mounted, an electronic flash device 20A to which a remote wireless adapter 10A is mounted, and an electronic flash device to which a remote wireless adapter 10B is mounted. 20B and the electronic flash device 20C to which the remote wireless adapter 10C is attached constitute a multi-flash photography system.

  Each of the electronic flash device 20 and the electronic flash devices 20 </ b> A to 20 </ b> C has a camera mounting leg that fits with an accessory shoe of the camera 30. In the example of FIG. 1, only the electronic flash device 20 is directly mounted on the camera 30 by the camera mounting leg, and the electronic flash devices 20A to 20C are respectively mounted on the remote wireless adapters 10A to 10C by the camera mounting leg. A remote wireless adapter may be built in the electronic flash device.

  The master wireless adapter 10 is attached to a connection terminal (not shown) on the side surface of the camera 30. The remote wireless adapters 10A to 10C have accessory shoes that are fitted to the camera mounting legs of the electronic flash devices 20A to 20C, respectively. The electronic flash devices 20A to 20C are attached to the accessory shoes of the remote wireless adapters 10A to 10C.

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

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

  The remote wireless adapter 10A and the electronic flash device 20A communicate with each other via a terminal (not shown) provided on the accessory shoe of the remote wireless adapter 10A. The remote wireless adapter 10B and the electronic flash device 20B perform wired communication 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 perform wired communication via a terminal (not shown) provided on the remote wireless adapter 10C and the accessory shoe.

  The configuration shown in FIG. 1 is a multi-flash photography system including one camera 30 and four electronic flash devices 20, 20A to 20C. The electronic flash devices 20 and 20A are group A, and the electronic flash is used. An example in which the device 20B is group B and the electronic flash device 20C is group C is illustrated. The total number of electronic flash devices need not be four, but may be three or eight. In addition, the number of electronic flash devices constituting each group may be changed as appropriate. Furthermore, the multi-flash flash photographing system may be configured using only the electronic flash devices 20A to 20C that perform wireless communication without using the electronic flash device 20 that is directly connected to the accessory shoe of the camera 30.

  FIG. 2 is a block diagram illustrating the configuration 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 this embodiment, since the circuit configurations of the master wireless adapter 10 and the remote wireless adapter 10A are the same, the same reference numerals are given to blocks that are common between the wireless adapters.

  Although not shown in FIG. 2, the configurations of the remote wireless adapter 10B and the electronic flash device 20B and the configurations of the remote wireless adapter 10C and the electronic flash device 20C are the same as those of the remote wireless adapter 10A and the electronic flash device 20A, respectively. The configuration is the same.

<Electronic flash device>
In FIG. 2, the electronic flash devices 20 and 20 </ b> A each include an arc tube 201 such as a xenon tube, an emission control circuit 202, and a CPU 203. The CPU 203 controls the light emission of the arc 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 light emission control circuit 202 includes a high voltage charging circuit and accumulates energy necessary for discharge light emission. The CPU 203 discharges the energy stored in the light emission control circuit 202 to cause the arc tube 201 to discharge light.

<Wireless adapter>
Each of the master wireless adapter 10 and the remote wireless adapter 10A includes an antenna 101, a communication circuit 102, 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 (the CPU 203 of the electronic flash device 20A or the CPU 306 of the camera 30), controls wireless communication performed with other wireless adapters, and will be described later. The flash standby control is performed.

  Flash standby control is a process that waits for light from another electronic flash device so that the electronic flash device can be triggered by the light emitted from another electronic flash device even if communication of the light emission command by wireless fails. Say. When the light from the other electronic flash device is received by the light receiving sensor 103 while waiting for the flash, the CPU 105 sends a light emission instruction to the CPU 203 of the electronic flash device connected by wired communication.

  The light receiving sensor 103 receives light from the outside (another electronic flash device) and sends a photoelectric conversion signal to the detection circuit 104. The detection circuit 104 sends a detection signal to the CPU 105 when a photoelectric conversion signal is input from the light receiving sensor 103 within the standby time designated by the CPU 105. The communication circuit 102 performs wireless 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 driving device 305, a CPU 306, and an operation member (including a release switch) 307.

  The photographing lens 301 forms a subject image on the imaging surface of the imaging element 303. The shutter 302 is controlled to be opened and closed by a shutter driving device 305. The photometric sensor 304 outputs a photometric signal corresponding 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 an aperture (not shown) by performing a predetermined exposure calculation based on the photometric signal. The CPU 306 also performs dimming control on the electronic flash devices 20 and 20A to 20C based on the output signal from the photometric sensor 304.

  The operation member 307 sends signals corresponding to various operations such as an operation signal of a release switch to the CPU 306. The image signal acquired by the image sensor 303 is subjected to predetermined image processing by the CPU 306 and recorded on a recording medium (not shown).

<Multi-flash photography>
When performing multi-flash photography, the CPU 306 of the camera 30 detects a pressing operation (shooting instruction) of the release switch 307 by the photographer and starts the release sequence process. Then, a light emission instruction is sent to the master wireless adapter 10 via wired communication. Prior to the photographing instruction, among the remote wireless adapters 10A to 10C (that is, the electronic flash devices 20A to 20C), the remote wireless adapter (electronic flash device) to be emitted is designated in advance by operating the operation member 307. Shall.

-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. This wired communication is appropriately performed as required by the camera 30.

  In communication between the camera 30 and the master wireless adapter 10, the camera 30 normally transmits a command (for example, a light emission gain command, a light emission command, etc.) and data to the master wireless adapter 10, and receives the master wireless adapter 10 that has received the data. Replies to the camera 30 (ack). The commands include commands for the electronic flash device 20A, commands for the electronic flash device 20B, and commands for the electronic flash device 20C.

―Wired communication between camera and electronic flash device―
Communication between the camera 30 (CPU 306) and the electronic flash device 20 (CPU 203) is also wired communication. This wired communication is also performed as required by the camera 30 as needed.

  In communication between the camera 30 and the electronic flash device 20, the camera 30 normally transmits a command (emission gain command, emission command, etc.) and data to the electronic flash device 20, and the electronic flash device 20 that receives the command transmits the command. Reply (ack) to 30. Commands include those for the electronic flash device 20.

− Communication between master wireless adapter and remote wireless adapter −
The communication between the master wireless adapter 10 and the remote wireless adapter 10A, the master wireless adapter 10 and the remote wireless adapter 10B, and the master wireless adapter 10 and the remote wireless adapter 10C is wireless communication. FIG. 3 is a diagram illustrating wireless communication performed by the master wireless adapter 10 with the remote wireless adapter 10A (remote wireless adapter 10B or remote wireless adapter 10C).

  The frequency of occurrence of wireless communication per remote wireless adapter is the same as the frequency 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, wireless communication is performed between the master wireless adapter 10 and each remote wireless adapter without delay.

  In the communication between the master wireless adapter 10 and the remote wireless adapter 10A (10B or 10C), the master wireless adapter 10 usually transmits the command and data to the remote wireless adapter 10A (10B or 10C) and receives it. The remote wireless adapter 10A (10B or 10C) returns (ack) to the master wireless adapter 10. The command includes a command for the electronic flash device 20A (20B or 20C) attached to the remote wireless adapter 10A (10B or 10C) of the communication partner.

-Communication between remote wireless adapter and electronic flash unit-
Communication between each remote wireless adapter 10A (10B or 10C) and the electronic flash device 20A (20B or 20C) is wired communication. This wired communication is immediately performed between each remote wireless adapter 10A (10B or 10C) and the corresponding electronic flash device after wireless communication with the master wireless adapter 10.

  Communication between the remote wireless adapter 10A (10B or 10C) and the electronic flash device 20A (20B or 20C) is usually to the electronic flash device 20A (20B or 20C) to which the remote wireless adapter 10A (10B or 10C) corresponds. The electronic flash device 20A (20B or 20C) that has received the command and data and sends it back (ack) to the remote wireless adapter 10A (10B or 10C). The command includes a command for the electronic flash device 20A (20B or 20C) attached to the remote wireless adapter 10A (10B or 10C).

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

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

  In the release sequence processing at the time of TTL light control, the camera 30 (CPU 306) causes each electronic flash device 20 before the shutter driving device 305 receiving the instruction from the CPU 306 opens the shutter 302 to open the front curtain of the shutter 302. And 20A to 20C are caused to perform monitor light emission in order for each group (time t3, t5, t7). The photometric sensor 304 of the camera 30 is controlled to receive reflected light from the subject when the monitor emits light (light control exposure). Based on the photometric signal output from the photometric sensor 304, the CPU 306 calculates the light emission amount (hereinafter referred to as the main light emission amount) during the main light emission of the electronic flash devices 20 and 20A to 20C.

  A calculation example of the light emission amount is as follows. The photometric signal output from the photometric sensor 304 in a state in which neither the electronic flash device 20 nor 20A to 20C emits light, and the photometric sensor 304 in a state in which the group A (the electronic flash device 20 and the electronic flash device 20A) emits the monitor light. Based on the difference from the output photometric signal, the light emission amount of group A necessary for the main light emission is calculated. Similarly, for group B and group C, the photometric signal output from the photometric sensor 304 without emitting light from the electronic flash device 20B (20C) and the photometric measurement with the electronic flash device 20B (20C) emitting monitor light, respectively. Based on the difference from the photometric signal output from the sensor 304, the light emission amount of group B (group C) necessary for the main light emission is calculated. At this time, if the amount of the first monitor light emission is not appropriate, the monitor light emission amount may be changed and the monitor light emission may be performed again to calculate the light emission amount.

  The CPU 306 causes the electronic flash devices 20 and 20A to 20C to perform main light emission substantially simultaneously at time t9 when the shutter 302 is fully open (main exposure).

  Hereinafter, detailed light emission timings of the electronic flash devices 20 and 20A to 20C will be described. The camera 30 (CPU 306) that has started the release sequence process at time t0 sends a command to the master wireless adapter 10 and wireless communication for light emission preparation to the electronic flash devices 20A to 20C connected via wireless communication. To do. In wireless communication for light emission preparation, a rough time schedule of light emission is notified in advance.

  The time schedule to be notified includes time information (time when wireless communication is transmitted (referred to as start time)), scheduled monitor light emission time and scheduled light emission time for each group based on the start time, monitor light emission amount, and start time The information of the standby timing for each group with reference to is included.

  The wireless communication for light emission preparation is transmitted from the master wireless adapter 10 to all the remote wireless adapters 10A (10B or 10C), and all the remote wireless adapters 10A (10B, 10C) return (ack) to the master wireless adapter 10. The camera 30 (CPU 306) receives the reply (ack) from all the remote wireless adapters 10A (10B, 10C) by the master wireless adapter 10 so that the wireless communication for light emission preparation is performed on all the remote wireless adapters 10A (10B). 10C). The wireless communication for light emission preparation increases the probability of success by repeating a plurality of times during a predetermined time (for example, 500 msec) from time t0 to time t1.

<Instruction of monitor light emission A to group A>
The master wireless adapter 10 transmits a command of monitor light emission A to the remote wireless adapter 10A of group A by wireless communication, for example, at time t2 after 300 msec has elapsed from time t1 when wireless communication for light emission preparation has ended. The command transmission of the monitor light emission A is one-way wireless communication that does not require a reply (ack) from the remote wireless adapter 10A.

  Although FIG. 4 illustrates the case where the remote wireless adapter 10A fails to receive the monitor light emission A command, the operation when the remote wireless adapter 10A normally receives the monitor light emission A command will be described first.

  When receiving the monitor light emission A command, the remote wireless adapter 10A transmits the monitor light emission A command to the connected electronic flash device 20A by wired communication. As a result, the electronic flash device 20A performs monitor light emission A at time t3. The remote wireless adapter 10A further sets a period until a predetermined time (for example, 300 msec) elapses from the end of command transmission of the monitor light emission A as a standby period for the above-described flash standby control. The standby period is based on the above time schedule and is provided to include time t3.

  At time t2 based on the time schedule, the camera 30 transmits a monitor light emission A command to the group A electronic flash devices 20 by wired communication. Upon receiving the monitor light emission A command, the electronic flash device 20 performs monitor light emission A at time t3.

<Instruction of monitor light emission B to group B>
For example, at time t4 after 600 msec has elapsed from time t2, the master wireless adapter 10 transmits a monitor light emission B command to the remote wireless adapter 10B of group B by wireless communication. The command transmission of the monitor light emission B is one-way wireless communication that does not require a reply (ack) from the remote wireless adapter 10B.

  When receiving the monitor light emission B command, the remote wireless adapter 10B transmits the monitor light emission B command to the connected electronic flash device 20B by wired communication. As a result, the electronic flash device 20B performs monitor light emission B at time t5. The remote wireless adapter 10B further sets a period until a predetermined time (for example, 300 msec) elapses from the end of the command transmission of the monitor light emission B as a standby period for the above-described flash standby control. The standby period is based on the above time schedule and is provided to include time t5.

<Instruction of monitor light emission B to group C>
For example, at time t6 after 600 msec has elapsed from time t4, the master wireless adapter 10 transmits a monitor light emission C command to the remote wireless adapter 10C in group C by wireless communication. The command transmission of the monitor light emission C is one-way wireless communication that does not require a reply (ack) from the remote wireless adapter 10C.

  When the remote wireless adapter 10C receives the monitor light emission C command, it transmits the monitor light emission C command to the connected electronic flash device 20C by wired communication. As a result, the electronic flash device 20C performs monitor light emission C at time t7. The remote wireless adapter 10 </ b> C further sets a period until a predetermined time (for example, 300 msec) elapses from the end of the command transmission of the monitor light emission C as a standby period for the above-described flash standby control. The standby period is based on the above time schedule and is provided to include time t7.

<Instruction of main light emission for all of groups A, B, and C>
FIG. 4 illustrates the case where the remote wireless adapter 10B has failed to receive the main light emission command, but the operation when the remote wireless adapter 10B normally receives the main light emission A command will be described first.

  At time t8 based on the time schedule (for example, after 500 msec from the end of the command transmission of the monitor light emission C), the master wireless adapter 10 wirelessly transmits a main light emission command and each main light emission amount to all the remote wireless adapters 10A to 10C. Send by communication. The wireless communication is one-way communication that does not require a reply (ack) from each of the remote wireless adapters 10A to 10C. On the other hand, at time t8, the camera 30 transmits a main light emission command and a main light emission amount to the group A electronic flash devices 20 by wired communication.

  The remote wireless adapters 10A to 10C upon receiving the main light emission command transmit the main light emission command to the connected electronic flash devices 20A to 20C by wired communication. At time t8 based on the time schedule, the camera 30 transmits a main light emission command to the group A electronic flash devices 20 by wired communication.

  The electronic flash devices 20A to 20C and the electronic flash device 20 perform the main light emission at time t9 by the transmission of the main light emission command. The remote wireless adapters 10A to 10C further set a period until a predetermined time (for example, 700 msec) elapses from the end of transmission of the main light emission command as a standby period for flash standby control. The standby period during the main light emission is based on the above time schedule, and is provided so as to include time t9.

<Purpose of flash standby control>
When transmitting the monitor light emission A command, the monitor light emission B command, the monitor light emission C command, the main light emission command, and the main light emission amount via wireless communication, in the same frequency band as the frequency band used by the master wireless adapter 10. If communication is concentrated, communication from the master wireless adapter 10 to the remote wireless adapters 10A, 10B, and 10C may not be performed normally, and command transmission of monitor light emission or main light emission may not reach. As a specific example, FIG. 4 illustrates a case where the remote wireless adapter 10A fails to receive the monitor light emission A command and the remote wireless adapter 10B fails to receive the main light emission command.

  In the present embodiment, the light receiving sensor 103 receives light from another electronic flash device 20 (20A, 20B, or 20C) during a predetermined period based on the above time schedule, and is connected as a trigger. The electronic flash device 20A (20B or 20C) is caused to emit light.

  In the flash standby control illustrated in FIG. 4, the remote wireless adapter 10 </ b> A that failed to receive the monitor light A command at the time of monitor light emission (time t <b> 2) is from the electronic flash device 20 included in the same group A as the remote wireless adapter 10 </ b> A. The monitor light emission (time t3) is received, and the electronic flash device 10A emits the monitor light.

  Further, at the time of the main light emission, the remote wireless adapter 10B that failed to receive the main light emission command (time t8) receives the light of the main light emission (time t9) from at least one of the electronic flash devices 20, 20A, and 20C. Light is received and the electronic flash device 20B is caused to emit main light.

  Note that the light receiving sensor 103 causes the connected electronic flash device 20A (20B or 20C) to emit light when triggered by receiving flash light from another electronic flash device 20 (20A, 20B, or 20C). Assume that the electronic flash device 20A (20B or 20C) does not emit light due to failure in receiving the monitor light emission or the main light emission command. In addition, the flash standby control is performed only during a predetermined period based on the above time schedule, and is limited to the period from the start of the flash standby for receiving the light emission trigger via the light receiving sensor 103 to the end of the flash standby (timeout). Is provided.

According to the embodiment described above, the following operational effects can be obtained.
(1) The camera 30 includes a CPU 306 that issues a light emission command to the electronic flash device 20A, and a CPU 306 that instructs the master wireless adapter 10 to transmit a light emission command. The CPU 306 prior to transmitting the light emission command, the electronic flash device The master wireless adapter 10 is instructed to transmit time schedule information for 20A. As a result, for example, even if the wireless transmission of the light emission command fails, the electronic flash device 20A can cope with light emission based on the time schedule, so that the conventional technique in which the failure of the wireless transmission is immediately linked to no light emission. Compared with this, the reliability can be improved.

(2) Since the time schedule includes information indicating the base time, the scheduled light emission time, and the light emission amount, the electronic flash device 20A can appropriately perform light emission according to the time schedule.

(3) The electronic flash device 20A (remote wireless adapter 10A) is transmitted by wireless communication from the arc tube 201, the remote wireless adapter 10A communicating with the master wireless adapter 10 (camera 30), and the camera 30, and the remote wireless adapter 10A. And a light receiving sensor 103 that receives light emitted from another electronic flash device, and the CPU 203 receives the light emitted from the light emitting sensor 103. , The arc tube 201 is caused to emit light. As a result, even if the wireless transmission of the light emission command fails, for example, it can emit light according to the light emitted from other electronic flash devices, so reliability is improved compared to the conventional technology in which the failure of wireless communication is immediately linked to no light emission. Can be increased.

(4) The CPU 203 limits the period during which the light-emitting tube 201 emits light in response to the light-receiving sensor 103 receiving the emitted light, to a predetermined flash standby period, so that the light-emitting tube responds to unintended external light. It is possible to avoid causing 201 to emit light.

(5) When the light emitting tube 201 is not caused to emit light in response to the light emission command input via the remote wireless adapter 10A, the CPU 203 emits the light emitting tube 201 in response to the light receiving sensor 103 receiving the emitted light. For example, when the wireless transmission of the light emission command fails, the light can be appropriately emitted.

(Modification 1)
In the above description, the example in which the master wireless adapter 10 is attached to the camera 30 has been described. However, the master wireless adapter 10 may be built in the camera 30.

(Modification 2)
In the above description, the example in which the electronic flash device 20 is mounted on the camera 30 has been described. However, the electronic flash device 20 may be built in the camera 30.

(Modification 3)
In the embodiment described above, an example has been described in which the wireless communication for light emission preparation increases the probability of success by repeating wireless communication a plurality of times during a predetermined time (for example, 500 msec) from time t0 to time t1. Instead of this, the reliability of wireless communication may be improved by subdividing the timing at which communication is not performed in a series of sequence processing and performing wireless communication little by little. In general, allocating a period of time between time t0 and time t1 leads to an increase in the time lag from the photographing instruction to the main exposure, and therefore, when it is desired to suppress the time lag, subdivided wireless communication is effective.

  The above description is merely an example, and is not limited to the configuration of the above embodiment.

DESCRIPTION OF SYMBOLS 10 ... Master wireless adapter 10A, 10B, 10C ... Remote wireless adapter 20, 20A, 20B, 20C ... Electronic flash device 30 ... Camera 101 ... Antenna 102 ... Communication circuit 103 ... Light receiving sensor 104 ... Detection circuit 105, 203, 306 ... CPU
201 ... arc tube 202 ... light emission control circuit

Claims (22)

Communication that performs communication between a first light emitting device that includes a first light emitting unit that emits light and a first light receiving unit that receives light, and a second light emitting device that includes a second light emitting unit that emits light. A connection that can be connected to the device;
A first signal for instructing to emit light from the first light emitting unit, and when no light is emitted from the first light emitting unit by the first signal, the first light receiving unit causes the second light emitting unit to A second signal indicating a period in which the first light receiving unit waits for light from the second light emitting unit to emit light from the first light emitting unit by receiving the light of the first light emitting unit, and the second signal connected to the connection unit A control unit that outputs to the communication device,
The control unit is a camera that outputs the second signal to the communication device before the first signal. The camera of claim 1,
The timing at which light is emitted from the first light emitting unit according to the first signal is faster than the timing at which light is emitted from the first light emitting unit by receiving light from the second light emitting unit at the first light receiving unit. The camera according to claim 1 or 2,
The control unit is a camera that outputs the second signal a plurality of times. In the camera according to any one of claims 1 to 3,
The control unit is a camera that requests a reply from the first light emitting device after outputting the second signal. In the camera according to any one of claims 1 to 4,
The control unit does not request a reply from the first light emitting device after outputting the first signal. The camera according to any one of claims 1 to 5 ,
The second light emitting device includes a second light receiving unit that receives light,
In the case where no light is emitted from the second light emitting unit according to the third signal and the third signal for instructing to emit light from the second light emitting unit, the control unit is configured to A fourth signal indicating a period during which the second light receiving unit waits for light from the first light emitting unit to emit light from the second light emitting unit by receiving light from the first light emitting unit; Output to the communication device connected to
The control unit is a camera that outputs the fourth signal to the communication device before the third signal. The camera according to claim 6 , wherein
The control unit is a camera that outputs the fourth signal to the communication device before the first signal. The camera according to claim 6 or 7 ,
The timing at which light is emitted from the second light emitting unit by the third signal is faster than the timing at which light is emitted from the second light emitting unit by receiving light from the first light emitting unit at the second light receiving unit. The camera according to any one of claims 6 to 8 ,
The control unit is a camera that outputs the fourth signal a plurality of times. The camera according to any one of claims 6 to 9 ,
The control unit is a camera that requests a reply from the second light emitting device after outputting the fourth signal. The camera according to any one of claims 6 to 10 ,
The controller does not request a reply from the second light emitting device after outputting the third signal. The camera according to any one of claims 6 to 11 ,
The control unit outputs a timing at which light is emitted from the second light emitting unit as the fourth signal. The camera according to claim 12 , wherein
The control unit is a camera that outputs a light emission amount of the second light emitting unit as the fourth signal. Communication that performs communication between a first light emitting device that includes a first light emitting unit that emits light and a first light receiving unit that receives light, and a second light emitting device that includes a second light emitting unit that emits light. And
A first signal for instructing to emit light from the first light emitting unit, and when no light is emitted from the first light emitting unit by the first signal, the first light receiving unit causes the second light emitting unit to A second signal indicating a period during which the first light receiving unit waits for light from the second light emitting unit in order to emit light from the first light emitting unit by receiving the light, and outputs the second signal to the communication unit A control unit,
The control unit is a communication device that outputs the second signal to the communication unit before the first signal. The communication device according to claim 14 , wherein
A communication device that emits light from the first light emitting unit in response to the first signal is faster than a timing at which light is emitted from the first light emitting unit by receiving light from the second light emitting unit at the first light receiving unit. . The communication device according to claim 14 or 15 ,
The control unit is a communication device that outputs the second signal a plurality of times. The communication device according to any one of claims 14 to 16 ,
The second light emitting device includes a second light receiving unit that receives light,
In the case where no light is emitted from the second light emitting unit according to the third signal and the third signal for instructing to emit light from the second light emitting unit, the control unit is configured to A fourth signal indicating a period in which the second light receiving unit waits for light from the first light emitting unit to emit light from the second light emitting unit by receiving light from the first light emitting unit; Output to
The control unit is a communication device that outputs the fourth signal to the communication unit before the third signal. The communication device according to claim 17 ,
The control unit is a communication device that outputs the fourth signal to the communication unit before the first signal. The communication device according to claim 17 or claim 18 ,
The communication device that emits light from the second light emitting unit by the third signal is faster than the timing at which light is emitted from the second light emitting unit by receiving light from the first light emitting unit at the second light receiving unit. . The communication device according to any one of claims 17 to 19 ,
The control unit is a communication device that outputs the fourth signal a plurality of times. The communication device according to any one of claims 17 to 19 ,
The said control part is a communication apparatus which outputs the timing which emits light from a said 2nd light emission part as a said 4th signal. The communication device according to claim 21 ,
The said control part is a communication apparatus which outputs the light-emission quantity of a said 2nd light emission part as a said 4th signal.

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