JP5623235B2 - Imaging device system, imaging device, and flash device - Google Patents

Description

The present invention relates to an imaging equipment system, shooting ZoSo location relates to 及 beauty flash equipment.

  In general, in an imaging device such as a camera, a flash device such as a strobe device is used according to ambient brightness. Here, a system having an imaging device and a flash device connected to the imaging device is referred to as an imaging device system. In such an imaging apparatus system, when the flash device is connected to the imaging apparatus, the flash device is connected to the imaging apparatus via an interface (hereinafter referred to as a communication interface).

  The communication interface includes a terminal (X terminal) for transmitting a light emission start signal from the imaging device to the flash device, and a clock terminal and a data terminal for performing digital communication. In addition, some communication interfaces transmit information at an analog voltage level (hereinafter referred to as the old communication interface). In addition, some communication interfaces include a mixture of information transmission by digital communication and information transmission by analog voltage level (hereinafter referred to as a mixed communication interface).

  In general, the flash device is activated by an activation signal sent from the imaging device and starts communication by a communication start signal sent from the imaging device.

  On the other hand, there is one in which an imaging device is started from a flash device (for example, see Patent Document 1). Furthermore, the strobe switch or distance setting switch is turned on / off, and the voltage input to the imaging device is changed in accordance with the charging completion signal, so that the strobe device is turned on / off in the imaging device, whether charging is completed, etc. Some have been recognized (see, for example, Patent Document 2). Here, a plurality of pieces of information are transmitted by switching the resistance connected to the X terminal.

Japanese Patent Laid-Open No. 1-287743 JP-A-6-186619

  By the way, in the above-described imaging device system, since the imaging device is activated from the flash device, the current backflow prevention circuit for preventing energization cut and current backflow when the imaging device is in the sleep state and always energization for activation. The circuit is connected to the clock terminal of the communication interface.

  On the other hand, as described above, in the old communication interface and the mixed communication interface, even when the flash device and the imaging device are not communicating, it is necessary to operate an analog circuit for voltage detection or the like, which consumes power. Is done.

  In the mixed communication interface, the power of the mixed communication interface is cut off in order to minimize power consumption when the imaging apparatus is in the sleep state. For this reason, when the imaging device is in the sleep state, if an activation signal is sent from the flash device to the imaging device, a current flows into the interface circuit on the imaging device side, and the interface circuit on the imaging device side is destroyed. There is a risk.

An object of the present invention is to make a communication start request from a flash device to an imaging device when the imaging device and the flash device are connected using a mixed communication interface, and to flash even when the imaging device is in a sleep state. An object of the present invention is to provide an imaging device system, an imaging device, and a flash device that can transmit a signal from the device to the imaging device.

In order to achieve the above object, an imaging apparatus system according to the present invention is a connection unit including at least one connection terminal in an imaging apparatus system including a flash device that emits light and an imaging device connected to the flash device. wherein the imaging device is switchable between low power consumption sleep mode than the standby mode and the standby mode capable of photographing operation, the flash device, a first communication interface unit, before SL connected First terminal level control means for setting a terminal potential to a ground level, the imaging device includes a second communication interface unit , and the flash device and the imaging device include the first communication. Data communication is performed with each other via the interface unit and the second communication interface unit, and the flash device includes the first terminal level control means. Therefore, when the imaging device is changed from the sleep mode to the standby mode, the potential of the connection terminal is set to the ground level, and when the imaging device is in the standby mode, the data communication with the imaging device is performed. The potential of the connection terminal is set to a ground level, and when the imaging apparatus is in the sleep mode, the potential of the connection terminal is set to the ground level by detecting whether the potential of the connection terminal has reached the ground level. Then, the switching means for switching from the sleep mode to the standby mode, and when in the standby mode, whether the potential of the connection terminal has become the ground level, the potential of the connection terminal is When the ground level is reached, the first communication interface unit and the second communication interface unit are To characterized in that it comprises a communication control means for communicating with the flash device.

According to the present invention, when the imaging device and the flash device are connected using the mixed communication interface, the flash device can make a communication start request to the imaging device, and even if the imaging device is in the sleep state, the flash device A signal can be transmitted from the apparatus to the imaging apparatus.

It is a figure which shows an example of a structure of the imaging device system by the 1st Embodiment of this invention. 3 is a flowchart for explaining the operation of the camera microcomputer shown in FIG. 1. 3 is a flowchart for explaining an operation when a release switch of the camera microcomputer shown in FIG. 1 is turned on. It is a flowchart for demonstrating operation | movement of the flash device microcomputer shown in FIG. It is a flowchart for demonstrating the light emission operation | movement of the flash device microcomputer shown in FIG. It is a flowchart for demonstrating operation | movement of the imaging device system by the 2nd Embodiment of this invention. FIG. 10 is a flowchart for explaining an operation when there is a communication interrupt request from the flash device when the camera is in an operating state in the second embodiment of the present invention. It is a flowchart for demonstrating operation | movement of the flash device by the 2nd Embodiment of this invention.

  Hereinafter, an example of an imaging apparatus system according to an embodiment of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a diagram illustrating an example of a configuration of an imaging apparatus system according to the first embodiment of the present invention.

  Referring to FIG. 1, the illustrated imaging apparatus system includes an imaging apparatus (hereinafter referred to as a camera) 100a and a flash device (also referred to as a strobe apparatus) 200a connected to the camera 100a. The illustrated camera 100a includes a standby mode (standby state) in which a shooting operation is possible and a sleep mode (sleep state) that consumes less power than the standby mode. Similarly, the flash device 200a also has a standby mode and a sleep mode.

  The camera 100 a includes a microcomputer (hereinafter referred to as camera microcomputer) 100 and a first communication interface unit (I / F) 101. The camera microcomputer 100 performs various controls relating to the camera 100a, and performs communication control between the camera 100a and the flash device 200a, light emission control of the flash device 100a, and the like.

  On the other hand, the flash device 200a includes a microcomputer (hereinafter referred to as a flash device microcomputer) 200 and a second communication interface unit (I / F) 201. The flash device microcomputer 200 performs various controls related to the flash device 200a, and performs communication control with the flash device 200a camera and light emission control of the flash device 200. The first and second communication interface units 101 and 201 are connected to each other via a contact group (also referred to as a connection unit) 110.

  The camera microcomputer 100 includes a clock (SCLK) terminal, a data transmission terminal and a data reception terminal (MOSI terminal and MISO terminal), a camera side control terminal (EFST terminal), and an interrupt signal reception terminal (IRQ_WAKE terminal: first interrupt terminal). Have. The MOSI terminal is a terminal for transmitting data from the camera 100a to the flash device 200a, and the MISO terminal is a terminal for receiving the data when data is transmitted from the flash device 200a to the camera 100a. That is, the camera 100a and the flash device 200a perform data communication with each other.

  As illustrated, the SCLK terminal, the MOSI terminal, and the MISO terminal are connected to the first communication interface unit 101. A power source 102 is connected to the first communication interface unit 101, and power is supplied from the power source 102 to the first communication interface unit 101. The first communication interface unit 101 performs level conversion of the signal (data) received via the connection unit 110 and supplies the level conversion to the SCLK terminal, the MOSI terminal, and the MISO terminal.

  The connection unit 110 includes an X contact (connection terminal) 110a, a ground (GND) contact 110b, an SCLK contact 110c, a MOSI contact 110d, and a MISO contact 110e. Note that the illustrated X contact 110 a is a terminal for transmitting a light emission start signal from the camera microcomputer 100 to the flash device microcomputer 200. The first communication interface unit 101 is connected to the SCLK contact 110c, the MOSI contact 110d, and the MISO contact 110e.

  The EFST terminal of the camera microcomputer 100 is connected to the gate terminal of a MOS type depletion type N-channel field effect transistor (FET: first switching means) 103 which is a switching element. The source terminal of the FET 103 is grounded, and its drain terminal is connected to the X contact 110 a of the connection unit 110. A power supply 106 is connected to the IRQ_WAKE terminal via a resistor 105, and the IRQ_WAKE terminal is connected to the drain terminal and the X contact of the FET 103 via a diode 104 (first diode).

  Specifically, the cathode of the diode 104 is connected to the drain terminal and the X contact of the FET 103, and the anode of the diode 104 is connected to the resistor 106 and the IRQ_WAKE terminal of the camera microcomputer 100.

  The flash device microcomputer 200 includes a flash device side control terminal (WAKE) and an interrupt terminal (IRQ_X: second interrupt terminal). The second communication interface unit 201 is connected to the SCLK contact 110c, the MOSI contact 110d, and the MISO contact 110e. A power source 202 is connected to the second communication interface unit 201, and power is supplied from the power source 202 to the second communication interface unit 201. The second communication interface unit 201 converts the level of the signal (data) received via the SCLK contact 110c, the MOSI contact 110d, and the MISO contact 110e, and supplies the signal to the flash device microcomputer 200.

  In the flash device microcomputer 200, the WAKE terminal is connected to the gate terminal of a MOS type depletion type N-channel field effect transistor (FET: second switching means) 203 as a switching element. The source terminal of the FET 203 is grounded at the connection part 110, and the drain terminal thereof is connected to the X terminal 110a. A power supply 206 is connected to the IRQ_X terminal via the resistor 205, and the IRQ_X terminal is connected to the drain terminal of the FET 203 via the diode 204 (second diode).

  Specifically, the anode of the diode 204 is connected to the resistor 205 and the IRQ_X terminal, and the cathode of the diode 204 is connected to the drain terminal of the FET 203 and the X terminal 110 a of the connection unit 110.

  Here, paying attention to the camera 100 a, the FET 103 is on / off controlled by the camera microcomputer 100. Now, when the FET 103 is turned on, the X terminal 110a becomes the GND level (ground level), and a light emission start signal is transmitted from the camera microcomputer 100 to the flash device microcomputer 200 (light emission start is instructed). That is, the flash device microcomputer 200 monitors the potential of the X terminal 110a via the IRQ_X terminal. When the X terminal 110a becomes the GND level, the flash device microcomputer 200 detects the GND level and knows that the light emission is started.

  As described above, the anode of the diode 104 is connected to the IRQ_WAKE terminal of the camera microcomputer 100, so that even if a flash device to which a high voltage is applied is connected via the X terminal 110a, the camera microcomputer microcomputer 100 is connected. It works to protect. The diode 104 is a diode to which a high voltage can be applied.

  The resistor 105 is a resistor for pulling up the IRQ_WAKE terminal of the camera microcomputer 100, and the power source 106 is applied even when the camera 100 is in the sleep state.

  Subsequently, paying attention to the flash device 200a, the FET 203 is ON / OFF controlled by the flash device microcomputer 203, and when the FET 203 is turned ON, the X terminal 110a becomes the GND level. Note that a high voltage can be applied to the FET 203, whereby the WAKE terminal of the flash device microcomputer 200 is protected when a flash device to which a high voltage is applied is connected via the X terminal 110a.

  As described above, the anode of the diode 204 is connected to the resistor 205, and the resistor 205 is a resistor for pulling up the IRQ_X terminal of the flash device microcomputer 200. The power source 206 is applied even when the flash device 200a is in the sleep state.

  Next, the operation of the camera 100a shown in FIG. 1 will be described using the flowchart shown in FIG.

  When a power switch (not shown) is operated or a sleep release signal (not shown) for releasing the sleep mode is received, the camera microcomputer 100 starts operation. When the camera microcomputer 100 operates, power is supplied from the power source 106 through the resistor 105 (step S101). Subsequently, power is supplied from the power supply 102 to the first communication interface unit 101 (step S102). In the sleep state, since the power supply 106 is energized, step S101 is omitted when the sleep mode is canceled.

  Subsequently, the camera microcomputer 100 prohibits interruption with respect to the IRQ_WAKE terminal (step S103). Then, the camera microcomputer 100 starts measuring time with a built-in timer (called a sleep timer: not shown) (step S104). The camera microcomputer 100 monitors whether an operation unit (not shown) of the camera 100a has been operated (step S105).

  If there is no operation from the operation unit (NO in step S106), the camera microcomputer 100 determines whether or not the time (count value) of the sleep timer is equal to or longer than a predetermined (preset) time (step). S106). If the measured time is less than the predetermined time (NO in step S106), camera microcomputer 100 returns to step S105 and continues the process.

  On the other hand, if the time measured by the sleep timer is equal to or longer than the predetermined time (YES in step S106), camera microcomputer 100 turns off power supply 102 and stops energization to first communication interface unit 101 (step S107). Then, the camera microcomputer 100 permits an interrupt to the IRQ_WAKE terminal (step S108) and shifts to the sleep mode.

  If there is an operation from the operation unit in step S105 (YES in step S105), the camera microcomputer 100 resets (clears) the sleep timer (step S109). Then, the camera microcomputer 100 proceeds to step S106, and compares the time measured when the sleep timer is reset with a predetermined time.

  Next, an operation when a release switch (not shown) is turned on in the camera 100a shown in FIG. 1 will be described.

  FIG. 3 is a flowchart for explaining the operation when the release switch is turned on in the camera microcomputer 100 shown in FIG.

  When a release switch (not shown) is turned on, the camera microcomputer 100 performs a release interrupt operation (processing). In the release operation interrupt process, the camera microcomputer 100 performs an operation of raising a main mirror (not shown) and a shutter (not shown) (camera operation: step S201).

  Subsequently, in order to cause the flash device 200a to emit light, the camera microcomputer 100 sets the EFST terminal to a high level (H level) and turns on the FET (switching element) 103 for a predetermined time (step S202). Then, the camera microcomputer 100 ends the release interrupt process.

  Next, the operation of the flash device 200a shown in FIG. 2 will be described using the flowchart shown in FIG.

  When a power switch (not shown) is operated, the flash device microcomputer 300 starts its operation. Then, the flash device microcomputer 300 turns on the pull-up power source 206 connected to the IRQ_X terminal and starts energization (step S301). Further, the flash device microcomputer 300 turns on the power source 202 of the second communication interface unit 201 and starts energization (step S302). Subsequently, the flash device microcomputer 200 permits an interrupt to the IRQ_X terminal (step S303).

  Thereafter, the flash device microcomputer 200 charges a charging circuit (not shown) to a predetermined voltage (step S304). Subsequently, the flash device microcomputer 200 determines whether or not the camera 100a is in the sleep state according to the output of the second communication interface unit 202 (step S305).

  That is, if the camera 100a is in the sleep state, the power supply 102 of the first communication interface unit 101 is not turned on. As a result, in the connection unit 110, the SCLK terminal 110c and the MOSI terminal 110d are at the GND level. Thus, the flash device microcomputer 200 can determine whether or not the camera 100a is in the sleep state.

  If it is determined that the camera 100a is not in the sleep state (NO in step S305), the flash device microcomputer 200 determines whether or not the power switch is turned off (step S306). If the power switch is not turned off (NO in step S306), flash device microcomputer 200 returns to step S304 and continues the process.

  On the other hand, when the power switch is turned off (YES in step S306), flash device microcomputer 200 turns off power supply 202 (step S307) and further turns off pull-up power supply 206 connected to the IRQ_X terminal. (Step S308). Subsequently, the flash device microcomputer 200 stops the charging circuit (step S309) and ends the process. At this time, the operation of the flash device microcomputer 200 stops and shifts to the power-off state.

  If it is determined in step S305 that the camera is in the sleep state (YES in step S305), the flash device microcomputer 200 determines whether or not an operation for starting the camera 100a is performed from an operation unit (not shown) on the flash device side. Is determined (step S315). If the operation for activating camera 100a is not performed (NO in step 315), flash device microcomputer 200 proceeds to step S306 and continues the process.

  On the other hand, when an operation for starting camera 100a is performed (YES in step 315), flash device microcomputer 200 prohibits interruption to IRQ_X terminal (step S320), and keeps WAKE terminal at the H level for a predetermined period. (Step S321). As a result, the flash device microcomputer 200 turns on the FET 203 (switching element) 203 for a predetermined period.

  When the FET 203 is turned on, the X terminal 110a at the connection unit 110 changes to the GND level, and the IRQ_WAKE terminal of the camera microcomputer 100 changes from the H level to the L level. As a result, a start interrupt is generated for the camera microcomputer 100 (that is, the camera microcomputer detects the GND level), and the camera microcomputer 100 performs the operation described with reference to FIG.

  Subsequently, the flash device microcomputer 200 permits an interrupt to the IRQ_X terminal (step S322), proceeds to step S306, and continues the process. In the above-described step S321, while the WAKE terminal of the flash device microcomputer 200 is at the H level, the IRQ_X terminal is at the L level, and the interruption is prohibited. Thereby, erroneous light emission in the flash device 200a can be prevented.

  Next, the light emission operation of the flash device 200a shown in FIG. 2 will be described using the flowchart shown in FIG.

  In the flash device microcomputer 200, when the IRQ_X terminal is in the interrupt enabled state, when the X terminal 110a is set to the GND level by the camera microcomputer 100, the IRQ_X terminal in the flash device microcomputer 200 is set to the L level. As a result, the flash device microcomputer 200 starts a light emitting operation.

  When the light emitting operation is started, the flash device microcomputer 200 controls the light emission of a light emitting unit (strobe: not shown) (step S401). Then, the flash device microcomputer 200 ends the light emission operation (return).

  Thus, in the first embodiment, even when the camera 100a is in the sleep state and the power supply 102 of the first communication interface unit 101 is turned off, the flash device 200a activates the camera 100a. Can be done. That is, since the activation factor is transmitted from the flash device 200a to the camera 100a via the X terminal 101a provided separately from the first communication interface unit 101, for example, the camera 100a and the flash using a mixed communication interface. Even when communicating with the apparatus 200a, the camera 100a can be activated from the flash apparatus 200a.

(Second Embodiment)
Next, an example of a camera according to the second embodiment of the present invention will be described. In the second embodiment, the configuration of the camera and the flash device is the same as that of the first embodiment, and a description thereof will be omitted here.

  FIG. 6 is a flowchart for explaining the operation of the camera according to the second embodiment of the present invention.

  In FIG. 6, the same steps as those described in FIG. 2 are denoted by the same reference numerals and description thereof is omitted. Referring to FIGS. 1 and 6, after power is supplied from the power source 102 to the first communication interface unit 101 in step S102 described in FIG. 2, the camera microcomputer 100 flashes the X terminal 110a at the GND level. In order to permit the communication interrupt request of the device 200a, the interrupt to the IRQ_WAKE terminal is permitted (communication request: step S503).

  Thereafter, the camera microcomputer 100 starts a sleep timer in step S104. Thereafter, steps S105 to S107 and step S109 described with reference to FIG. After turning off the power supply 102 in step S107, the camera microcomputer 100 permits an interrupt to the IRQ_WAKE terminal to permit an activation request by setting the X terminal 110a to the GND level when the camera 100a is in the sleep state ( Activation request: Step S508). Then, the camera microcomputer 100 shifts to the sleep mode.

  Next, an operation in the case where a communication interruption request is made by bringing the X terminal 110a to the GND level from the flash device 200a when the camera 100a is in an operating state will be described.

  FIG. 7 is a flowchart for explaining an operation when a communication interrupt request is received from the flash device when the camera is in an operating state in the second embodiment of the present invention.

  Referring to FIGS. 1 and 7, when there is a communication interrupt request from the flash device 200a, the camera microcomputer 100 communicates with the flash device microcomputer 200 via the first and second communication interface units 101 and 201. (Step S601). When the communication is completed, the camera microcomputer 100 ends the interrupt process (return). Here, in the communication, for example, the camera microcomputer 100 communicates information indicating whether or not the interrupt processing for setting the X terminal 110a to the GND level is supported.

  In the second embodiment, the release operation is the same as the operation described with reference to FIG.

  Next, the operation of the flash device according to the second embodiment of the present invention will be described.

  FIG. 8 is a flowchart for explaining the operation of the flash device according to the second embodiment of the present invention.

  In FIG. 8, the same steps as the operations described in FIG. 4 are denoted by the same reference numerals, and description thereof is omitted. As described with reference to FIGS. 1 and 8, in step S <b> 304, the flash device microcomputer 200 charges the charging circuit to a predetermined voltage. Subsequently, the flash device microcomputer 200 determines whether the camera 100a is the camera 100a corresponding to the communication interrupt request and the interrupt for the sleep state cancellation based on the communication with the camera microcomputer 100 described in FIG. (Step S705). Here, the communication interrupt request is made when the flash device microcomputer 200 sets the X terminal 110a to the GND level.

  If the camera 100a is not an interrupt-capable camera (NO in step S705), the flash device microcomputer 200 determines whether or not the power switch is turned off in step S306 as described with reference to FIG. Steps S307 to S309 described in step 4 are performed.

  On the other hand, if camera 100a is an interrupt-capable camera (YES in step S705), flash device microcomputer 200 determines whether the camera is in a sleep state according to the output of second communication interface circuit 202 (step S705). Step S715).

  Here, if the camera 100a is in the sleep state, the interface power supply 102 is not turned on, so the SCLK terminal 110c and the MOSI terminal 110d of the connection unit 110 are at the GND level. Accordingly, the flash device microcomputer 200 can know whether or not the camera 100a is in the sleep state by looking at the output of the second communication interface unit 202.

  When the camera 100a is in the sleep state (YES in step S715), the flash device microcomputer 200 performs an operation of starting the camera 100a from the flash device 200a by an operation of an operation unit or the like (not shown) on the flash device 200a side. It is determined whether or not it has been received (step S716). If the activation operation of the camera 100a has not been performed (NO in step S716), the flash device microcomputer 200 proceeds to step S306 described with reference to FIG.

  On the other hand, when the activation operation of camera 100a is performed (YES in step S716), flash device microcomputer 200 prohibits interruption to IRQ_X terminal (step S720), and then keeps WAKE terminal at the H level for a predetermined period. (Step S721). As a result, the flash device microcomputer 200 turns on the FET (switching element) 203 for a predetermined period.

  When the FET 203 is turned on, the X terminal 110a of the connection unit 110 changes to the GND level, and the IRQ_WAKE terminal of the camera microcomputer 100 changes from the H level to the L level. As a result, if the camera 100a is in the sleep state, an activation interrupt is generated for the camera microcomputer 100. Then, the camera microcomputer 100 starts the operation described with reference to FIG. 2 (that is, performs a transition operation).

  If the camera 100a is in an operating state (standby mode), the camera microcomputer 100 starts communication with the flash device microcomputer 200.

  Subsequently, the flash device microcomputer 200 permits an interrupt to the IRQ_X terminal (step S722), and the process proceeds to step S306. In this way, while the flash device microcomputer 200 sets the WAKE terminal to the H level, the flash device microcomputer 200 is prohibited from interrupting when the IRQ_X terminal is at the L level, thereby preventing erroneous light emission in the flash device. Become.

  If the camera 100a is not in the sleep state (NO in step S715), the flash device microcomputer 200 determines whether a communication start request is required for the camera microcomputer 100 by an external operation or a change in the state of the flash device. (Step S717). If it is determined that a communication start request is not required (NO in step S717), flash device microcomputer 200 shifts the process to step S306.

  On the other hand, when it is determined that a communication start request is necessary (YES in step S717), flash device microcomputer 200 shifts the process to step S720. The light emitting operation of the flash device microcomputer 200 is the same as the issuing operation described with reference to FIG.

  As described above, according to the second embodiment, even when the camera 100a is in the sleep state and the interface power supply on the camera 100a side is turned off, the flash device 200a activates the camera 100a. It becomes possible. That is, since the activation factor can be transmitted from the flash device microcomputer 200 to the camera microcomputer 100 using the X terminal 110a provided separately from the second communication interface unit 201, for example, even if a mixed interface is used. The flash device 200a can not only start the camera 100a, but also can make a communication start request from the flash device 200a to the camera 100a.

  Furthermore, the flash device microcomputer 200 sets the X terminal 110a to the GND level only when the camera 100a responds to a communication interrupt request and a sleep state cancellation interrupt. Thus, not only can the flash device 200a make a communication request to the camera 100a, but also the camera 100a can be released from the sleep state.

  In addition, since the X terminal 110a is not inadvertently set to the GND level for the unsupported camera 100a, when the flash device 200a and the unsupported camera 100a are connected, the unsupported camera 100a and the flash device are not connected. In 200a, problems such as malfunction and short circuit do not occur.

  As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to these embodiment, Various forms of the range which does not deviate from the summary of this invention are also contained in this invention. .

DESCRIPTION OF SYMBOLS 100 Camera microcomputer 101,201 Communication interface part 200 Flash apparatus microcomputer 102,106,202,206 Power supply 103,203 FET (switching element)
104,204 Diode 100 Connection part 105,205 Resistor 110a X terminal

Claims (6)

In an imaging device system having a flash device that emits light and an imaging device connected to the flash device,
Comprising a connection part comprising at least one connection terminal;
The imaging device can switch between a standby mode in which a photographing operation can be performed and a sleep mode with less power consumption than the standby mode ,
The flash device includes a first communication interface unit, a first terminal level control means for the potential before Symbol connecting terminal and the ground level, and
The imaging device includes a second communication interface unit,
The flash device and the imaging device perform data communication with each other via the first communication interface unit and the second communication interface unit,
In the flash device, the potential of the connection terminal is set to a ground level when the imaging device is shifted from the sleep mode to the standby mode by the first terminal level control means, and the imaging device is in the standby mode. In this case, when performing the data communication with the imaging device, the potential of the connection terminal is set to the ground level,
When the imaging device is in the sleep mode, it detects whether or not the potential of the connection terminal has reached the ground level, and when the potential of the connection terminal reaches the ground level, the sleep mode is changed to the standby mode. Switching means for switching between the first communication and the first communication when the potential of the connection terminal reaches the ground level by detecting whether the potential of the connection terminal has reached the ground level in the standby mode. An image pickup apparatus system comprising: a communication control unit configured to communicate with the flash device via an interface unit and the second communication interface unit .   The switching means includes an interrupt terminal and monitors the potential of the connection terminal via the interrupt terminal, prohibits an interrupt by the interrupt terminal in the standby mode, and by the interrupt terminal in the sleep mode. The imaging apparatus system according to claim 1, wherein an interruption is permitted. 2. The imaging according to claim 1 , wherein the communication control unit includes an interrupt terminal, monitors the potential of the connection terminal through the interrupt terminal, and permits an interrupt by the interrupt terminal in the standby mode. Equipment system. The imaging device has second terminal level control means for setting the potential of the connection terminal to a ground level when instructing the flash device to start light emission,
The flash device detects whether or not the potential of the connection terminal has reached the ground level, and when the potential of the connection terminal reaches the ground level, performs light emission control to perform light emission control on the basis of the instruction to start the light emission. imaging system according to any one of claims 1 to 3, characterized in that it has means. An imaging device connectable to a flash device that emits light,
A connection portion comprising at least one connection terminal connected to the flash device;
Switching means for switching between a standby mode capable of shooting operation and a sleep mode with less power consumption than the standby mode;
A communication interface unit;
Communication control means for communicating with the flash device via the communication interface unit ,
It said switching means when said a sleep mode, when the potential of the previous SL connection terminal by detecting whether the potential of the connection terminal becomes the ground level is the ground level, the standby mode from the sleep mode There line switching to,
The communication control means detects whether or not the potential of the connection terminal has reached the ground level in the standby mode, and when the potential of the connection terminal reaches the ground level, the communication control unit passes through the communication interface unit. imaging device comprising a row Ukoto communication with the flash device. A flash device connectable to an imaging device having a standby mode capable of shooting operation and a sleep mode that consumes less power than the standby mode,
A connection unit comprising at least one connection terminal connected to the imaging device;
A communication interface unit;
Terminal level control means for setting the potential of the connection terminal to the ground level,
The terminal level control means is configured to switch the connected imaging device from the sleep mode to the standby mode by setting the potential of the connection terminal to a ground level when the connected imaging device is in the sleep mode , When the connected imaging device is in the standby mode, the flash device is characterized in that the potential of the connection terminal is set to the ground level to cause the connected imaging device to start data communication via the communication interface unit. .

Images