JP2010261993A - Remote illumination controller, remote illumination device, and remote illumination device system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote illumination controller enabling a user to recognize circumstances of a remote illumination device. <P>SOLUTION: The remote illumination controller includes: a light emission-instructing part 21M instructing the remote illumination device 20R that irradiates a subject with illuminating light for photography from a place remote from a photographing device 10 to emit the illuminating light for photography; an information acquiring part 25M acquiring physical quantity information that causes variation in the remote illumination device 20R by being influenced by light emission when the illuminating light for photography is emitted according to an instruction from the light emission-instructing part 21M; and display parts 27 and 16 displaying the physical amount information acquired by the information acquiring part 25M. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a remote lighting control device, a remote lighting device, and a remote lighting device system.

When taking a photograph, a lighting device for photographing may be used. When high-speed continuous shooting is performed, the lighting device also emits light continuously. In this case, the booster circuit and the light emitting unit (especially the Fresnel lens) of the illuminating device generate heat, which not only makes the user uncomfortable, but may also lead to deformation and destruction of components.
2. Description of the Related Art Conventionally, in order to prevent overheating of a light emitting part and its peripheral part of a lighting device, there is a technique that reduces the amount of illumination light when the temperature of the light emitting part rises (see Patent Document 1). When the amount of emitted light is reduced in this prior art, the fact that the reduction operation has been performed is displayed on the liquid crystal screen of the illumination device.

JP 2005-156793 A

  However, in order to improve the lighting effect at the time of shooting, there are cases where multi-lamp shooting is performed using several groups or several lighting devices. At this time, since the remote illumination device is arranged at a position away from the photographer, the photographer cannot grasp whether the heat generation state or the reduction operation of the remote illumination device has been performed.

  An object of this invention is to provide the remote lighting control apparatus which can grasp | ascertain the condition of a remote lighting apparatus, a remote lighting apparatus, and a remote lighting apparatus system.

  The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.

According to the first aspect of the present invention, the remote illumination device (20R) that irradiates the photographic illumination light toward the subject from a place away from the photographic device (10) is instructed to emit the photographic illumination light. When the photographing illumination light is emitted according to the instruction from the light emission instruction unit (21M) and the light emission instruction unit (21M), the remote illumination device (20R) varies due to the influence of the light emission. A remote lighting control device comprising: an information acquisition unit (25M) that acquires physical quantity information; and a display unit (27, 16) that displays the physical quantity information acquired by the information acquisition unit (25M). 20M, 10).
The invention described in claim 2 is the remote lighting control device (20M, 10) according to claim 1, wherein the content of the command transmitted from the light emission instruction unit (21M) to the remote lighting device (20R). The remote lighting control device (20M, 10) is characterized by comprising a calculation unit (23M, 13) for estimating and calculating the physical quantity information based on the above.
Invention of Claim 3 is a remote lighting control apparatus (20M, 10) of Claim 2, Comprising: It is used at the time of the said estimation calculation of the said physical-quantity information in the said calculating part (23M, 13), A remote lighting control device (20M, 10) comprising a storage unit (24M, 14) for storing information relating to estimation of physical quantity information for each type of the remote lighting device (20R).
The invention according to claim 4 is the remote lighting control device (20M, 10) according to claim 3, wherein the unique information of the remote lighting device (20R) transmitted from the remote lighting device (20R) is transmitted. A receiving unit (25M) for receiving, and the calculation unit (23M, 13) includes the unique information received by the receiving unit (25M) among the information stored in the storage unit (24M, 14). A remote lighting control device (20M, 10) characterized in that the physical quantity information is estimated based on information corresponding to.
The invention according to claim 5 is the remote lighting control device (20M, 10) according to claim 1, wherein the receiving unit (25M) receives the physical quantity information transmitted from the remote lighting device (20R). The display unit (27, 16) is a remote lighting control device (20M, 10) characterized by displaying the physical quantity information received by the receiving unit (25M).
The invention according to claim 6 is the remote lighting control device (20M, 10) according to any one of claims 1 to 5, wherein the physical quantity information exceeds a preset threshold value, The remote lighting control device (20M, 10) is characterized by displaying a warning on the display unit (27, 16).
A seventh aspect of the present invention is the remote lighting control device (20M, 10) according to any one of the first to sixth aspects, wherein the physical quantity information includes a battery remaining amount of the remote lighting device (20R). It is a remote lighting control device (20M, 10) characterized by including a quantity.
The invention according to claim 8 is the remote lighting control device (20M, 10) according to any one of claims 1 to 7, wherein the physical quantity information includes a temperature of the remote lighting device (20R). It is a remote lighting control apparatus (20M, 10) characterized by including.
The invention according to claim 9 is the remote illumination control device (20M) according to any one of claims 1 to 8, wherein the remote illumination control device (20M) illuminates the subject with illumination light. It is a remote illumination control device (20M) characterized by being a master illumination device (20M) provided with an illumination unit (21M) capable of irradiating the light.
The invention according to claim 10 is the remote illumination control device (10) according to any one of claims 1 to 8, wherein the remote illumination control device (10) illuminates the subject with illumination light. It is a remote illumination control device (10) characterized by being a camera (10) having a built-in illumination unit (21M) capable of irradiating.
The invention according to claim 11 is the remote illumination control device (10) according to any one of claims 1 to 8, wherein the remote illumination control device (10) illuminates the subject with illumination light. The remote illumination control device (10) is a camera (10) in which a master illumination device (20M) including an illumination unit (21M) capable of irradiating a light is removable.
A twelfth aspect of the present invention is the remote illumination control device (10) according to the tenth or eleventh aspect, wherein the photographing lens (11) and a diaphragm member for adjusting the amount of light passing through the photographing lens (11). (11A), and when the temperature of the remote lighting device (20R) exceeds a preset threshold, the diaphragm member (11A) increases the amount of light passing through the photographing lens (11). A remote lighting control device (10) characterized by
The invention according to claim 13 is the remote illumination control device (10) according to any one of claims 10 to 12, wherein the imaging unit and a sensitivity setting unit (12A) for changing the sensitivity of the imaging unit. And when the temperature of the remote lighting device (20R) exceeds a preset threshold, the sensitivity setting unit (12A) increases the sensitivity of the imaging unit. (10).
The invention according to claim 14 is the remote illumination control device (20M, 10) according to any one of claims 1 to 13, wherein the illumination light source is movable in an irradiation optical axis direction. The remote lighting device (20R) includes a transmission unit (21) that transmits a control signal for controlling the movement of the light source, and the temperature of the remote lighting device (20R) exceeds a preset threshold value. In this case, the transmission unit (21) transmits a control signal for moving the position of the light source of the remote illumination device (20R) to the side where the light distribution angle becomes narrower to the remote illumination device (20R). The remote lighting control device (20M, 10) characterized by the above.
The invention according to claim 15 is a remote illumination device (20R) for emitting illumination light for photographing, and is emitted from a remote illumination control device (20M, 10) at a position separated from the remote illumination device (20R). In addition, a receiving unit (25R) that receives a light emission command for causing the photographing illumination light to be emitted, and a transmitting unit (21R) that can transmit its own unique information to the remote lighting control device (20M, 10). A remote lighting device (20R).
The invention according to claim 16 is the remote lighting device (20R) according to claim 15, wherein the transmission of the specific information is performed in accordance with a command from the remote lighting control device (20M, 10). The remote lighting device (20R) is characterized in that the light emission is performed as part of the test light emission.
According to a seventeenth aspect of the present invention, in the remote lighting device (20R) according to the fifteenth or sixteenth aspect, the transmitter (21) emits the photographing illumination light as the specific information in accordance with the emission command. In this case, the remote illuminating device (20R) is characterized by transmitting physical quantity information that causes fluctuations in the remote illuminating device (20R) under the influence of the light emission.
According to the eighteenth aspect of the present invention, a remote illumination device (20R) that irradiates the illuminating light for photographing toward a subject from a place away from the photographing device (10), and a position separated from the remote illumination device (20R) The remote illumination control device (20M, 10) that issues a light emission command for causing the remote illumination device (20R) to emit the illuminating illumination light, and the remote illumination control device (20M, 10) are integrally disposed. When the remote illumination device (20R) emits the illumination light for photographing according to the light emission command, the physical quantity information that causes fluctuations in the remote illumination device (20R) due to the light emission is displayed. A remote lighting device system (1), comprising: a device (27, 16).
Note that the configuration described with reference numerals may be improved as appropriate, or at least a part thereof may be replaced with another component.

  ADVANTAGE OF THE INVENTION According to this invention, the remote lighting control apparatus which can grasp | ascertain the condition of a remote lighting apparatus, a remote lighting apparatus, and a remote lighting apparatus system can be provided.

1 is a block diagram illustrating a configuration of an embodiment of an imaging system 1 according to the present invention. It is a circuit diagram which shows notionally the structure of the drive circuit of an illuminating device. It is a flowchart of the temperature warning display control by the control part of a master illuminating device. It is a figure which shows the temperature warning display in the display part of a master illuminating device. It is a flowchart of the temperature warning display control by the control part of a remote illuminating device. It is a figure which illustrates the signal of identification information transmission from a remote lighting device to a master lighting device. It is a flowchart of the temperature warning control by the control part of a master illuminating device. It is a flowchart of the temperature warning control by the control part of a remote illuminating device.

(First embodiment)
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of an embodiment of an imaging system 1 according to the present invention.
The imaging system 1 includes a camera 10, a master lighting device 20 </ b> M attached to the camera 10, and a remote lighting device 20 </ b> R arranged at a position separated from the camera 10. The imaging system 1 shown in FIG. 1 includes one master lighting device 20M and one remote lighting device 20R, but the present invention is also applicable to a case where two or more remote lighting devices 20R are provided.

  The master lighting device 20M and the remote lighting device 20R are each a flash lighting device using a xenon tube 21A. The camera 10 functions as a command device that commands the master lighting device 20M and the remote lighting device 20R to emit light. When the camera 10 includes a lighting device, the lighting device included in the camera can also be the master lighting device 20M.

The master lighting device 20M emits a flash that illuminates the subject based on a light emission command from the camera 10.
The remote illumination device 20R emits a flash that illuminates the subject based on a light emission command via the master illumination device 20M. The light emission command to the remote lighting device 20R is performed by a communication flash emitted from the light emitting unit of the master lighting device 20M.

The camera 10 is a digital still camera, for example, and includes a photographic lens 11, an imaging unit 12, a control unit 13, a storage unit 14, an operation unit 15, and a display unit 16.
The lens 11 is a photographing optical system composed of a plurality of optical lens groups. In FIG. 1, it is represented by a single lens for simplification. Further, the photographing lens 11 includes a stop 11A that adjusts the amount of incident light by changing the aperture diameter.

Although not shown in detail, the imaging unit 12 includes an imaging element such as a CCD or a CMOS, an image processing circuit, and the like that photoelectrically convert an image formed by the photographing lens 11 into image electronic information. The image pickup unit 12 converts an image signal analog-to-photoelectrically converted by the image pickup device into a digital image signal (A / D conversion) and performs various image processing by pressing the release button in the operation unit 15 described later. After application, it is stored in the buffer memory as an image file.
Further, the imaging unit 12 includes a sensitivity setting unit 12A that changes an amplification factor (sensitivity) of image information output after photoelectric conversion by the imaging element.

The control unit 13 is configured by a CPU or the like, and comprehensively controls the operation of the camera 10. At the time of shooting, the image file shot by the image pickup unit 12 is read from the buffer memory. The image file is stored in a recording medium such as a removable memory card (not shown). The image file may be stored in the storage unit 14.
The control unit 13 reads a program stored in the storage unit 14 and executes various processes described later.

The storage unit 14 stores various programs related to the control of the camera 10 by the control unit 13.
The operation unit 15 includes various switches and buttons such as a release button and a power switch, and is operated by a user to select and set functions of the camera 10.
The display unit 16 is configured by a liquid crystal panel or the like, for example, and is disposed on the back surface of the camera 10. The display unit 16 displays a reproduced image of the captured image, a function setting screen of the camera 10, and the like based on an instruction from the control unit 13.

Next, the master lighting device 20M and the remote lighting device 20R will be described with reference to FIG. 1 and FIG. FIG. 2 is a circuit diagram conceptually showing the configuration of the drive circuit 22 of the illumination device 20.
In the present embodiment, the master lighting device 20M and the remote lighting device 20R have the same configuration. For this reason, in FIG. 1, the same elements are denoted by the same reference numerals. In the following description, when it is necessary to distinguish, “M” is added to the end of the reference numeral in the master lighting device 20M, and “R” is added in the remote lighting device 20R.

First, the overall configuration of the master lighting device 20M and the remote lighting device 20R will be described as the lighting device 20.
The illumination device 20 includes a light emitting unit 21, a drive circuit 22, a control unit 23, a storage unit 24, a light receiving unit 25, an operation unit 26 and a display unit 27. Further, a Fresnel lens 28 is provided in front of the light emitting unit 25.

The light emitting unit 21 includes a xenon tube 21A, a reflector 21B, and the like, and emits flash light from the xenon tube 21A by a high voltage applied from a drive circuit 22 described later. A Fresnel lens 28 is provided on the front side of the light emitting unit 21.
As shown in FIG. 2, the drive circuit 22 includes a battery 22A as a power source, a booster circuit including a booster transformer 22B and a booster transistor 22C, a main capacitor 22D, a switching element 22E, and the like. A high-voltage direct current voltage is applied to the light emitting section 21 (xenon tube 21A) by the action of the switching element 22E based on the command from.

  The control unit 23 is configured by a CPU or the like, and comprehensively controls the operation of the lighting device 20. And the control part 23 receives the light emission command, controls the drive circuit 22, and makes the light emission part 21 light-emit. The control unit 23 has a plurality of light emission control modes such as a TTL automatic light control mode and a manual mode.

  In addition, the control unit 23 performs temperature rise estimation and temperature warning control caused by light emission. That is, when the temperature rise of the light emitting unit 21 (including the Fresnel lens 28) and the drive circuit 22 due to light emission is estimated, the estimated temperature is compared with a preset threshold value, and the estimated value exceeds the set threshold value In this case, a temperature warning is displayed on the display unit 27. This temperature rise estimation and temperature warning control will be described in detail later.

  Further, the control unit 23 has an optical communication function. In other words, the control unit 23 can emit light pulses of the light emitting unit 21 and transmit optical signals of information such as unique information, setting state, and light emission history of the lighting device. Further, the control unit 23 can receive transmission information by receiving a light signal by the light receiving unit 25.

The storage unit 24 stores information for controlling the overall light emission operation of the lighting device 20 including a program related to temperature rise estimation and temperature warning control and information necessary for the program.
The light receiving unit 25 senses (receives) light from another illumination device or the like, and inputs the sensed information to the control unit 23.

The operation unit 26 includes a power switch and various operation buttons, and is operated by a user to select functions of the lighting device 20 and input settings.
The display unit 27 is configured by a liquid crystal panel, for example, and is disposed on the back surface of the lighting device 20. The display unit 27 displays a function setting screen such as an operation menu or a light emission mode based on an instruction from the control unit 23. In addition, temperature warning display by temperature warning control is performed.

The illuminating device 20 configured as described above is attached to, for example, an accessory shoe of a camera and electrically connected via a hot shoe (master illuminating device 20M in the present embodiment), or at a position away from the camera. Arranged (remote illumination device 20R). Then, based on a control signal sent from the attached camera via the hot shoe or a control signal sent by optical communication, the control unit 23 controls the drive circuit 22 to cause the light emitting unit 21 to emit light.
In the lighting device 20, the control unit 23 estimates the temperature rise of the part (the light emitting unit 21, the Fresnel lens 28, and the drive circuit 22) that rises in temperature due to light emission, and displays a temperature warning on the display unit 27.

のように計算でき、一般式では、

と表せる。対象部品のｎ回発光後の温度Ｔｎは、一般的には、発光光量、周囲温度、昇圧直前の温度等に関係する。
発光光量ＧＮは、メインコンデンサ２２Ｄの放出電気エネルギーに比例する。すなわち、
Ｃ：メインコンデンサ２２Ｄの容量
Ｖ０：発光開始時のメインコンデンサ２２Ｄの充電電圧
Ｖ１：発光完了後のメインコンデンサ２２Ｄの充電電圧
として、

よって、

このようにして、駆動回路２２の温度上昇を算出できる。 Here, the temperature rise estimation by the control unit 23 will be described in detail.
First, the temperature rise of the drive circuit 22 (step-up transformer 22B and step-up transistor 22C)
Ta: ambient temperature Tn: temperature after the nth boost operation of the target part T (n-1) d: next boost operation from the temperature T (n-1) after the (n-1) th boost operation of the target part Tnr: Temperature rise due to the nth boost operation of the target part t: Light emission interval

In the general formula,

It can be expressed. The temperature Tn of the target component after n times of light emission is generally related to the amount of emitted light, the ambient temperature, the temperature just before the pressure increase, and the like.
The amount of emitted light GN is proportional to the electric energy emitted from the main capacitor 22D. That is,
C: Capacity of main capacitor 22D V0: Charging voltage of main capacitor 22D at the start of light emission V1: Charging voltage of main capacitor 22D after completion of light emission

Therefore,

In this way, the temperature rise of the drive circuit 22 can be calculated.

のように計算でき、一般式では、

と表せる。フレネルレンズ２８のｎ回発光後の温度Ｔｎは、一般的には、発光光量、周囲温度、発光直前の温度、フレネルレンズ２８と発光部２１（キセノン管２１Ａ）との間隔が変化するズーム機能を有するものではその間隔、等に関係する。
よって、

なお、「ｚｏｏｍ」は、ズーム機能の作用（フレネルレンズ２８と発光部２１との間隔）に関する係数である。 On the other hand, the temperature rise of the light emitting unit 21 and the Fresnel lens 28 is as follows.
Ta: ambient temperature Tn: temperature after the nth light emission of the Fresnel lens T (n-1) d: next step-up operation from the temperature T (n-1) after the (n-1) th light emission of the Fresnel lens 28 Tnr: temperature rise due to the nth emission of the Fresnel lens 28 t: emission interval

In the general formula,

It can be expressed. The temperature Tn of the Fresnel lens 28 after n times of light emission generally has a zoom function in which the amount of emitted light, the ambient temperature, the temperature just before light emission, and the distance between the Fresnel lens 28 and the light emitting unit 21 (xenon tube 21A) change. What you have is related to the spacing, etc.
Therefore,

“Zoom” is a coefficient related to the function of the zoom function (the distance between the Fresnel lens 28 and the light emitting unit 21).

  The program of the above arithmetic expression is stored in the storage unit 24. The control unit 23 estimates the temperature rise of the drive circuit 22 and the light emitting unit 21 (including the Fresnel lens 28) by calculating according to a program of an arithmetic expression stored in the storage unit 24. Or the result calculated beforehand according to the said arithmetic formula may be stored in the memory | storage part 24 as a table, and the control part 23 is good also as a structure which reads temperature from the table.

  Next, temperature warning control of the master lighting device 20M and the remote lighting device 20R will be described with reference to FIGS. 3 to 6 in addition to FIG. FIG. 3 is a flowchart of temperature warning display control by the control unit 23M of the master lighting device 20M. FIG. 4 is a diagram showing a temperature warning display on the display unit 27 of the master lighting device 20M. FIG. 5 is a flowchart of temperature warning display control by the control unit 23R of the remote lighting device 20R. FIG. 6 is a diagram illustrating a signal for transmitting identification information from the remote lighting device 20R to the master lighting device 20M.

In the present embodiment, the master lighting device 20M is mounted on the camera 10, and the remote lighting device 20R is disposed at a position separated from the camera 10. That is, the remote lighting device 20R is located away from the master lighting device 20M.
Then, the master lighting device 20M inputs the light emission setting of the remote lighting device 20R and transmits it to the remote lighting device 20R, recognizes the remote lighting device 20R, temperature warning control of the master lighting device 20M, and temperature warning control of the remote lighting device 20R. I do. That is, the master lighting device 20M estimates the temperature rise of the remote lighting device 20R as well as the master lighting device 20M, and displays the temperature warning of the remote lighting device 20R on the display unit 27.

First, temperature warning control by the control unit 23M in the master lighting device 20M shown in the flowchart of FIG. 3 will be described.
First, setting that the master lighting device 20M is the main lighting is performed on the master lighting device 20M via the operation unit 26M (S01). Accordingly, the master lighting device 20M is set to perform the light emission command control and the temperature warning control of the remote lighting device 20R.
Next, light emission settings such as a light emission mode, a light emission amount, and a zoom position are input via the operation unit 26M (S02). Here, the light emission settings of both the master lighting device 20M and the remote lighting device 20R are input.

  When the light emission setting is input, the input light emission setting of the remote lighting device 20R is transmitted to the remote lighting device 20R by communication light emission of the light emitting unit 21M (S03). This communication light emission also serves as a test light emission for confirming the connection between the master lighting device 20M and the remote lighting device 20R, and is performed by operating the master lighting device 20M or the camera 10. In addition, transmission light emission may use pre-light emission for obtaining information such as the color, reflectance, and distance of a subject that is performed prior to actual photographing.

  When the light receiving unit 25M receives and receives the unique information (identification information) of the remote lighting device 20R transmitted by communication light emission as a reply of receiving the light emission setting from the remote lighting device 20R, the remote lighting device 20R is turned on. The identification is recognized (S04). This completes the preparation for shooting.

When the release switch of the camera 10 is pressed (ON) (S05), the light emitting unit 21M emits light (photographing light emission) according to the setting (S06).
Along with the photographing light emission, the temperature Tm of the master lighting device 20M is calculated (S07). Then, the calculation result is compared with a preset threshold value (S08), and if it is determined that the temperature Tm exceeds the set threshold value, a temperature warning is displayed on the display unit 27M (S09).
In parallel with Step 09 to Step 09, the temperature Tr of the remote lighting device 20R is calculated (S10). Then, the calculation result is compared with a preset threshold value (S11), and if it is determined that the temperature Tr exceeds the set threshold value, the temperature warning display of the remote lighting device 20R is displayed on the display unit 27M ( S12).

  It should be noted that the temperature Tm of the master lighting device 20M and the temperature Tr of the remote lighting device 20R to be compared with the set threshold are severe in conditions of either the light emitting units 21M and 21R (including the Fresnel lenses 28M and 28R) or the drive circuits 22M and 22R. Adopt one. In other words, the light emitting units 21M and 21R (including the Fresnel lenses 28M and 28R) and the drive circuits 22M and 22R are compared with the set threshold value, and if either one exceeds the set threshold value, a temperature warning display may be performed. Moreover, the structure which compares only any one with severe temperature conditions may be sufficient.

Here, an example of the temperature warning display on the display unit 27M is shown in FIG. Fig.4 (a) is an example at the time of providing the three remote lighting apparatuses 20R of AC.
In the display shown in FIG. 4A, the leftmost column indicates the lighting device, “M” indicates the master lighting device 20M, and “A” to “C” indicate the remote lighting device 20R. Hereinafter, although the detailed description is omitted for each column in the right direction, the light emission mode and the dimming correction amount are provided. The graphic display of the rightmost thermometer in the drawing shows the temperature, and in this example, the temperature warning display is made on the remote lighting device 20R of “C”.

Next, temperature warning control by the control unit 23M in the remote lighting device 20R whose flowchart is shown in FIG. 5 will be described.
First, the remote lighting device 20R is set so that the remote lighting device 20R is sub-illumination (S21). Thereby, the remote lighting device 20R is set to follow the light emission command control from the master lighting device 20M.

Next, the communication light emission of the light emission setting information that also serves as confirmation of connection from the master lighting device 20M is received and input by the light receiving unit 25R receiving light (S22).
As a reply that received the light emission setting, unique information (identification information) of the remote lighting device 20R is transmitted to the master lighting device 20M by communication light emission of the light emitting unit 21R (S23). This completes the preparation for shooting.

Thereafter, when the light receiving unit 25R receives the photographing light emission of the master illumination device 20M (S24), the light emitting unit 21R emits light (photographing light emission) according to the setting (S25).
Here, FIG. 6 shows an example of communication light emission for transmitting the unique information (identification information) of the remote lighting device 20R to the master lighting device 20M.
FIG. 6 shows an example in which three remote lighting devices 20R of A to C are provided.
From the master lighting device 20M, the light emission setting is transmitted (communication light emission) as an optical pulse signal. The remote illumination devices 20R of A to C received when the light receiving unit 25R receives the light returns a light pulse signal (communication light emission) from the light emitting unit 21R at a predetermined time (T1 to T3). . The reply from the remote lighting device 20R in FIG. 6 is an example in which identification information such as a model is transmitted by a 4-bit pulse signal.

As described above, this embodiment has the following effects.
(1) The temperature warning display of the remote lighting device 20R disposed away from the camera 10 can be performed on the display unit 27M of the master lighting device 20M attached to the camera 10. Thereby, it is possible to easily grasp the temperature rise of the remote lighting device 20R separated by the operator, and it is possible to prevent the failure of the imaging and the malfunction of the device related to the temperature rise.
(2) It is not necessary to newly provide a temperature sensor or the like, and can be configured at a low cost with a simple configuration.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS.
FIG. 7 is a flowchart of temperature warning control by the control unit 23M in the master lighting device 20M. FIG. 8 is a flowchart of temperature warning control by the control unit 23R in the remote lighting device 20R.

The temperature warning control in the master lighting device 20M and the remote lighting device 20R is different from the first embodiment described above. Since the overall configuration of the system and the configuration of the illumination device are exactly the same as those of the first embodiment described above, description thereof is omitted.
In the temperature warning control in the second embodiment, the remote lighting device 20R itself makes a temperature rise estimation of the remote lighting device 20R, and transmits the estimated information to the master lighting device 20M. The temperature warning display is performed on the display unit 27M of the master lighting device 20M.

First, temperature warning control by the control unit 23M in the master lighting device 20M shown in the flowchart of FIG. 7 will be described.
First, setting that the master lighting device 20M is the main lighting is performed on the master lighting device 20M via the operation unit 26M (S31). Accordingly, the master lighting device 20M is set to perform the light emission command control and the temperature warning control of the remote lighting device 20R.
Next, light emission settings such as a light emission mode, a light emission amount, and a zoom position are input via the operation unit 26M (S32). Here, the light emission settings of both the master lighting device 20M and the remote lighting device 20R are input.

  When the light emission setting is input, the input light emission setting of the remote lighting device 20R is transmitted to the remote lighting device 20R by communication light emission of the light emitting unit 21M (S33). This communication light emission also serves as a test light emission for confirming the connection between the master lighting device 20M and the remote lighting device 20R, and is performed by operating the master lighting device 20M or the camera 10.

  When the light receiving unit 25M receives and receives the unique information (identification information) of the remote lighting device 20R sent by communication light emission as a reply of receiving the light emission setting from the remote lighting device 20R, the remote lighting device 20R Is recognized and recognized (S34). This completes the preparation for shooting.

When the release switch of the camera 10 is pressed (ON) (S35), the light emitting unit 21M emits light (photographing light emission) according to the setting (S36).
Along with the photographing light emission, the temperature Tm of the master lighting device 20M is calculated (S37). Then, the calculation result is compared with a preset threshold value (S38), and if it is determined that the temperature Tm exceeds the set threshold value, a temperature warning is displayed on the display unit 27M (S39).
Further, the temperature Tr of the remote lighting device 20R transmitted from the remote lighting device 20R after light emission is received (S40). Then, the received temperature Tr of the remote lighting device 20R is compared with a preset threshold value (S41). If it is determined that the temperature Tr exceeds the set threshold value, the display unit 27M displays the remote lighting device 20R. A temperature warning is displayed (S42).

Next, temperature warning control by the control unit 23R in the remote lighting device 20R whose flowchart is shown in FIG. 8 will be described.
First, the remote lighting device 20R is set so that the remote lighting device 20R is sub-illumination (S51). Thereby, the remote lighting device 20R is set to follow the light emission command control from the master lighting device 20M.

Next, the communication light emission of the light emission setting information that also serves as confirmation of connection from the master lighting device 20M is received and received by the light receiving unit 25R (S52).
As a reply that received the light emission setting, unique information (identification information) of the remote lighting device 20R is transmitted to the master lighting device 20M by communication light emission of the light emitting unit 21R (S53). This completes the preparation for shooting.

Thereafter, when the light receiving unit 25R receives light emission (photographing light emission) of the master illumination device 20M (S54), the light emitting unit 21R emits light (photographing light emission) according to the setting (S55).
Along with photographing light emission, the temperature Tr of the remote lighting device 20R is calculated (S56). Then, the calculated temperature Tr is transmitted to the master illumination device 20M by communication light emission of the light emitting unit 21R after a predetermined time determined after photographing light emission (S57).

  In this control configuration, the remote lighting device 20R transmits information on the calculated temperature Tr of the remote lighting device 20R to the master lighting device 20M. However, the configuration may be such that the remote lighting device 20R compares the temperature Tr with the threshold value to determine whether or not the temperature warning display is necessary, and transmits the necessity of the temperature warning display to the master lighting device 20M.

  As described above, according to the second embodiment, similarly to the first embodiment described above, the temperature warning display of the remote lighting device 20R arranged separately can be performed on the display unit 27M of the master lighting device 20M. Thereby, it is possible to easily grasp the temperature rise of the remote lighting device 20R separated by the operator, and it is possible to prevent the failure of the imaging and the malfunction of the device related to the temperature rise.

(Deformation)
The present invention is not limited to the above-described embodiment, and various modifications and changes as described below are possible, and these are also within the scope of the present invention.
(1) In the above embodiment, the remote lighting device 20R has an optical communication function of transmitting identification information to the master lighting device 20M by light emission. However, the present invention can also apply the remote lighting device 20R that does not have a communication function.
In that case, the storage unit 24 of the master lighting device 20M stores in advance the unique information (temperature increase condition or temperature increase table) related to temperature control in the existing lighting device as a database. And it sets by manual operation at the time of the setting of the main illumination with respect to the master illuminating device 20M, or the light emission setting of the remote illuminating device 20R. That is, the operation unit 26 is operated to display and set the identification code (model, etc.) of the remote lighting device 20R on the display unit 27. Thereby, a temperature rise can be estimated based on the set unique information of the remote lighting device 20R, and a temperature warning display can be performed. Moreover, it can respond also to a new illuminating device by updating the specific information database stored in the memory | storage part 24. FIG. According to such a configuration, an existing illumination device can be used as the remote illumination device 20R.
FIG. 4B shows an example of a temperature warning display when the identification code of the remote lighting device 20R is set by manual operation. The identification code of the remote lighting device 20R is displayed in the leftmost column in the figure. Further, a temperature warning is displayed on the remote lighting device 20R of “C”.

(2) The above embodiment is an example in which a so-called external lighting device attached to the camera 10 is a master lighting device 20M. However, when the camera 10 includes a lighting device, the lighting device included in the camera 10 may be the master lighting device 20M. In that case, the control unit 13 of the camera 10 performs the above-described control, and the temperature warning display is performed by the display unit 16 of the camera 10.

(3) The above embodiment is configured to exchange information between the master lighting device 20M and the remote lighting device 20R by communication light emission. However, information exchange between the master lighting device 20M and the remote lighting device 20R is not limited to communication light emission, and information may be exchanged by wireless telecom communication.

(4) In the above embodiment, the information (temperature warning) of the remote lighting device 20R located at a distance is displayed on the display unit 27M of the master lighting device 20M located near the user or the display unit 16 of the camera 10. indicate. However, the information exchange function and display unit with the remote lighting device 20R may be provided in a controller or the like separate from the master lighting device 20M and the camera 10.

(5) In addition to the configuration of the above embodiment, the shooting condition setting of the camera 10 is variably controlled so as to reduce the thermal load applied to the master lighting device 20M and the remote lighting device 20R in accordance with the temperature warning in the master lighting device 20M. You may comprise so that it may do. The variable control of the photographing condition setting for reducing the thermal load includes an increase in sensitivity by the sensitivity setting unit 12A, opening of the aperture 11A, and the like. That is, in a state where a temperature warning is issued, the sensitivity set by the sensitivity setting unit 12A is increased or the aperture 11A is opened. Thereby, the light emission amount in the master lighting device 20M and the remote lighting device 20R can be reduced, and as a result, the temperature rise can be suppressed. Such correspondence control of the camera 10 is not limited to the case where the illumination device provided in the camera 10 is the master illumination device 20M.

Further, the light emission condition may be changed so as to reduce the thermal load acting on the master lighting device 20M and the remote lighting device 20R in accordance with the temperature warning in the master lighting device 20M. For example, the light emission interval may be set longer than usual or the light amount may be reduced.
Further, in the remote lighting device 20R in which the light emitting unit 21 can be controlled to move in the illumination light irradiation direction, the position of the light source (xenon tube 21A) is moved to the side where the light distribution angle becomes narrower due to the temperature warning in the master lighting device 20M. It is good also as a structure to which it moves. The control command is configured to be issued from the master lighting device 20M with a temperature warning in the master lighting device 20M.

(6) In the above embodiment, the temperature warning display (temperature information) of the remote lighting device 20R is displayed on the display unit 27M of the master lighting device 20M. However, the information transmitted from the remote lighting device 20R and displayed on the display unit 27M of the master lighting device 20M is not limited to temperature information. For example, other physical quantities such as a remaining battery level may be used.
(7) The above embodiment is an example in which the present invention is applied to a flash illumination device. However, the application target of the present invention is not limited to the flash illumination device, but may be applied to, for example, an LED illumination device.

  In addition, although embodiment and a deformation | transformation form can also be used in combination as appropriate, detailed description is abbreviate | omitted. Further, the present invention is not limited to the embodiment described above.

  1: imaging system, 10: camera 10, 11: photographing lens. 11A: Aperture, 12: Imaging unit, 12A: Sensitivity setting unit, 20M: Master illumination device, 21M: Light emission unit, 23M: Control unit, 24M: Storage unit, 25M: Light reception unit, 27M: Display unit, 20R: Remote illumination Device, 21R: Light emitting part, 21A: Xenon tube, 25R: Light receiving part

Claims (18)

A light emission instructing unit for instructing light emission of the illumination light for photographing to a remote illumination device that irradiates the illumination light for photographing toward a subject from a place away from the photographing device;
An information acquisition unit that acquires physical quantity information that varies in the remote lighting device under the influence of the light emission when the illuminating illumination light is emitted according to the instruction from the light emission instruction unit;
And a display unit that displays the physical quantity information acquired by the information acquisition unit. The remote lighting control device according to claim 1,
A calculation unit that estimates and calculates the physical quantity information based on the content of the command transmitted from the light emission instruction unit to the remote lighting device;
Remote lighting control device characterized by. The remote lighting control device according to claim 2,
A storage unit that stores information related to the estimation of the physical quantity information used for the estimation calculation of the physical quantity information in the calculation unit for each type of the remote lighting device;
Remote lighting control device characterized by. The display device according to claim 3,
A receiver that receives the unique information of the remote lighting device transmitted from the remote lighting device;
The calculation unit is configured to estimate and calculate the physical quantity information based on information corresponding to the specific information received by the reception unit among the information stored in the storage unit;
Remote lighting control device characterized by. The remote lighting control device according to claim 1,
A receiving unit for receiving the physical quantity information transmitted from the remote lighting device;
The display unit displays the physical quantity information received by the receiving unit;
Remote lighting control device characterized by. The remote lighting control device according to any one of claims 1 to 5,
When the physical quantity information exceeds a preset threshold, displaying a warning on the display unit;
Remote lighting control device characterized by. The remote lighting control device according to any one of claims 1 to 6,
The physical quantity information includes a remaining battery level of the remote lighting device;
Remote lighting control device characterized by. The remote lighting control device according to any one of claims 1 to 7,
The physical quantity information includes a temperature of the remote lighting device;
Remote lighting control device characterized by. The remote lighting control device according to any one of claims 1 to 8,
The remote illumination control device is a master illumination device including an illumination unit capable of irradiating illumination light to the subject. The remote lighting control device according to any one of claims 1 to 8,
The remote illumination control device is a camera having a built-in illumination unit capable of irradiating illumination light to the subject. The remote lighting control device according to any one of claims 1 to 8,
The remote illumination control device is a camera in which a master illumination device including an illumination unit capable of irradiating illumination light to the subject is detachable. The remote lighting control device according to claim 10 or 11,
A photographic lens and a diaphragm member for adjusting the amount of light passing through the photographic lens;
If the temperature of the remote lighting device exceeds a preset threshold,
The diaphragm member is configured to increase the amount of light passing through the photographing lens;
Remote lighting control device characterized by. The remote lighting control device according to any one of claims 10 to 12,
An imaging unit and a sensitivity setting unit for changing the sensitivity of the imaging unit;
If the temperature of the remote lighting device exceeds a preset threshold,
The sensitivity setting unit increases the sensitivity of the imaging unit;
Remote lighting control device characterized by. The remote lighting control device according to any one of claims 1 to 13,
A transmission unit that transmits a control signal for controlling the movement of the light source to the remote illumination device capable of moving the light source of the illumination light in the irradiation optical axis direction;
If the temperature of the remote lighting device exceeds a preset threshold,
The transmission unit transmits a control signal for moving the position of the light source of the remote lighting device to a side where a light distribution angle becomes narrower to the remote lighting device;
Remote lighting control device characterized by. A remote lighting device that emits illumination light for photographing,
A receiver for receiving a light emission command for emitting the photographing illumination light emitted from the remote illumination control device at a position separated from the remote illumination device;
A transmitter capable of transmitting its own unique information to the remote lighting control device;
Providing
Remote lighting device characterized by. The remote lighting device according to claim 15, wherein
The transmission of the specific information is performed as a part of the test light emission at the time of the test light emission performed in accordance with a command from the remote lighting control device,
Remote lighting device characterized by. The remote lighting device according to claim 15 or 16,
The transmission unit transmits, as the unique information, physical quantity information that causes fluctuations in the remote illumination device under the influence of the light emission when the photographing illumination light is emitted according to the light emission command. Remote lighting device. A remote illumination device that emits illumination light for photographing toward a subject from a place away from the photographing device;
A remote illumination control device that issues a light emission command for causing the remote illumination device to emit the illumination light for photographing from a position away from the remote illumination device;
Physical quantity information that is arranged integrally with the remote lighting control device and causes fluctuations in the remote lighting device under the influence of the light emission when the remote lighting device emits the photographing illumination light according to the light emission command A display device for displaying
A remote lighting device system comprising:

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