JP2012168321A - Remote control transmitter, remote control receiver, camera and imaging system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance both credibility and simultaneity of a camera system.SOLUTION: A remote control transmitter 10 comprises: communication means 103 for wirelessly transmitting communication packets; packet generation means 108 for generating a communication packet including an instruction for a remote control receiver 20 and first identification information indicating whether the instruction is identical with an instruction by a communication packet previously transmitted; and control means 108 for, in response to a transmission instruction, controlling the communication means 103 to continuously transmitting communication packets including the same instruction predetermined times.

Description

  The present invention relates to a remote control transmitter, a remote control receiver, a camera, and an imaging system.

  A technique for performing packet communication between electronic devices such as cameras is known (see Patent Document 1). In general, the receiving device transmits a reply packet (ACK packet) to notify the transmitting device that it has been normally received.

JP 2008-102337 A

  When the above communication technology is applied to a remote control transmitter that transmits instructions to a plurality of cameras, there is a problem that the simultaneity of instructions is impaired, although reliability is improved by waiting for a reply packet from each camera. . In other words, after sending an instruction to a certain camera, it waits for a reply packet from that camera and sends an instruction to the next camera. The operation timing differs from the camera receiving the instruction.

(1) The remote control transmitter according to the present invention includes a communication means for wirelessly transmitting a communication packet, an instruction for the remote control receiver, and first identification information indicating whether or not the instruction is the same as the instruction by the communication packet transmitted last time A packet generation unit that generates a communication packet including the control unit, and a control unit that controls the communication unit to continuously transmit a predetermined number of communication packets including the same instruction in response to the transmission instruction. To do.
(2) The remote control receiver according to the present invention determines the communication means for receiving a wirelessly transmitted communication packet and whether or not the instruction included in the received communication packet is the same as the instruction included in the previously received communication packet. And a control unit that prohibits processing according to the instruction when the same instruction is determined by the determination unit, and performs processing according to the instruction included in the received communication packet when the same instruction is not determined. And.
(3) An imaging system according to the present invention includes the remote control transmitter according to claim 4 and the camera according to claim 7 or 8.

  According to the present invention, both reliability and simultaneity can be improved.

It is a figure explaining the structure of the camera system by one embodiment of this invention. It is a block diagram which illustrates the composition of a camera, a wireless adapter, and a remote control transmitter. It is a figure which illustrates a communication packet. It is a figure explaining "Data" in a packet. It is a flowchart which illustrates the process which remote control transmitter CPU performs. It is a figure which illustrates "Data" in which the photography end command was set. It is a flowchart which illustrates the process which CPU of a wireless adapter performs. It is a figure explaining the structure of the camera system of the modification 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 a camera system according to an embodiment of the present invention. The camera system includes cameras 30 </ b> A to 30 </ b> C and a remote control transmitter 10. The cameras 30A to 30C are equipped with wireless adapters 20A to 20C, respectively.

  The remote control transmitter 10 includes operation members 107a, 107b, and 107c. The remote control transmitter 10 wirelessly transmits operation signals such as shooting instructions to the cameras 30A to 30C in response to operations of the operation members 107a, 107b, and 107c. The wireless adapters 20A to 20C receive wireless signals from the remote control transmitter 10, and send operation signals demodulated by the wireless signals to any of the cameras 30A to 30C that are mounted.

  The operation member 107a is a push button corresponding to a release button, and the operation member 107b is a changeover switch for switching the operation target camera. The operation member 107c is a switch between single shooting and continuous shooting, which will be described later, and a bulb shooting setting switch.

  The remote control transmitter 10 when the changeover switch 107b is set to “ALL” performs wireless transmission for all the cameras 30A to 30C as instructions. The remote control transmitter 10 when the changeover switch 107b is set to “A” performs wireless transmission with the camera 30A as an instruction target. The remote control transmitter 10 when the changeover switch 107b is set to “B” performs wireless transmission with the camera 30B as an instruction target. Furthermore, the remote control transmitter 10 when the changeover switch 107b is set to “C” performs wireless transmission with the camera 30C as an instruction target.

  This embodiment is characterized when the remote control transmitter 10 in which the changeover switch 107b is set to “ALL” performs radio transmission, and the following description will focus on the usage mode. The system illustrated in FIG. 1 is a camera system including three cameras 30 and one remote control transmitter 10, but the number of cameras is not limited to three, and may be five or ten. Good.

  FIG. 2 is a block diagram illustrating the configuration of the camera 30, the wireless adapter 20, and the remote control transmitter 10. In FIG. 2, the camera 30 is configured similarly to the cameras 30A to 30C. The wireless adapter 20 is configured in the same manner as the wireless adapter 20A to the wireless adapter 20C. Blocks that are commonly included in both the wireless adapter 20 and the remote control transmitter 10 will be described with the same reference numerals.

  The remote control transmitter 10 includes an antenna 101, a modulation transmission circuit 103, an oscillator 106, an operation member 107, and a CPU 108. When receiving an operation signal from the operation member 107 a, the CPU 108 of the remote control transmitter 10 generates a transmission data block called a packet and outputs it to the modulation transmission circuit 103. The modulation transmission circuit 103 modulates the packet into a signal that can be wirelessly transmitted at a predetermined frequency, and then transmits the packet to the wireless adapter 20 via the antenna 101 in the form of a carrier wave. The predetermined frequency is determined by the oscillator 106.

  The wireless adapter 20 includes an antenna 101, a frequency down converter 102, a modulation transmission circuit 103, a demodulation circuit 104, an oscillator 106, and a CPU 108. The CPU 108 of the wireless adapter 20 receives a 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 CPU 108.

  The CPU 108 reads and analyzes the input packet from the beginning, and transmits the analyzed command information to the CPU 306 of the camera 30. At this time, the CPU 108 outputs command information to the camera 30 only when synchronization data (“SYNC” 4b described later) included in the packet matches a preset data string. Accordingly, it is possible to prevent malfunction (for example, transmission of command information to the camera 30 despite reception of communication directed to another device) when there is interference with other communication.

  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 CPU 306 of the camera 30 is configured to perform camera control according to command information from the CPU 108 of the wireless adapter 20 in addition to performing camera control according to an operation signal from the operation member 307.

  The CPU 108 of the remote control transmitter 10 when the above-described changeover switch 107b is set to “ALL” performs so-called broadcast transmission for a plurality of cameras 30A to 30C as instruction targets. Since broadcast transmission is one-to-many transmission, the receiving device does not transmit a reply packet (ACK packet). Hereinafter, control performed by the CPU 108 of the remote control transmitter 10 will be described.

−Packet generation−
When the push operation signal is input from the push button 107a, the CPU 108 of the remote control transmitter 10 generates a communication packet as follows. FIG. 3 is a diagram illustrating a communication packet, which conforms to the format of digital communication. In FIG. 3, “preamble” 4a is data corresponding to the run-up portion transmitted at the beginning of communication. In the receiving side device (in this example, wireless adapter 20A to wireless adapter 20C), carrier detection, AGC, and phase reference Used for detection. The device on the receiving side detects the “preamble” 4a and enables reception of subsequent signals. In the “preamble” 4a, a fixed bit pattern such as 0, 0, 0, 0... Is set.

  “SYNC” 4b is data for synchronization added to the head part of the packet following “preamble” 4a, and is also called SFD. “SYNC” 4b is a pattern for detecting the start of a packet, and is normally 1 byte (or 2 bytes). Since the standard “SYNC” 4b is determined in advance by the communication method, the reception side only when the signal received and decoded by the reception side device within the predetermined reception period matches the standard “SYNC” 4b. Subsequent reception is enabled in the device.

  “Length” 4c is data indicating the communication data capacity (number of bytes), and means the information amount of the packet. The device on the receiving side detects the “SYNC” 4b, decodes the number of data indicated by the “length” 4c, and ends one reception.

  “Header” 4d is an address, packet type, and address specifying the transmission source (in this example, the remote control transmitter 10) and the transmission destination (in this example, the wireless adapters 20A to 20C attached to the instruction target camera). And data indicating serial numbers and the like. When the changeover switch 107b is set to “ALL”, the CPU 108 includes an ID indicating indefinite in the address designating the transmission destination. Transmission in which the destination address is indefinite corresponds to broadcast transmission.

  When the changeover switch 107b is set to “A”, the CPU 108 includes an ID indicating the wireless adapter 20A (that is, the camera 30A) in the address that specifies the transmission destination. Similarly, when the changeover switch 107b is set to “B”, the CPU 108 includes an ID indicating the wireless adapter 20B (that is, the camera 30B) in an address that designates a transmission destination. Further, when the changeover switch 107b is set to “C”, the CPU 108 includes an ID indicating the wireless adapter 20C (that is, the camera 30C) in an address that designates a transmission destination.

  “Data” 4f includes command information f1 indicating the instruction content to the instruction target camera, information f2 indicating the number of times of shooting activation by the command, information f3 indicating the number of times of transmission of the packet, and other necessary information It is constituted by a data group representing information f4. FIG. 4 is a diagram for explaining the contents of “Data” 4f.

  “Check Data” 4g is check data located at the end of the packet. For example, it is composed of 2-byte data generated by an error detection data generation algorithm using CRC. The receiving device is configured to make an error determination based on “Check Data” 4g and discard the received packet when an error is determined.

-Processing performed by CPU 108 of remote control transmitter 10-
A flow of processing performed by the CPU 108 will be described with reference to a flowchart illustrated in FIG. When a battery (not shown) is loaded in the remote control transmitter 10, the CPU 108 activates the process shown in FIG.

  In step S11 in FIG. 5, the CPU 108 initializes (clears) flags and proceeds to step S12. However, the count value of the shooting number P corresponding to the information f2 included in the “Data” 4f (the shooting start number indicates the number of shooting times and is referred to as the shooting number P in this description) is not initialized. In step S12, the CPU 108 detects shooting start and proceeds to step S13. The CPU 108 detects a pressing operation signal from the push button 107a as a shooting activation signal.

  In step S13, the CPU 108 determines whether or not single shooting is performed. If single shooting is set, the CPU 108 makes a positive determination in step S13 and proceeds to step S14. If single shooting is not set, the CPU 108 makes a negative determination in step S13 and proceeds to step S15. Single shooting means that the camera 30 captures one frame in response to the pressing operation of the push button 107a. The CPU 108 determines single shooting, continuous shooting described later, and bulb shooting setting based on the operation position of the operation member 107c.

  In step S14, the CPU 108 sets a single shooting flag to 1 and proceeds to step S18. In step S15, the CPU 108 sets 1 in the continuous shooting flag and proceeds to step S16. Continuous shooting means that the camera 30 continuously shoots a plurality of frames while the push button 107a is pressed. The CPU 108 instructs the start of continuous shooting in response to the pressing operation of the push button 107a, and instructs the end of continuous shooting in response to the release of the push button 107a. Receiving the instruction to start continuous shooting, the camera 30 repeatedly shoots at a predetermined frame rate until receiving an instruction to end continuous shooting. As described above, the CPU 108 determines single shooting, continuous shooting, and later-described bulb shooting setting based on the operation position of the operation member 107c.

  In step S <b> 16, the CPU 108 determines whether or not bulb shooting is performed. If the bulb photographing setting has been set, the CPU 108 makes a positive determination in step S16 and proceeds to step S17. If the bulb photographing setting is not set, the CPU 108 makes a negative determination in step S16 and proceeds to step S18. Bulb shooting refers to shooting with exposure while the push button 107a is pressed. The CPU 108 instructs the start of exposure according to the pressing operation of the push button 107a, and instructs the end of exposure according to the release of the push button 107a. The camera 30 that has received an instruction to start exposure continuously performs exposure until receiving an instruction to end exposure. As described above, the CPU 108 determines single shooting, continuous shooting, and bulb shooting setting based on the operation position of the operation member 107c.

  In step S17, the CPU 108 sets 1 to the valve flag and proceeds to step S18. In step S18, the CPU 108 sets the number of transmissions n to the initial value 1, and proceeds to step S19. The number of transmissions n corresponds to the information f3 in the “Data” 4f of the transmission packet.

  In step S <b> 19, the CPU 108 generates a transmission packet and sends it to the modulation transmission circuit 103 to transmit the packet. In the transmission packet, a shooting activation command is set in the information f1 in “Data” 4f. The shooting start command is an instruction to start shooting with respect to the instruction target camera. The shooting start command includes parameters for identifying single shooting, continuous shooting, and bulb shooting.

  In step S20, the CPU 108 increments the transmission count n and proceeds to step S21. The number of transmissions n after the increment is set in the information f3 in the “Data” 4f of the packet when returning to step S19.

  In step S21, the CPU 108 determines whether or not the number of transmissions n has reached a predetermined number. If n is a predetermined number of times, the CPU 108 makes an affirmative decision in step S21 and proceeds to step S23. If n is not the predetermined number of times, the CPU 108 makes a negative determination in step S21 and proceeds to step S22.

  In step S22, the CPU 108 waits for a predetermined time (for example, 3 msec) (delay) and returns to step S19. By repeating the processes of steps S19 to S22, a transmission packet including the same shooting activation command is repeatedly transmitted a predetermined number of times (for example, 20 times) at the predetermined time interval.

  In step S23, the CPU 108 determines whether or not single shooting is performed. If the single-shot flag is 1, the CPU 108 makes a positive determination in step S23 and proceeds to step S30. If the single shooting flag is not 1, the CPU 108 makes a negative determination in step S23 and proceeds to step S24. The process proceeds to step S24 when continuous shooting or bulb shooting is set.

  In step S24, the CPU 108 determines whether or not the end of shooting has been detected. The CPU 108 detects the end of shooting when the pressing operation signal from the push button 107a is released. If the CPU 108 detects the end of shooting, the CPU 108 makes a positive determination in step S24 and proceeds to step S25. If the end of shooting is not detected, the CPU 108 makes a negative determination in step S24 and repeats the determination process.

  In step S25, the CPU 108 sets the number of transmissions m to the initial value 1, and proceeds to step S26. The number of transmissions m corresponds to the information f3 in the “Data” 4f of the transmission packet.

  In step S26, the CPU 108 generates a transmission packet, sends it to the modulation transmission circuit 103, and causes the packet to be transmitted. The packet generated in this step is different from the packet generated in step S19 in that a shooting end command is set instead of the shooting start command in the information f1 in “Data” 4f. The shooting end command is an instruction to end shooting with respect to the instruction target camera. “Data” 4f in which the shooting end command is set is illustrated in FIG.

  In step S27, the CPU 108 increments the transmission count m and proceeds to step S28. The number of transmissions m after the increment is set in the information f3 in the “Data” 4f of the packet when returning to step S26.

  In step S28, the CPU 108 determines whether or not the number of transmissions m has reached a predetermined number. CPU108 makes affirmation determination of step S28, and progresses to step S30, when m is predetermined times. If m is not the predetermined number of times, CPU 108 makes a negative determination in step S28 and proceeds to step S29.

  In step S29, the CPU 108 waits for a predetermined time (for example, 3 msec) (delay) and returns to step S26. By repeating the processes of steps S27 to S29, a transmission packet including the same photographing end command is repeatedly transmitted a predetermined number of times (for example, 20 times) at the predetermined time interval.

  In step S30, the CPU 108 increments the shooting number P and returns to step S1. The incremented shooting number P is set in the information f2 in the “Data” 4f of the packet when returning to step S19.

-Processing performed by CPU 108 of wireless adapter 20-
A flow of processing performed by the CPU 108 of the wireless adapter 20 will be described with reference to a flowchart illustrated in FIG. When the power is supplied from the camera 30, the CPU 108 activates the process illustrated in FIG. 7.

  In step S51 of FIG. 7, the CPU 108 initializes (clears) the memory in the CPU 108 and proceeds to step S52. As a result, the data indicating the shooting number P corresponding to the information f2 included in the “Data” 4f of the received packet is cleared.

  In step S52, the CPU 108 determines whether or not a packet has been received. If the CPU 108 has received the packet without error, the CPU 108 makes a positive determination in step S52 and proceeds to step S53. If the CPU 108 has not received the packet or has determined an error for the received packet, the CPU 108 makes a negative determination in step S52 and repeats the determination process.

  In step S53, the CPU 108 determines whether or not it is a shooting end command. If the information f1 in the “Data” 4f is a shooting end command, the CPU 108 makes a positive determination in step S53 and proceeds to step S59. If the information f1 in the “Data” 4f is not a shooting end command, the CPU 108 makes a negative determination in step S53 and proceeds to step S54.

  In step S54, the CPU 108 determines whether it is a shooting activation command. If the information f1 in the “Data” 4f is a shooting start command, the CPU 108 makes a positive determination in step S54 and proceeds to step S55. If the information f1 in the “Data” 4f is not a shooting activation command, the CPU 108 makes a negative determination in step S54 and proceeds to step S61.

  In step S55, the CPU 108 determines whether or not the shooting number P corresponding to the information f2 in the “Data” 4f of the received packet is the same as that of the previous received packet. If the same as the previous time, the CPU 108 makes a positive determination in step S55 and returns to step S52. If not the same as the previous time, the CPU 108 makes a negative determination in step S55 and proceeds to step S56. In the present embodiment, only when the shooting number P is different from the previous time, the process proceeds to step S56 to start shooting.

  In step S56, the CPU 108 activates any one of single shooting, continuous shooting, and bulb shooting according to a parameter for identifying single shooting, continuous shooting, and bulb shooting included in the shooting start command. A signal to be transmitted is transmitted to the CPU 306 of the camera 30, and the process proceeds to step S57. In step S57, the CPU 108 stores the shooting number P in the memory in the CPU 108 and proceeds to step S58.

  In step S <b> 58, the CPU 108 stores the transmission count n corresponding to the information f <b> 3 in the “Data” 4 f of the received packet in the memory in the CPU 108. Further, the CPU 108 transmits the photographing number P and the transmission number n to the CPU 306 of the camera 30 so as to record it as photographing data, and returns to step S52. In addition to the shooting number P, the number of transmissions n is included in the shooting data and recorded, so that the recorded contents are useful as analysis information. When the packet is received without error, shooting is started based on the first transmission packet, so the number of transmissions n is 1. For example, a reception error occurs twice due to radio wave conditions, and the third transmission packet (transmission When shooting is started based on the number of times n = 3), the number of times of transmission n = 3 is recorded. When n = 3 is recorded, it indicates that “shooting activation at shooting number P is delayed” for two packet transmissions.

  In step S59, which proceeds after making an affirmative determination in step S53, the CPU 108 transmits a signal to end shooting to the CPU 306 of the camera 30, and proceeds to step S60. Thereby, the CPU 306 of the camera 30 does not shoot a new frame when continuous shooting is being performed, and stops exposure when bulb shooting is being performed.

  In step S60, the CPU 108 transmits the shooting number P included in the information f2 in the “Data” 4f of the packet and its storage instruction to the CPU 306 of the camera 30 and returns to step S52. By recording the photographing number P, the recorded contents are useful as analysis information. That is, normally, the same shooting number P is recorded when shooting starts (step S57) and when shooting ends (step S60). If a shooting number P that is not recorded at the start of shooting is recorded at the end of shooting, it indicates that “shooting activation of shooting number P has failed”.

  In step S61, which proceeds after making an affirmative determination in step S54, the CPU 108 transmits a signal for starting a predetermined process corresponding to the command to the CPU 306 of the camera 30, and returns to step S52. Thereby, the CPU 306 of the camera 30 performs, for example, a power-on process.

According to the embodiment described above, the following operational effects can be obtained.
(1) The remote control transmitter 10 includes a modulation transmission circuit 103 that wirelessly transmits a communication packet, an instruction f1 to the wireless adapter 20 side, and a first indicating whether the instruction f1 is the same as the instruction by the communication packet transmitted last time Since the camera 108 includes a CPU 108 that generates a communication packet including the identification information f2, and a CPU 108 that controls the modulation transmission circuit 103 so as to continuously transmit a communication packet including the same instruction a predetermined number of times in response to the transmission instruction. Both system reliability and simultaneity can be improved.

  The information f2 included in the “Data” 4f described above is composed of, for example, 1-byte data. In this case, the photographing number P can be counted up to 255 times. If the number of shooting activations exceeds 255, it is reset to 0 and incremented again.

(2) In the remote control transmitter 10 of (1) above, the CPU 108 that generates the communication packet further includes the second identification information f3 indicating the number of consecutive transmissions of the communication packet including the same instruction in the communication packet. Both the reliability and simultaneity of the camera system can be improved.

  Similarly, the information f3 included in the “Data” 4f is composed of 1-byte data. The number of transmissions n and m is reset to 1 when starting to send a new command (steps S18 and S25), and the number of transmissions of the same command is normally about 20, so the number of transmissions n and m exceeds 255. There is nothing.

  In the above-described embodiment, the shooting number P and the transmission count m in the shooting end command are not necessarily required. However, in order to provide packet structural symmetry at the end of shooting and at the start of shooting, information “f2” (shooting number P) and f3 (number of transmissions m) are included in “Data” 4f of the packet including the shooting end command. Configured to include.

(3) In the remote control transmitter 10 of the above (1) or (2), there are a plurality of wireless adapters 20, and the modulation transmission circuit 103 broadcasts communication packets. Therefore, both the reliability and simultaneity of the camera system are provided. Can be increased.

(4) In the remote control transmitter 10 of any one of the above (1) to (3), when the device on the wireless adapter 20 side is the camera 30, and the instruction f1 is a shooting start instruction for the camera 30, a plurality of cameras Can increase the simultaneity of shooting activation.

(5) The wireless adapter 20 includes the frequency down converter 102 and the demodulation circuit 104 that receive wirelessly transmitted communication packets, and whether the instruction included in the received communication packet is the same as the instruction included in the previously received communication packet. A CPU 108 that determines whether or not the same instruction is determined, and a CPU 108 that prohibits a process according to the instruction and performs a process according to the instruction included in the received communication packet when the same instruction is not determined. Therefore, both the reliability and simultaneity of the camera system can be improved.

(6) In the wireless adapter 20 of (5) above, the frequency converter 102 and the demodulation circuit 104 receive the communication packet from any one of the remote control transmitters (1) to (4), and the CPU 108 Since it is determined whether or not the instructions are the same based on the first identification information f2 included in the packet, it can be determined appropriately.

(7) The camera system includes the wireless adapter 20 of (5) or (6) above, and the camera 30, and the CPUs 108 and 306 each include an instruction included in the received communication packet as a shooting activation instruction, and the CPU 108. Since the photographing process by the camera 30 is activated when the same instruction is not determined by the above, both the reliability and the simultaneity of the camera system can be improved.

(8) In the camera system of (7) above, the CPUs 108 and 306 determine whether the instruction included in the received communication packet is an instruction to end the photographing process and the camera 30 determines that the same instruction is not determined by the CPU 108. Since the photographing process is terminated, both the reliability and simultaneity of the camera system can be improved.

(Modification 1)
When the CPU 306 of the camera 30 receives a shooting end command even when it is not shooting (step S59), the CPU 306 stores error information in the CPU 306 according to the shooting number P to be received and its storage instruction (step S60). Was stored in the memory. This error information indicates, for example, that “shooting activation of the shooting number P has failed”, and therefore it is possible to perform post-mortem analysis regarding what number of shooting activation has failed based on the stored contents of the memory.

(Modification 2)
In the above description, an example in which single shooting, continuous shooting, and bulb shooting settings are switched based on the operation position of the operation member 107c on the remote control transmitter 10 side has been described. When the remote control transmitter 10 does not have the operation member 107c (that is, when the remote control transmitter 10 cannot switch between single shooting / continuous shooting / bulb shooting), Steps S13 to S17 and Step S23 in FIG. It is preferable to always transmit the shooting start command (step S19) and the shooting end command (step S26) in a set after skipping.

(Modification 3)
FIG. 8 is a diagram illustrating the configuration of a camera system according to the third modification. The camera system includes a camera group 300 </ b> A that forms group A, a camera group 300 </ b> B that forms group B, a camera group 300 </ b> C that forms group C, and the remote control transmitter 10. The camera group 300A includes a plurality of the cameras 30A described above (with the wireless adapter 20A attached). The camera group 300B includes a plurality of cameras 30B described above (equipped with the wireless adapter 20B). The camera group 300C includes a plurality of the above-described cameras 30C (with the wireless adapter 20C attached).

  The remote control transmitter 10 when the changeover switch 107b is set to “ALL” performs wireless transmission with respect to all the camera groups 300A to 300C as instructions. The remote control transmitter 10 when the changeover switch 107b is set to “A” performs wireless transmission with the camera group 300A as an instruction target. The remote control transmitter 10 when the changeover switch 107b is set to “B” performs wireless transmission with the camera group 300B as an instruction target. Further, the remote control transmitter 10 when the changeover switch 107b is set to “C” performs wireless transmission with the camera group 300C as an instruction target.

  In the system illustrated in FIG. 8, the number of cameras constituting one group and the total number of groups are not limited.

  "Header" 4d in the case of the modification 3 designates the transmission source (in this example, the remote control transmitter 10) and the transmission destination camera group (in this example, the wireless adapter having the same address is attached to the instruction target camera group). It consists of data indicating the address, packet type, serial number, and the like. When the changeover switch 107b is set to “ALL”, the CPU 108 includes an ID indicating indefinite in an address for designating a destination camera group. Transmission in which the address of the destination camera group is indefinite corresponds to broadcast transmission in which all camera groups are designated.

  When the changeover switch 107 b is set to “A”, the CPU 108 includes an ID indicating the wireless adapter attached to the camera group 300 </ b> A in an address designating the transmission destination camera group. Similarly, when the changeover switch 107b is set to “B”, the CPU 108 includes an ID indicating the wireless adapter attached to the camera group 300B in an address that specifies the destination camera group. Further, when the changeover switch 107b is set to “C”, the CPU 108 includes an ID indicating the wireless adapter attached to the camera group 300C in an address that designates the transmission destination camera group.

(Modification 4)
In the above embodiment, an example in which the cameras 30A to 30C and the wireless adapters 20A to 20C are connected to each other has been described. Instead, the configuration of each wireless adapter may be built in each camera and integrated.

  The above-described camera may be a digital camera or a film camera, and may be a still camera or a video camera.

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

DESCRIPTION OF SYMBOLS 10 ... Remote control transmitter 20 ... Wireless adapter 30 ... Camera 102 ... Frequency down converter 103 ... Modulation transmission circuit 104 ... Demodulation circuit 106 ... Oscillator 107 ... Operation member 108,306 ... CPU
303 ... Image sensor

Claims (9)

A communication means for wirelessly transmitting a communication packet;
A packet generation means for generating a communication packet including an instruction to the remote control receiver side and first identification information indicating whether or not the instruction is the same as the instruction by the communication packet transmitted last time;
A control means for controlling the communication means to continuously transmit a predetermined number of communication packets including the same instruction in response to a transmission instruction;
A remote control transmitter comprising: The remote control transmitter according to claim 1,
The remote control transmitter, wherein the packet generation means further includes second identification information indicating the number of consecutive transmissions of the communication packet including the same instruction in the communication packet. The remote control transmitter according to claim 1 or 2,
There are a plurality of the remote control receivers,
The remote control transmitter, wherein the communication means broadcasts the communication packet. In the remote control transmitter according to any one of claims 1 to 3,
The device on the remote control receiver side is a camera,
The remote control transmitter according to claim 1, wherein the instruction is a shooting start instruction for the camera. Means for receiving wirelessly transmitted communication packets;
Determining means for determining whether an instruction included in the received communication packet is the same as an instruction included in the previously received communication packet;
Control means for prohibiting processing according to the instruction when the same instruction is determined by the determining means, and performing processing according to the instruction included in the received communication packet when the same instruction is not determined; ,
A remote control receiver comprising: The remote control receiver according to claim 5, wherein
The communication means receives a communication packet from the remote control transmitter according to any one of claims 1 to 4,
The determination unit determines whether or not the instructions are the same based on the first identification information included in the communication packet. A remote control receiver according to claim 5 or 6,
An imaging means,
The control means activates the photographing process by the imaging means when the instruction included in the received communication packet is a photographing activation instruction and the same instruction is not determined by the determination means. Camera. The camera according to claim 7, wherein
The control unit terminates the photographing process by the imaging unit when the instruction included in the received communication packet is an instruction to end the photographing process and the determination unit does not determine the same instruction. Camera characterized by. A remote control transmitter according to claim 4;
An imaging system comprising the camera according to claim 7 or 8.

Images