JP5593828B2 - Imaging system and communication adapter - Google Patents

Description

The present invention relates to an imaging system and a communication adapter .

  A technique for synchronizing processing between devices connected via wireless communication is known (see Patent Document 1). According to Patent Document 1, the master electronic flash device individually transmits a light emission confirmation packet to a plurality of remote electronic flash devices, and the remote electronic flash device that has received the light emission confirmation packet transmits a report packet to the master electronic flash device. To do.

JP 2008-32909 A

  In the prior art, the master electronic flash device performs packet communication with one remote electronic flash device and then performs packet communication with another remote electronic flash device. If communication of a packet with a certain remote electronic flash device fails (transmission / reception does not end), there is a problem that communication with another remote electronic flash device cannot be started and processing is delayed.

Imaging system according to the present invention, have a communication function, a camera for outputting a command to the first illumination device for photography, a first communication adapter for performing a first communication between the camera, the first communication adapter A second communication adapter that performs second communication between the second communication adapter and a first photographing illumination device that performs third communication with the second communication adapter, and a command output from the camera is for the first photographing. The first, second, and third communications are performed asynchronously with each other when the command is not a command for instructing the light emitting operation for the lighting device .
It is characterized by.
The communication adapter according to the present invention performs first communication with a camera that outputs a command to the photographing illumination device, and performs second communication with a communication adapter that communicates with the photographing illumination device. A communication adapter for a camera, wherein the communication adapter for the camera performs the first communication and the second communication when the command output from the camera is not a command for instructing the light emission operation to the photographing illumination device. It is characterized by being performed asynchronously with each other.
The communication adapter according to the present invention performs first communication with a communication adapter that performs communication with a camera that outputs a command to the photographing illumination device, and also performs second communication with the photographing illumination device. The communication adapter for the photographic illumination device is configured to perform the first operation when the command output from the camera is not a command for instructing the light emission operation to the photographic illumination device. The communication and the second communication are performed asynchronously with each other.

  ADVANTAGE OF THE INVENTION According to this invention, the imaging | photography system which performs radio | wireless communication appropriately can be provided.

It is a figure explaining 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 communication which an imaging | photography system performs. It is a figure explaining a communication packet. It is a figure which illustrates the communication packet by this embodiment. FIG. 10 is a diagram illustrating a configuration of modification example 3.

  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. This photographing system includes a camera 30 to which a master wireless adapter 10 is attached and an electronic flash device 20A to which a remote wireless adapter 10A is attached. The master wireless adapter 10 and the remote wireless adapter 10A perform wireless communication according to a standard such as a wireless LAN, Bluetooth (registered trademark), or ZigBee (registered trademark).

  In addition to the electronic flash device 20A, the electronic flash device 20B is equipped with a remote wireless adapter 10B, and the electronic flash device 20C is equipped with a remote wireless adapter 10C. The master wireless adapter 10 and the remote wireless adapter 10B, and the master wireless adapter 10 and the remote wireless adapter 10C perform wireless communication according to the above-mentioned standards.

  The remote wireless adapter 10A is configured in the same manner as the remote wireless adapter 10B and the remote wireless adapter 10C, and the electronic flash device 20A is configured in the same manner as the electronic flash device 20B and the electronic flash device 20C.

  The master wireless adapter 10 has a camera mounting leg that fits into an accessory shoe of the camera 30 and is attached to the camera 30 by the camera mounting leg. The remote wireless adapter 10A has an accessory shoe that fits with the camera mounting leg of the electronic flash device 20A, and is attached to the electronic flash device 20A by the accessory shoe.

  The reason why the electronic flash device 20A has the camera mounting leg is that the electronic flash device 20A can also be used by being directly attached to the accessory shoe of the camera 30. When the electronic flash device 20A is directly attached to the camera 30, wireless communication is not performed because wired communication is performed between the electronic flash device 20A and the camera 30 via a terminal (not shown) provided in the accessory shoe.

  Since the present embodiment has a feature in a usage mode in which wireless communication is performed between the electronic flash device 20A and the camera 30, the following description will be made with the remote wireless adapter 10A attached to the electronic flash device 20A and the master wireless to the camera 30. This is mainly performed when the adapter 10 is attached.

  The system illustrated in FIG. 1 is a light increase system configured with one camera 30 and three electronic flash devices 20A to 20C, but the number of electronic flash devices may not be three. One or one unit may be used.

  FIG. 2 is a block diagram illustrating the configuration of the camera 30, the master wireless adapter 10, the remote wireless adapter 10A, and the electronic flash device 20A. Since the master wireless adapter 10 and the remote wireless adapter 10A have the same configuration, the same reference numerals are assigned to the corresponding blocks between the wireless adapters.

  Although not shown, 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 the configurations of the remote wireless adapter 10A and the electronic flash device 20A, respectively. It is.

  In FIG. 2, the electronic flash device 20 </ b> A includes a light emitting tube 201 such as a xenon tube, a light emission control circuit 202, and a CPU 203. In addition, the remote wireless adapter 10A and the master wireless adapter 10 include an antenna 101, a frequency down converter 102, a modulation transmission circuit 103, a demodulation circuit 104, detectors 105 and 109, an oscillator 106, and a buffer memory 107, respectively. 110 and CPU 108.

  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.

<Wired communication 1>
FIG. 3 is a diagram illustrating communication performed by the above-described imaging system. In FIG. 3, wired communication 1 on the left side represents wired communication performed by the camera 30 with the master wireless adapter 10, and is performed via a terminal (not shown) provided in the accessory shoe. This wired communication 1 is cyclically determined at predetermined time intervals (for example, 100 msec) regardless of the wireless communication performed by the master wireless adapter 10 with the remote wireless adapter 10A (10B or 10C) (that is, asynchronously). The communication speed (for example, 62.5 kbps) is used. Here, “synchronization” means to align reference points on the time axis for the execution timing of a plurality of processes (in this example, wired communication 1 and wireless communication, or wireless communication and wired communication 2). Includes a case where a predetermined time difference is always provided, and a case where a plurality of processes are always performed simultaneously. On the other hand, “asynchronous” is a case that does not correspond to the above “synchronous”, and means that one process is performed regardless of the execution timing of the other process.

  In communication between the camera 30 and the master wireless adapter 10, the camera 30 usually 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 include commands for the electronic flash device 20A, commands for the electronic flash device 20B, and commands for the electronic flash device 20C.

<Wireless communication>
In FIG. 3, central wireless communication represents wireless communication performed by the master wireless adapter 10 with the remote wireless adapter 10A (remote wireless adapter 10B or remote wireless adapter 10C). This wireless communication is performed at a predetermined communication speed (for example, 250 kbps) cyclically at predetermined time intervals (for example, 30 msec) irrespective of the wired communication 1 performed by the master wireless adapter 10 with the camera 30 (that is, asynchronous). ).

  Here, the frequency of wireless communication is set higher than the communication frequency of wired communication 1 and wired communication 2 described later. In this embodiment, since the master wireless adapter 10 communicates wirelessly with three remote wireless adapters, the waiting time for the wired communication 1 (wired communication 2) (the waiting time until the next wired communication 1 (wired communication 2) is performed). This is because wireless communication is performed with three remote wireless adapters. Since wireless communication and wired communication 1 (wired communication 2) are asynchronous, not only standby time of wired communication 1 (wired communication 2) but also wireless communication in the middle of wired communication 1 (wired communication 2) may occur. .

  In general, when the master wireless adapter 10 performs communication of a predetermined packet with the remote wireless adapter 10A, the master wireless adapter 10 performs communication of the predetermined packet with the remote wireless adapter 10B instead of the remote wireless adapter 10A. The packet will be described later. When a predetermined packet is communicated with the remote wireless adapter 10B, the predetermined packet is communicated with the remote wireless adapter 10C instead of the remote wireless adapter 10B. Thereafter, similarly, instead of the remote wireless adapter 10C, communication of a predetermined packet is performed again with the remote wireless adapter 10A. Thus, the master wireless adapter 10 repeats communication with the remote wireless adapter 10A (10B or 10C) in a time division manner.

  In communication between the master wireless adapter 10 and the remote wireless adapter 10A (10B or 10C), the master wireless adapter 10 usually transmits both commands and data, or only commands, to the remote wireless adapter 10A (10B or 10C). The remote wireless adapter 10A (10B or 10C) that has received this returns (ack) or returns data 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.

<Wired communication 2>
In FIG. 3, wired communication 2 on the right side represents wired communication performed by each remote wireless adapter 10A (10B or 10C) with the electronic flash device 20A (20B or 20C), and a terminal (not shown) provided in the accessory shoe is provided. Done through. This wired communication 2 is cyclically determined at predetermined time intervals (for example, 100 msec) independently of the wireless communication performed by the remote wireless adapter 10A (10B or 10C) with the master wireless adapter 10 (that is, asynchronously). The communication speed (for example, 62.5 kbps) is used.

  Communication between the remote wireless adapter 10A (10B or 10C) and the electronic flash device 20A (20B or 20C) is normally performed by the remote wireless adapter 10A (10B or 10C) to the electronic flash device 20A (20B or 20C) and Both the data or only the command is transmitted, and the electronic flash device 20A (20B or 20C) that receives the command returns (ack) or returns data 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).

  Since the wired communication 1 and the wired communication 2 according to the present embodiment are performed between devices directly connected via an accessory shoe, communication failure does not occur in a normal usage mode. On the other hand, in the above wireless communication, for example, when the remote wireless adapter 10A (electronic flash device 20A) is moved out of the communicable range with the camera 30, or radio waves (noise) emitted from other devices. ), The remote wireless adapter 10A may not receive a command from the camera 30, or the camera 30 may not receive a reply from the remote wireless adapter 10A.

<Timeout processing 1>
Therefore, if the reply from the remote wireless adapter 10A (10B and 10C) that transmitted only the command cannot be received after a predetermined time (for example, 30 msec), the master wireless adapter 10 gives up that the communication has failed. Proceed to the next process. In FIG. 3, “* 1” indicates an example in which the return of data from the remote wireless adapter 10B is delayed. In this case, the master wireless adapter 10 receives the data when it is returned within 30 msec, but does not receive it when it is later than 30 msec (performs the next process without waiting).

  When the data requested from the camera 30 after the communication failure is related to the remote wireless adapter 10B (electronic flash device 20B) that has failed in the communication, the master wireless adapter 10 receives the data from the remote wireless adapter 10B during the most recent communication. The transmitted data is sent to the camera 30.

  Furthermore, the master wireless adapter 10 transmits the same command as the previous failure again to the remote wireless adapter 10B at the next communication with the remote wireless adapter 10B. Such re-transmission (retry) is performed a predetermined number of times (for example, three times), and if a reply from the remote wireless adapter 10B cannot be received even after a predetermined number of retries, communication with the remote wireless adapter 10B is not performed. Judge that it is impossible and terminate the retry. When it is determined that communication is impossible, when data related to the remote wireless adapter 10 </ b> B (electronic flash device 20 </ b> B) is requested from the camera 30, data including communication failure is transmitted to the camera 30.

<Timeout processing 2>
When the master wireless adapter 10 cannot receive a reply from the remote wireless adapter 10A (10B and 10C) that has transmitted both the command and data or only the data even after a predetermined time (for example, 30 msec), the communication is Give up on failure and proceed to the next process. In FIG. 3, “* 2” indicates an example in which the command has not reached the remote wireless adapter 10C. In this case, the master wireless adapter 10 transmits the same command and data, or only data, to the remote wireless adapter 10C again. Such re-transmission (retry) is performed a predetermined number of times (for example, three times), and if a reply from the remote wireless adapter 10C cannot be received even after a predetermined number of retries, communication with the remote wireless adapter 10C is not performed. Judge that it is impossible and terminate the retry.

  When the data requested from the camera 30 after the communication failure is related to the remote wireless adapter 10C (electronic flash device 20C) that has failed in the communication, the master wireless adapter 10 receives from the remote wireless adapter 10C during the most recent communication. The transmitted data is sent to the camera 30. If it is determined that communication is not possible, data including that is sent to the camera 30.

  By performing “timeout process 1” or “timeout process 2” as described above, even if wireless communication with one remote wireless adapter fails, communication processing with other remote wireless adapters is performed as usual. However, retry processing is performed at the timing when communication is performed again with the remote wireless adapter that has failed in communication.

<Light emission control>
An example of light emission control performed by the photographing system will be described. In the light emission control, when the user presses the release switch 307 of the camera 30, the shutter 302 is opened and the subject image input through the lens 301 is picked up by the image pickup device 303, the light emission timing of the electronic flash device 20A, This is performed to synchronize the light emission timings of the electronic flash device 20B and the electronic flash device 20C.

  Further, in order to determine the light emission amount of each of the electronic flash devices 20A to 20C at the time of photographing, preliminary light emission (monitor light emission) that emits light with a lower light intensity than at the time of main light emission is performed prior to light emission at the time of photographing (main light emission). In some cases, this is also performed to synchronize the light emission timing of each of the electronic flash devices 20A to 20C and the photometry timing by the photometry sensor 304.

  In order to synchronize the timing, in this embodiment, the CPU 108 of the master wireless adapter 10 instructs the remote wireless adapter 10A (10B, 10C) to perform monitor light emission and main light emission based on a signal from the CPU 306 of the camera 30. put out. At this time, a communication packet conforming to a digital communication format including a signal (synchronization data) for synchronizing the timing of main light emission and the timing of monitor light emission and control information indicating the contents of control is generated. For example, the CPU 108 generates a communication packet having a format as shown in FIG. In FIG. 4, preamble 4a is data such as a run-up portion transmitted at the beginning of communication, and transmission of preamble 4a of about 4 bytes is obligatory. In the preamble 4a, a fixed bit pattern such as 0, 0, 0, 0... is set.

  The SFD (Start of Frame Delimiter) 4b is data for synchronization added to the head part of the packet following the preamble 4a. Frame length 4c is data indicating the communication data capacity (number of bytes). Thereafter, according to the standard, a 2-byte FCF (Frame Control Field) 4d and a 1-byte Data Sequence Number 4e are subsequently added. However, since communication itself can be put into practical use without completely complying with the standard, in the present embodiment, these FCF 4d and Data Sequence Number 4e are omitted, and as shown in FIG. A byte command 4f, a 1-byte counterpart ID 4g, and data 4h including various information are added.

  The SFD 4b is originally fixed data inherent to the communication method, and has a function of preventing malfunction when it interferes with other communications. That is, on the receiving side, when a communication packet including an SFD whose data pattern does not match the preset SFD is received, it is determined that the packet is not a packet to be received by itself.

  In the present embodiment, the CPU 306 of the camera 30, the CPU 108 of the master wireless adapter 10, the CPU 108 of the remote wireless adapter 10A, the CPU 108 of the remote wireless adapter 10B, the CPU 108 of the remote wireless adapter 10C, and the CPU 203 of the electronic flash device 20A. In addition, the CPU 203 of the electronic flash device 20B and the CPU 203 of the electronic flash device 20C use the SFD 4b for the purpose of preventing malfunction during such interference, and as described above, the main flash of the electronic flash device 20A. It is used as synchronization data for synchronizing the timing, the main light emission timing of the electronic flash device 20B, the main light emission timing of the electronic flash device 20C, and the timing of opening the shutter 302 of the camera 30.

  Similarly, the SFD 4b is also used as synchronization data for synchronizing the monitor light emission timing of each of the electronic flash devices 20A to 20C and the photometric timing by the photometric sensor 304.

  Specifically, the transmission side outputs a synchronization signal for synchronization at the timing of transmitting SFD 4b, and the reception side outputs the synchronization signal at the timing of receiving SFD 4b. Then, on each of the transmission side and the reception side, by executing a command defined in the command 4f described later after a predetermined time set after the synchronization signal is output, the processing timing on the transmission side and the reception side is set. Match.

  Here, since a delay time (reception delay time) such as a decoding time is generated on the reception side compared to the transmission side, the reception completion timing A of the SFD 4b on the reception side is higher than the transmission completion B timing of the SFD 4b on the transmission side. May be delayed, and the two may not match completely. However, this delay time is extremely small compared to the light emission time of the electronic flash devices 20A to 20C, and can be ignored. Even when a delay time that cannot be ignored occurs, this delay time is almost constant, so it is set in advance as a fixed value and defined in the command 4f in consideration of this delay time. By adjusting the command execution timing, the processing timings of the transmission side and the reception side are matched.

  In the present embodiment, a method of matching the processing timings of the transmission side and the reception side based on the transmission / reception completion timings A and B of the SFD 4b will be described. However, the transmission side and the reception side are determined based on the transmission / reception completion timing of the Frame length 4c. The processing timing on the side may be matched.

  The command 4f is data representing a control command for starting processing. For example, data representing the main light emission start command is added as the command 4f to the communication packet (main light emission start packet) instructing execution of the main light emission described above. Further, data representing a monitor light emission activation command is added as the command 4f to the communication packet (monitor light emission activation packet) instructing execution of the monitor light emission described above. The counterpart ID 4g includes the ID of the electronic flash device 20A (20B or 20C) that is the execution target of the control command defined by the command 4f. That is, it instructs the electronic flash device 20A (20B or 20C) designated by the counterpart ID 4g to execute the control command defined by the command 4f.

  Here, IDs (individual IDs) are individually added to the electronic flash devices 20A to 20C, and the electronic flash devices 20A to 20C can be uniquely identified by the individual IDs. Therefore, the individual ID can be designated as the counterpart ID 4g, and the execution target of the command 4f can be designated.

  Further, instead of this individual ID, an ID (all device IDs) for designating all the electronic flash devices 20A to 20C as the execution target of the command 4f can be designated. For example, when the individual IDs of the three electronic flash devices 20A to 20C shown in FIG. 1 are 1 to 3, respectively, 0 can be specified as the total device ID when these are specified together.

  As a result, when all the electronic flash devices 20A to 20C want to execute the same command 4f (actual light emission activation or the like), all the electronic flash devices 20A to 20C are designated by designating all device IDs as the counterpart ID 4g. Can be collectively instructed to execute the control command defined by the command 4f. On the other hand, when it is desired that the electronic flash devices 20A to 20C individually execute the command 4f (such as monitor light emission activation), the individual flash device 20A to 20C is individually designated by specifying the individual ID for the counterpart ID 4g. Can be instructed to execute the control command defined by the command 4f. As described above, in the electronic flash devices 20A to 20C that have received the communication packet, the definition is made by the command 4f when the partner ID 4g includes its own individual ID or all device IDs. Recognize that the target of executing the control command is itself.

  The type of data 4h includes mode information, time information, check data, and the like. The mode information is information indicating an operation mode such as a light emission mode indicating main light emission or monitor light emission. The time information is information related to a predetermined time from the output of the synchronization signal to the start of processing. The check data is error check data such as a checksum and CRC for preventing malfunction.

<Processing on the camera and master wireless adapter side>
-Monitor flash-
The communication packet (monitor light emission activation packet) is individually transmitted to each of the electronic flash devices 20A to 20C. After entering the shooting sequence, the CPU 306 of the camera 30 sends a monitor light emission command to the master wireless adapter 10 to the master wireless adapter 10 (wired communication 1). The CPU 108 of the master communication adapter 10 issues a monitor emission instruction to the remote wireless adapters 10A to 10C based on a signal (monitor emission command) from the camera 30. At this time, a communication packet is generated in order to synchronize the timing of monitor light emission.

  The communication packet generated by the CPU 108 of the master communication adapter 10 is temporarily stored in the buffer memory 110 and then output to the detector 109. The detector 109 reads an input packet from the beginning and analyzes it. The detector 109 outputs a synchronization signal to the CPU 108 when detecting that the reading of the SFD 4b as the synchronization data is completed. That is, the detector 109 detects the synchronization data before completing the transmission of the communication packet. The detector 109 outputs this synchronization signal as an interrupt signal to the synchronization timing pin (interrupt terminal) of the CPU 108. Then, the CPU 108 outputs a synchronization interrupt signal to the CPU 306 of the camera 30.

  The CPU 108 of the master wireless adapter 10 and the CPU 306 of the camera 30 start timing when each detects an interrupt of a synchronization signal. Then, the CPU 108 of the master wireless adapter 10 determines whether or not the electronic flash device 20A (20B or 20C) and the camera 30 need to synchronize the processing start based on the command 4f included in the generated communication packet. To do. As a specific example, a case where the command 4f is data representing a monitor light emission command will be described.

  As described above, the monitor light emission timing is synchronized with the photometry timing by the camera 30. Therefore, when the command 4f represents the monitor light emission command, it corresponds to the case of the above synchronization, and therefore the CPU 108 determines that it is necessary to synchronize the process start.

  The CPU 108 that determines that the process start synchronization is necessary starts the necessary process based on the command 4f after a predetermined time after detecting the interruption of the synchronization signal from the detector 109. For example, if the command 4f is data representing a monitor light emission command, the CPU 108 attaches to the remote wireless adapter 10A (10B or 10C) after the first predetermined time has elapsed after detecting the synchronization signal interrupt. A communication packet instructing the start of monitor light emission by the electronic flash device 20A (20B or 20C) is sent (monitor light emission command in wireless communication).

  The communication packet is output from the detector 109 of the master wireless adapter 10 to the modulation transmission circuit 103. The modulation transmission circuit 103 modulates the communication packet into a signal that can be wirelessly transmitted at a predetermined frequency, and then the antenna in the form of a carrier wave. 101 to the remote wireless adapter 10A (10B or 10C). This predetermined frequency is determined by the oscillator 106.

  On the other hand, the CPU 306 of the camera 30 acquires photometric data from the photometric sensor 304 after a second predetermined time has elapsed after detecting the interruption of the synchronization signal. As a result, the processing timing between the electronic flash device 20A (20B or 20C) and the camera 30 can be synchronized with high accuracy.

  If it is determined that the electronic flash device 20A (20B or 20C) and the camera 30 do not need to synchronize processing start (the command 4f is neither a monitor light emission command nor a main light emission command), the master wireless adapter 10 The CPU 108 sends a communication packet instructing the start of processing according to the command to the remote wireless adapter 10A (10B or 10C) even before a predetermined time has elapsed.

-Main flash-
The communication packet (main light emission activation packet) is transmitted to the electronic flash devices 20A to 20C at once. The CPU 108 of the master communication adapter 10 issues a main light emission instruction to the remote wireless adapters 10A to 10C based on a signal (so-called X signal) from the camera 30. At this time, a communication packet is generated in order to synchronize the timing of the main light emission. The configuration and function of the communication packet are the same as in the case of the monitor light emission described above.

  As described above, the main light emission timing is synchronized with the timing at which the camera 30 opens the shutter 302. Therefore, when the command 4f represents the main light emission command, it corresponds to the case of the above synchronization, and therefore the CPU 108 determines that it is necessary to synchronize the process start.

  The CPU 108 that determines that the process start synchronization is necessary starts the necessary process based on the command 4f after a predetermined time after detecting the interruption of the synchronization signal from the detector 109. For example, when the command 4f is data representing a main light emission command, the CPU 108 detects the electronic signal attached to the remote wireless adapters 10A to 10C after the third predetermined time has elapsed after detecting the interruption of the synchronization signal. A communication packet for instructing the start of main light emission by the flash devices 20A to 20C is transmitted (main light emission command in wireless communication).

  On the other hand, the CPU 306 of the camera 30 instructs the shutter driving device 305 to open the shutter 302 after the fourth predetermined time has elapsed after detecting the interruption of the synchronization signal. Thereby, the synchronization of the processing timing between the electronic flash devices 20A to 20C and the camera 30 can be achieved with high accuracy. Note that the shutter 302 provided in the camera 30 may be an electronic shutter of the image sensor 303 instead of a mechanical shutter.

<Remote wireless adapter and electronic flash device processing>
-Monitor flash-
The remote wireless adapter 10A (10B or 10C) receives this communication packet in the form of a carrier wave via the antenna 101. The received carrier wave is first input to the frequency down converter 102. The frequency down converter 102 down-converts the received packet into predetermined low-frequency data, and then outputs the data to the demodulation circuit 104. This predetermined frequency is determined by the oscillator 106. The demodulation circuit 104 demodulates the input signal into a digital communication packet and outputs it to the detector 105.

  The detector 105 of the remote wireless adapter 10A (10B or 10C) reads and analyzes the input packet from the beginning, as with the detector 109 in the master wireless adapter 10 described above, and the reading of the SFD 4b as synchronization data is completed. When this is detected, the synchronization signal is output as an interrupt signal to the synchronization timing pin of the CPU. At this time, the detector 105 outputs a synchronization signal only when the read SFD 4b matches a preset data string. Thus, malfunction can be prevented when there is interference with other communications.

  The detector 105 of the remote wireless adapter 10A (10B or 10C) outputs the read communication packet to the buffer memory 107 and records it. Based on the command 4f included in the packet stored in the buffer memory 107, the CPU 108 of the remote wireless adapter 10A (10B or 10C) sends a signal instructing the electronic flash device 20A (20B or 20C) to start monitor light emission. Output (monitor emission command in wired communication 2).

  As described above, at the time of monitor light emission, the master wireless adapter 10 synchronizes the timing at which a communication packet is transmitted to the remote wireless adapter 10A (10B or 10C) and the timing at which the camera 30 acquires photometric data, and The remote wireless adapter 10A (10B or 10C) that has received the communication packet from the wireless adapter 10 outputs a signal instructing the electronic flash device 20A (20B or 20C) to start monitor light emission based on the received communication packet. By designating the individual ID, only the target electronic flash device among the electronic flash devices 20A to 20C emits monitor light, so that the timing at which the camera 30 performs photometry and the monitor light emission timing of the electronic flash device are synchronized. Can be taken.

-Main flash-
The remote wireless adapters 10A to 10C receive the communication packet transmitted from the master wireless adapter 10. When the detector 105 of the remote wireless adapter 10A (10B or 10C) reads and analyzes the input packet from the head and detects that the reading of the SFD 4b as the synchronization data is completed, as in the monitor light emission. The synchronization signal is output to the synchronization timing pin of the CPU 108 as an interrupt signal. Similarly to the case of monitor light emission, the synchronization signal is output only when the read SFD 4b matches a preset data string.

  The detectors 105 of the remote wireless adapters 10A to 10C output the read communication packet to the buffer memory 107 and record it. The CPUs 108 of the remote wireless adapters 10A to 10C each output a signal instructing the electronic flash devices 20A to 20C to start the main light emission based on the command 4f included in the packet stored in the buffer memory 107 (wired communication 2 Direct X-on output at).

  As described above, at the time of the main light emission, the master wireless adapter 10 synchronizes the timing at which the communication packets are collectively transmitted to the remote wireless adapters 10A to 10C and the timing at which the camera 30 opens the shutter 302, and the master wireless adapter 10 The remote wireless adapters 10A to 10C that have received the communication packet from each output a signal instructing the electronic flash devices 20A to 20C to start main light emission based on the received communication packet. By specifying all device IDs, the electronic flash devices 20A to 20C start the main flash at the same time, so that the timing at which the camera 30 opens the shutter 302 and the main flash timing of the electronic flash devices 20A to 20C are synchronized. Can be taken.

According to the embodiment described above, the following operational effects can be obtained.
(1) A camera 30 having a communication function, a master wireless adapter 10 that performs first communication with the camera 30, and a remote wireless adapter that performs second communication with the master wireless adapter 10 in the photographing system. 10B and the electronic flash device 20A that performs the third communication between the remote wireless adapter 10B, and the first, second, and third communications are performed asynchronously with each other. It can be performed. If asynchronous communication is used, even if communication is not completed (transmission / reception is normally completed), it is possible to proceed to another process (for example, communication with another device) without waiting for the completion of the communication.

(2) The camera 30 performs first communication with the master wireless adapter 10 every 100 msec, and the master wireless adapter 10 performs first communication with the camera 30 in response to a request from the camera 30, and the first Independently of the first communication, the second communication is performed with the remote wireless adapter 10A every 30 msec. The remote wireless adapter 10A performs the second communication with the master wireless adapter 10 in response to a request from the master wireless adapter 10. And the third communication is performed with the electronic flash device 20A every 100 msec independently of the first communication and the second communication. The electronic flash device 20A responds to the request from the remote wireless adapter 10A. Since the third communication is performed with the wireless adapter 10A, the first, second, and third communications are asynchronous with each other.

(3) The above radiographing system further includes a remote wireless adapter 10B that performs fourth communication with the master wireless adapter 10 and an electronic flash device 20B that performs fifth communication with the remote wireless adapter 10B. Provided, the first, second, and third communications are performed asynchronously with each other, and the first, fourth, and fifth communications are performed asynchronously with each other, so that wireless communication can be performed appropriately. .

(4) In the photographing system of (3) above, the camera 30 performs first communication with the master wireless adapter 10 every 100 msec, and the master wireless adapter 10 communicates with the camera 30 in response to a request from the camera 30. 1, the second communication with the remote wireless adapter 10A and the fourth communication with the remote wireless adapter 10B are alternately performed every 30 msec independently of the first communication. 10A performs the second communication with the master wireless adapter 10 in response to a request from the master wireless adapter 10, and the electronic flash device 20A and the second communication every 100 msec independently of the first communication and the second communication. The remote wireless adapter 10B communicates with the master wireless adapter 10 in response to a request from the master wireless adapter 10. And the fifth communication with the electronic flash device 20B every 100 msec independently of the first communication and the fourth communication, and the electronic flash device 20A responds to the request from the remote wireless adapter 10A. Since the third communication is performed with the remote wireless adapter 10A and the electronic flash device 20B performs the fifth communication with the remote wireless adapter 10B in response to a request from the remote wireless adapter 10B, the first, The second, third, fourth, and fifth communications are asynchronous with each other.

(5) In the photographing system of (4), the first predetermined time, the third predetermined time, and the fifth predetermined time are substantially equal, the second predetermined time and the fourth predetermined time are substantially equal, and the second predetermined time Since both the time and the fourth predetermined time are shorter than the first predetermined time, normally, the second communication and the fourth communication are performed between the first communication, the third communication, and the fifth communication. Yes.
(6) In the above communications, if there is no data transmission even after waiting for a predetermined time from the other party who requested the data, the data is requested again at the next communication to the same party. Also good.

(7) If there is no reply after waiting for a predetermined time from the other party that sent the data, the above-mentioned communications will send the data again at the next communication with the same party, so there is no need to keep waiting for the reply indefinitely.

(8) In the imaging system of (6) or (7), the re-data request or re-data transmission is limited to a predetermined number of times, so that it is not necessary to continue a useless request or useless transmission. .

(Modification 1)
In the above description, the number of retries is limited to three, but the limit may be one or five. Alternatively, it may be 0 times (retry is not permitted).

(Modification 2)
If no reply is received after a predetermined number of retries, a warning display may be displayed on the camera 30 or a warning sound may be generated. In this case, when the CPU 306 of the camera 30 receives data including a communication failure from the remote wireless adapter 10A (10B or 10C), the CPU 306 causes the display (not shown) to indicate that communication is not possible, A warning sound is generated from the speaker.

(Modification 3)
In the above description, the case where the user presses the release switch 307 of the camera 30 has been described. However, a photographing instruction may be transmitted from another external device to the camera 30 wirelessly. FIG. 6 is a diagram illustrating the configuration of the third modification. Compared to FIG. 1, a personal computer 40 to which a wireless communication module 45 is attached is added.

  The CPU 108 of the master communication adapter 10 issues monitor light emission and main light emission instructions to the remote wireless adapter 10A (10B, 10C) based on a signal (shooting instruction) from the personal computer 40 via the wireless communication module 45. At this time, the communication packet described above is generated in order to synchronize the timing of the main light emission and the timing of the monitor light emission. The configuration and function of the communication packet are the same as those in the above-described embodiment. According to the modification 3, wireless communication can be appropriately performed in the case of remote photographing using wireless.

  Although an example in which an electronic flash device is used as the illumination light source for photographing has been described, an LED light source may be used.

  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-10C ... Remote wireless adapter 20A-20C ... Electronic flash device 30 ... Camera 101 ... Antenna 102 ... Frequency down converter 103 ... Modulation transmission circuit 104 ... Demodulation circuit 105, 109 ... Detector 107, 110 ... Buffer Memory 108, 306 ... CPU
302 ... Shutter 303 ... Image sensor 304 ... Photometric sensor 305 ... Shutter driving device 307 ... Operation member

Claims (14)

Have a communication function, a camera for outputting a command to the first illumination device for photography,
A first communication adapter for performing first communication with the camera;
A second communication adapter for performing second communication with the first communication adapter;
A first photographing illumination device that performs third communication with the second communication adapter;
With
The first, second, and third communications are performed asynchronously with each other when the command output from the camera is not a command for instructing a light emission operation to the first photographing illumination device. Shooting system to do. The imaging system according to claim 1,
The camera performs the first communication with the first communication adapter every first predetermined time,
The first communication adapter performs the first communication with the camera in response to a request from the camera, and the second communication adapter and the second communication adapter every second predetermined time independently of the first communication. Perform the second communication,
The second communication adapter performs the second communication with the first communication adapter in response to a request from the first communication adapter, and is independent of the first communication and the second communication. The third communication is performed with the first photographing illumination device every third predetermined time,
The first photographing illumination device performs the third communication with the second communication adapter in response to a request from the second communication adapter. The imaging system according to claim 1 or 2,
A third communication adapter for performing fourth communication with the first communication adapter;
A second photographing illumination device for performing fifth communication with the third communication adapter;
Further comprising
The first, second, and third communications are performed asynchronously with each other, and the first, fourth, and fifth communications are performed asynchronously with each other. In the imaging system according to claim 3,
The camera performs the first communication with the first communication adapter every first predetermined time,
The first communication adapter performs the first communication with the camera in response to a request from the camera, and the second communication with the second communication adapter and the fourth communication with the third communication adapter. Are alternately performed every fourth predetermined time independently of the first communication,
The second communication adapter performs the second communication with the first communication adapter in response to a request from the first communication adapter, and is independent of the first communication and the second communication. Performing the third communication with the first photographing illumination device every third predetermined time;
The third communication adapter performs the fourth communication with the first communication adapter in response to a request from the first communication adapter, and is independent of the first communication and the fourth communication. The fifth communication is performed with the second photographing illumination device every fifth predetermined time,
The first photographing illumination device performs the third communication with the second communication adapter in response to a request from the second communication adapter,
The second photographing illumination device performs the fifth communication with the third communication adapter in response to a request from the third communication adapter. In the imaging system according to claim 4,
The first predetermined time, the third predetermined time, and the fifth predetermined time are substantially equal,
The second predetermined time and the fourth predetermined time are substantially equal to each other, and both the second predetermined time and the fourth predetermined time are shorter than the first predetermined time. In the imaging system according to any one of claims 1 to 5,
In each of the communications, if there is no data transmission after waiting for a predetermined time from the other party who requested the data, the imaging system is characterized by requesting the data again at the next communication with the same party. In the imaging system according to any one of claims 1 to 6,
In each of the communications, if there is no reply from the other party that sent the data for a predetermined time, the data is sent again at the next communication with the same party. In the imaging system according to claim 6 or 7,
The imaging system according to claim 1, wherein the second data request or the second data transmission is limited to a predetermined number of times. In the imaging system according to any one of claims 1 to 8,
The first communication adapter is attached to the camera;
The second communication adapter is attached to the first photographing illumination device,
The second communication between the first communication adapter and the second communication adapter is wireless communication;
The first communication between the camera and the first communication adapter and the third communication between the first photographing illumination device and the second communication adapter are respectively wired communication. Shooting system. The imaging system according to claim 3 or 4,
The first communication adapter is attached to the camera;
The second communication adapter is attached to the first photographing illumination device,
The third communication adapter is attached to the second photographing illumination device;
The second communication between the first communication adapter and the second communication adapter, and the fourth communication between the first communication adapter and the third communication adapter are respectively wireless communication.
The first communication between the camera and the first communication adapter, the third communication between the first photographing illumination device and the second communication adapter, and the second photographing illumination device The imaging system according to claim 5, wherein the fifth communication with the third communication adapter is wired communication. In the imaging system according to any one of claims 1 to 10,
The first, second, and third communications are performed in synchronization with each other when the command output from the camera is a command for instructing a light emission operation to the first photographing illumination device. Shooting system to do. A communication adapter for the camera that performs a first communication with a camera that outputs a command to the photographing illumination device and a second communication with a communication adapter that communicates with the photographing illumination device. Because
The communication adapter for the camera is
A communication adapter that performs the first communication and the second communication asynchronously with each other when the command output from the camera is not a command for instructing a light emission operation to the photographing illumination device. . The first camera performs communication with a communication adapter that performs communication with a camera that outputs a command to the photographing illumination device, and performs second communication with the photographing illumination device. A communication adapter for a lighting device,
The communication adapter for the photographing illumination device is:
A communication adapter that performs the first communication and the second communication asynchronously with each other when the command output from the camera is not a command for instructing a light emission operation to the photographing illumination device. . The communication adapter according to claim 12 or 13,
The communication adapter, wherein the first and second communications are performed in synchronization with each other when the command output from the camera is a command for instructing a light emission operation to the photographing illumination device.

Images