JP4724333B2 - Flash device, imaging device, and control method of flash device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is plural Device having the above light emitting means, imaging device, and control method of the flash device It is about.
[0002]
[Prior art]
Conventionally, in a flash device having a single discharge tube and performing pre-emission for obtaining exposure information at the time of photographing as disclosed in Japanese Patent Application Laid-Open No. 9-61913, an invention regarding the amount of pre-emission is described.
[0003]
The light intensity of the pre-light emission is only changed according to the charging voltage, the subject brightness, and the distance to the subject by communication from the camera.
[0004]
[Problems to be solved by the invention]
However, in a flash device having a plurality of discharge tubes, when one or more of the plurality of discharge tubes are used for photographing, each discharge tube determines the light intensity of pre-emission only by an instruction from the camera. When using a single discharge tube and multiple discharge tubes, there is a difference in the charging voltage of the main capacitor after the end of pre-emission, and when the interval between pre-emission and main emission is short, There arises a problem that the charging energy of the main capacitor is insufficient.
[0005]
Referring to FIG. 9, 1a is a pre-emission waveform in the case of a single discharge tube, and 1b is a change in the charging voltage of the main capacitor at this time. An example in which two discharge tubes are used as in the conventional example will be described with reference to 2a, 2b and 2c in FIG. As indicated by the camera, the pre-emission waveform (2a) of the discharge tube A and the light intensity (H2A, H2B) of the pre-emission waveform (2b) of the discharge tube B are the same as the pre-emission intensity H1 in the case of a single discharge tube. In the case of light emission of light intensity (assuming that H2A = H2B = H1), as shown in FIG. 2c, the charging voltage of the main capacitor is reduced from the charging voltage (2c dotted line) of the discharge tube by pre-emission.
[0006]
An object of the present invention is to solve such a problem, and the charging voltage of the main capacitor is Light emitting means Can be maintained so that it does not drop below the light-emitting charge voltage Flash device, imaging device, and control method of flash device Is to provide.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the flash device of the present invention is suitable for flash photography. Prior to performing the main flash A flash device that performs pre-emission, a main capacitor that stores electrical energy, and a plurality of light emitting means that emit light using the electrical energy stored in the main capacitor, A light emission control means for controlling a pre-emission light amount at the time of pre-emission of the light emission means; Have The light emission control unit is configured to perform pre-light emission so that a charging voltage of the main capacitor does not become less than a charging voltage required for main light emission. Number of light emitting means that sometimes emit light Will increase In accordance with the pre-emission light amount at the pre-emission of the light emitting means for emitting light Decline It is characterized by making it.
[0008]
In addition, the image pickup apparatus of the present invention is suitable for flash photography. Prior to performing the main flash An imaging device that performs pre-emission, a main capacitor that stores electrical energy, and a plurality of light emitting means that emit light using the electrical energy stored in the main capacitor, A light emission control means for controlling a pre-emission light amount at the time of pre-emission of the light emission means; Have The light emission control unit is configured to perform pre-light emission so that a charging voltage of the main capacitor does not become less than a charging voltage required for main light emission. Number of light emitting means that sometimes emit light Will increase In accordance with the pre-emission light amount at the pre-emission of the light emitting means for emitting light Decline It is characterized by making it.
[0009]
Further, the light emission control method of the flash device of the present invention has a plurality of light emitting means for emitting light using electric energy stored in the same main capacitor. Before the main flash is fired during flash photography. A light emission control method for a flash device, comprising: Pre-light emission so that the charging voltage of the main capacitor does not become less than the charging voltage required for main light emission. Number of light emitting means that sometimes emit light Will increase In accordance with the pre-emission light amount at the pre-emission of the light emitting means for emitting light Decline It is characterized by making it.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 is a cross-sectional view mainly illustrating an optical configuration of a flash device camera system implemented by applying the present invention to a single-lens reflex camera.
[0018]
Reference numeral 1 denotes a camera body in which optical parts, mechanical parts, electric circuits, films, and the like are housed so that photography can be performed. Reference numeral 2 denotes a main mirror, which is obliquely set in or removed from the photographing optical path according to the observation state and the photographing state. Even when the main mirror 2 is a half mirror and is inclined, approximately half of the light beam from the subject is transmitted through a focus detection optical system described later. Reference numeral 3 denotes a focusing plate arranged on the planned imaging plane of the photographing lenses 12 to 14, 4 denotes a pentaprism for changing the finder optical path, and 5 denotes a finder. The photographer observes the focusing plate 3 through this window. You can observe the screen. Reference numerals 6 and 7 denote an imaging lens and a multi-divided photometric sensor for measuring the luminance of the object in the observation screen. The imaging lens 6 is connected to the focusing plate 3 and the multi-divided photometric sensor 7 via the reflected light path in the pentaprism 4 It is related to conjugation.
[0019]
FIG. 4 shows a photometric area division diagram on the photographing screen. The photographing screen is divided into 23 areas from A0 to A22. The multi-segment photometric sensor 7 can measure the brightness of each area related to the imaging screen in a conjugate manner.
[0020]
Returning to FIG. 1, 8 is a shutter and 9 is a photosensitive member, which is made of a silver salt film or the like. Even when the main mirror 2 is installed obliquely, approximately half of the light rays from the subject are transmitted. Reference numeral 25 denotes a sub-mirror that guides the light beam from the subject toward the focus detection unit 26 by bending downward. The focus detection unit 26 includes a secondary imaging mirror 27, a secondary imaging lens 28, a focus detection line sensor 29, and the like. The secondary imaging mirror 27 and the secondary imaging lens 28 form a focus detection optical system, and the secondary imaging surface of the photographing optical system is connected to the focus detection line sensor 29. The focus detection unit 26 detects the focus state of the subject in the shooting screen by a known phase difference detection method by processing of an electric circuit described later, and realizes an automatic focus detection device by controlling the focus adjustment mechanism of the shooting lens. ing. This automatic focus detection apparatus detects the seven focus states A0 to A6 in the photographing screen of FIG.
[0021]
Reference numeral 23 denotes a photometric lens for photometry of the film surface, and reference numeral 24 denotes a film surface photometric sensor. These are used for so-called TTL dimming, in which the amount of exposure is measured using diffuse reflection of light that reaches the film surface during exposure to obtain an appropriate amount of light for the flash device.
[0022]
A mount contact 10 serves as an interface between a known camera and a photographing lens, and a lens barrel 11 is installed on the camera body. Reference numerals 12 to 14 denote photographing lenses, and reference numeral 12 denotes a first group lens. The focusing position on the photographing screen can be adjusted by moving the lens on the optical axis to the left and right. Reference numeral 13 denotes a two-group lens that is movable left and right on the optical axis, thereby changing the shooting screen and changing the focal length of the shooting lens. Reference numeral 14 denotes a three-group fixed lens. Reference numeral 15 denotes a photographing lens aperture.
[0023]
Reference numeral 16 denotes a first group lens driving motor, which can automatically adjust the focus position by moving the first group lens to the left or right according to the automatic focus adjustment operation. Reference numeral 17 denotes a lens diaphragm drive motor, which can open or squeeze the photographing lens diaphragm.
[0024]
Reference numeral 18 denotes an external flash device controller which is attached to the camera body 1 and performs light emission control in accordance with a signal from the camera. 19 A, 19 B is a flash device light emitting unit, and is electrically connected to the flash device control unit 18 by connection cords 30A and 30B.
[0025]
310A and 310B are discharge tubes that convert current energy into luminous energy. Reference numerals 20A, 21A, 20B, and 21B are a reflector and a Fresnel, and each has a role of efficiently condensing light emission energy toward a subject. A known flash device contact 22 is an interface between the camera body 1 and the external flash device 18. The light emitted from the discharge tube 310A is received by the flat light emission control sensor 333A and the integration sensor 335A. The light emitted from the discharge tube 310B is received by the flat light emission control sensor 333B and the integration sensor 335B. FIG. 1 shows only the optical mechanical member among the members necessary for realizing the present invention, and other electric circuit members are necessary, but are omitted here.
[0026]
2 and 3 are electric circuit block diagrams of the flash device camera system according to the embodiment of the present invention. 2 shows circuit blocks on the camera body side and the lens side, and FIG. 3 shows circuit blocks on the flash device side, and members corresponding to those in FIG. 1 are given the same numbers.
[0027]
First, FIG. 2 will be described. Connected to the camera microcomputer 100 are a focus detection circuit 105, a photometry circuit 106, a shutter control circuit 107, a motor control circuit 108, a film running detection circuit 109, a switch sensor circuit 110, a liquid crystal display circuit 111, and a film surface reflection photometry circuit 114. ing. Further, a signal is transmitted to the photographing lens side via the mount contact group 10. Further, the flash device side transmits signals through the flash device contact group 22 in a state where the flash device is directly attached to the camera body.
[0028]
As described above, the line sensor 29 is for detecting the focus states of the seven points A0 to A6 in the photographing screen on the finder, and corresponds to each distance measuring point in pairs on the secondary imaging plane of the photographing optical system. Line sensor. The focus detection circuit 105 performs accumulation control and readout control of these line sensors 29 in accordance with signals from the camera microcomputer 100, and outputs pixel information obtained by photoelectric conversion to the camera microcomputer 100. The camera microcomputer 100 A / D converts this information and performs focus detection by a known phase difference detection method. The camera microcomputer 100 performs focus adjustment of the lens by exchanging signals with the lens microcomputer 112 based on the focus detection information.
[0029]
The photometry circuit 106 outputs to the camera microcomputer 100 the output from the multi-division photometry sensor 7 that divides the screen into a plurality of areas as described above as the luminance signal of each area in the screen. The photometry circuit 106 outputs a luminance signal in both the steady state where the flash device light is not pre-flashed toward the subject and the pre-flash state where the pre-flash is being emitted, and the camera microcomputer 100 outputs the luminance signal to the A / D. Then, the aperture value and the shutter speed are calculated for adjusting the exposure of photographing, and the main flash quantity of the flash device at the time of exposure is calculated.
[0030]
The shutter control circuit 107 runs the shutter front curtain (MG-1) and the shutter rear curtain (MG-2) in accordance with a signal from the camera microcomputer 100, and performs the exposure operation.
[0031]
The motor control circuit 108 controls the motor in accordance with a signal from the camera microcomputer 100 to perform up / down of the main mirror 2, charge of the shutter, and feeding of the film. The film running detection circuit 109 detects whether or not the film has been wound up by one frame when the film is fed, and sends a signal to the camera microcomputer 100.
[0032]
SW1 is turned on by a first stroke of a release button (not shown), and serves as a switch for starting photometry and AF. SW2 is turned on by the second stroke of the release button and serves as a switch for starting an exposure operation. SWFELK is a switch that is turned on by a push switch (not shown), and is a start switch for an operation for determining and locking the light amount of the flash device by performing pre-emission of the flash device before the exposure operation. Signals from SW1, SW2, SWFELK and other camera operation members (not shown) are detected by the switch sensor circuit 110 and sent to the camera microcomputer 100. SWX is a switch that is turned on when the shutter is fully opened, and sends the light emission timing of main light emission during exposure to the flash device side.
[0033]
The liquid crystal display circuit 111 controls display on the in-viewfinder LCD 41 and a monitor LCD 42 (not shown) according to a signal from the camera microcomputer 100. Reference numeral 114 denotes a film surface reflection photometry circuit, and the camera microcomputer 100 can obtain photometric information of the film surface photometry sensor 24. The film surface photometric sensor 24 divides the screen as shown in FIG. 4 like the multi-segment photometric sensor 7, and can measure the luminance of each area related to the imaging screen.
[0034]
Next, the configuration of the lens will be described. The camera body and the lens are electrically connected to each other via the lens mount contact 10. The lens mount contact 10 includes a focus drive motor 16 in the lens and a power supply contact L0 of the aperture drive motor 17, a power supply contact L1 of the lens microcomputer 112, and a clock for performing known serial data communication. A contact L2 for data transmission, a contact L3 for data transmission from the camera to the lens, a contact L4 for data transmission from the lens to the camera, a ground contact L5 for the motor power supply, and a ground contact for the power supply for the lens microcomputer 112. L6.
[0035]
The lens microcomputer 112 is connected to the camera microcomputer 100 through these lens mount contacts 10 and operates the first lens drive motor 16 and the lens aperture motor 17 to control the focus adjustment and the aperture of the lens. Reference numerals 35 and 36 denote a photodetector and a pulse plate. The lens microcomputer 112 can obtain the position information of the first lens group by counting the number of pulses, adjust the focus of the lens, and obtain the absolute distance information of the subject. It can be transmitted to the camera microcomputer 100.
[0036]
Next, the configuration of the flash device will be described with reference to FIG. In the figure, reference numeral 301 denotes a battery as a power source, and reference numeral 302 denotes boosting means for boosting the battery voltage to several hundred volts. A main capacitor 303 charges the output of the booster 302. 304 and 305 use the voltage of the main capacitor as the control circuit. The This is a voltage dividing resistor provided for monitoring by the microcomputer 338 (hereinafter referred to as “flash device microcomputer”). The flash device microcomputer 338 A / D-converts the divided voltage by the built-in A / D converter, thereby indirectly monitoring the charging voltage of the main capacitor 303 and controlling the operation of the booster 302 to thereby control the main capacitor. The charging voltage 303 is controlled to a predetermined voltage.
[0037]
308A and 308B are coils for limiting the light emission current, 309A and 309B are diodes for returning the energy accumulated in the current limiting coils 308A and 308B when light emission is stopped, 310A and 310B are discharge tubes as light emitting means, and 311A , 311B is a trigger means for generating a high voltage of several thousand volts in the discharge tubes 310A, 310B at the start of light emission, 306A is an AND gate, the input is connected to the TRIG terminal and the SEL_A terminal of the flash device microcomputer 338, and the output is the trigger means 311A, 306B is an AND gate, the input is connected to the TRIG terminal and the SEL_B terminal of the flash device microcomputer 338, and the output is connected to the trigger means 311B.
[0038]
312A and 312B are light emission control circuits which are first switching means for controlling the light emission current of the discharge tubes 310A and 310B and controlling the start and stop of light emission of the discharge tubes, and are constituted by switching elements such as IGBTs.
[0039]
330A and 330B are data selectors, and EN terminals are respectively connected to SEL_A and SEL_B terminals of the flash device microcomputer 338. When the EN terminal is H, inputs D0 to D2 are input based on signals input to the X0 and X1 terminals. Is output to the Y terminal. When the EN terminals of the data selectors 330A and 330B are L, the output terminal Y outputs L regardless of the D0 to D2 terminals. The output Y of the data selector 330A is connected to the input terminal IN_A of the flash device microcomputer 338 and the switching means 312A, and the output Y of the data selector 330B is connected to the input terminal IN_B of the flash device microcomputer 338 and the switching means 312B.
[0040]
333A and 335A are light receiving elements that receive light from the discharge tube 310A, and 333B and 335B are light receiving elements that are sensors that receive light from the discharge tube 310B. Reference numerals 334A, 334B, 336A, and 336B denote signal processing and amplification of the light receiving elements, 337A and 337B denote integration circuits that integrate outputs of the light receiving circuits 336A and 336B, and 331A, 331B, 332A, and 332B denote comparators. 338 is a microcomputer for controlling the operation of the entire flash device, 339 is a connection terminal for a camera (not shown), and CLK (camera side S0 terminal), DI (camera side S1), DO (camera side S2) terminals are used. Performs known serial communication. Reference numeral 340 denotes an EEPROM serving as storage means, which stores the maximum integration value of the integration circuits 337A and 337B when the discharge tubes 310A and 310B are fully lit.
[0041]
Next, each terminal of the flash device microcomputer 338 will be described. As described above, CLK, DI, and DO are communication terminals for performing known serial communication with a camera (not shown). A synchronous clock signal from the camera is input to CLK, and DI is synchronized with the clock signal. Serial data from the camera is output to the terminal, and at the same time, serial data is output from the flash device from the DO terminal. The CHG (camera side S3) terminal is a terminal for communicating information about the light emission of the flash device as current information to the camera, and X is a terminal to which a light emission start signal from the camera is input. ECK is a terminal for outputting a communication clock for serial communication with a writable storage means such as an EEPROM or a flash ROM connected to the outside of the flash device microcomputer 338, and EDI is a serial data input from the storage means. A terminal, EDO is a serial data output terminal to the storage means, and SELE is an enable terminal for permitting communication with the storage means. For the sake of explanation, it is enabled by L and disabled by H. In this embodiment, the storage means is set outside the flash device microcomputer 338. However, it goes without saying that the same is true even if it is built in the flash device microcomputer 338.
[0042]
INT_A and INT_B are control outputs for controlling the integration start and stop of the integration circuits 337A and 337B. The integration start is L and the integration stop is H. DA_A and DA_B are digital / analog conversion output terminals, which convert the internal digital data of the flash unit microcomputer 338 into a voltage that is an analog signal, and output a comparator voltage for the comparators 331A, 331B, 332A, 332B. AD_A and AD_B are terminals for analog / digital conversion for reading the output voltages of the integration circuits 337A and 337B and converting them into digital data for processing inside the microcomputer.
[0043]
The SEL_A terminal outputs H when the discharge tube 310A emits light, outputs L when not emitting light, and the SEL_B terminal outputs H when light is emitted from the discharge tube 310B and outputs L when not emitting light. The flash device microcomputer 338 detects the state of the output terminal Y of the data selectors 330A and 330B by detecting the state of the output terminals Y of the data selectors 330A and 330B. The terminal ADI is an analog / digital conversion input terminal for inputting the voltage obtained by dividing the high voltage of the main capacitor 303 by the resistors 304 and 305 as described above and converting it into digital data for processing inside the flash unit microcomputer 338. , CNT are control output terminals for controlling oscillation / stop of the boosting means, and control the operation of the boosting means 302 according to the charging voltage of the main capacitor 303 monitored by the ADI and the operating condition of the flash device.
[0044]
(Adjustment)
Next, storage of the maximum integral value at the time of full light emission at the time of adjusting the flash device and adjustment of the light amount at the time of flat light emission that is pre-light emission will be described below.
[0045]
(Storing the maximum integrated value at full flash)
A process of storing the maximum value (maximum integrated value) of the outputs of the integrating circuits 337A and 337B when the discharge tubes of the discharge tubes 310A and 310B are caused to emit full light will be described with reference to the flow of FIG.
[0046]
Start at S1001, and set maximum values to DA_A and DA_B of the DA converter terminal of the flash unit microcomputer 338 at S1002. . If the maximum integral value of the discharge tube 310A is stored in S1003, the process proceeds to S1004, and if the maximum integral value of the discharge tube 310B is stored, the process proceeds to S1005. In S1004, H and L are output to the SEL_A and SEL_B terminals, and only the discharge tube 310A is allowed to emit light. In S1005, L and H are output to the SEL_A and SEL_B terminals, and only the discharge tube 310B is allowed to emit light.
[0047]
In S1006, the data selectors 330A and 330B select the D1 input by outputting H and L to the respective terminals X0 and X1. At this time, since the discharge tubes 310A and 310B are not emitting light, almost no high current flows through the sensors 335A and 335B that directly monitor the discharge tubes, and the integration circuits 337A and 337B prohibit the integration. The outputs of 332A and 332B are H, and the IGBT of the light emission control circuit 312A or 312B becomes conductive through the data selectors 330A and 330B (if SEL_A or SEL_B is L, the Y of the data selector whose EN terminal is L) The output remains L and the IGBT is non-conductive). In step S1007, H is output to the TRIG terminal for a predetermined time. When SEL_A is H, the trigger unit 311A generates a high voltage from the trigger unit 311B. When SEL_B is H, the high voltage is generated from the trigger unit 311B. To do. In S1008, wait is performed after a predetermined time from TRIG = H. In S1009, the INT_A and INT_B terminals of the flash device microcomputer 338 are set to L, and the integration circuits 337A and 337B start integration. In step S1010, after waiting for a time to complete the light emission, the INT_A and INT_B terminals are set to H in S1011 to stop the integration. In S1012, the outputs of the integrating circuits 337A and 337B corresponding to the discharge tubes that emit light from the AD_A and AD_B terminals are AD-converted. In S1013, the values AD-converted in S1012 are written and stored in the EEPROM 340 as storage means as INT_FULLLA and INT_FULLLB. The process ends in S1014.
[0048]
(Flat light intensity adjustment)
Next, the light amount adjustment operation at the time of flat light emission which is pre-light emission will be described along the flow of FIG.
[0049]
In S2001, the process proceeds to S2003 when adjusting the flat light emission amount of the discharge tube 310A in S2002, and to S2005 when adjusting the discharge tube 310B. In S2003, H and L are output to SEL_A and SEL_B, and only the discharge tube 310A is allowed to emit light. In S2004, the DA value DA_PA, which is a reference for flat light emission, is output from the DA_A terminal. In S2005, L and H are output to the SEL_A and SEL_B terminals, and only the discharge tube 310B is allowed to emit light. In S2006, the DA value DA_PB, which is a reference for flat light emission, is output from the DA_B terminal. The flat emission reference values DA_PA and DA_PB are values stored in the EEPROM 340.
[0050]
By outputting L and H to the X0 and X1 terminals in S2007, the data selectors 330A and 330B select the D2 input. At this time, since the discharge tube is not emitting light, almost no photocurrent flows through the sensors 333A and 333B that are directly monitoring the discharge tube, and the outputs of the comparators 331A and 331B are H and pass through the data selectors 330A and 330B. The IGBTs of the light emission control circuits 312A and 312B are turned on (if SEL_A or SEL_B is L, the Y output of the data selector whose EN terminal is L remains L and the IGBT is non-conductive). At the same time, by setting the TRIG terminal of the flash device microcomputer 338 to a predetermined time H in S2008, a high voltage is generated from the trigger means 311A if SEL_A is H, and a high voltage is generated from the trigger means 311B if SEL_B is H, and a discharge tube which has received a high pressure from the trigger means. 310A and 310B start light emission. After waiting for a predetermined time in S2009, INT_A and INT_B terminals are set to L in S2010 to start integration. In S2011, a timer for controlling the light emission time of flat light emission is started.
[0051]
After the start of light emission, the sensors 333A and 333B monitoring the discharge tubes 310A and 310B cause a photocurrent to flow according to the light generated by the discharge tubes 310A and 310B, and the output voltages of the light receiving circuits 334A and 334B are output to DA_A and DA_B. When the voltage becomes higher than the control voltage, the outputs of the comparators 331A and 331B are inverted to L level, the IGBTs of the light emission control circuits 312A and 312B are cut off, and the energy accumulated in the coils 308A and 308B is discharged from the discharge tubes 310A and 310B. The current flowing through the discharge tubes 310A and 310B through the diodes 309A and 309B gradually decreases. At the same time, the amount of light emission also decreases, becomes equal to or less than the predetermined light amount, and when the outputs of the receiving circuits 334A and 334B become lower than the values set by DA_A and DA_B, the comparators 331A and 331B are inverted again and become H level, and the light emission control circuits 312A and 312B The IGBT becomes conductive again, and the light generated by the discharge tubes 310A and 310B increases. By repeating the above process, the flat light emission is maintained at a substantially constant light emission intensity.
[0052]
When the elapse of a predetermined time is determined in S2012, the process proceeds to S2013. In S2013, the flash device microcomputer 338 sets the X0 and X1 terminals to L and L, the IGBTs of the light emission control circuits 312A and 312B are forcibly cut off, and the light emission stops. To do.
[0053]
At the end of light emission, INT_A and INT_B terminals are set to H in S2014 and integration is stopped. In S2015, the flash unit microcomputer 338 reads the outputs of the integration circuits 337A and 337B integrating the pre-light emission from the A / D input terminals AD_A and AD_B terminals. , A / D conversion and the value at this time is set to INT_P.
[0054]
If the discharge tube 310A is selected in S2016, the process proceeds to S2017, and if the discharge tube 310B is selected, the process proceeds to S2018.
[0055]
In S2017, the undervalue for the excess is calculated so that the integrated value INT_P becomes INT_P = INT_FULL / N compared to INT_FULLA stored in S1013 of FIG. 10, and the value obtained by adding the correction value to DA_PA is taken as the adjusted DA_PA.
[0056]
In S2018, an over-under amount is calculated so that the integrated value INT_P becomes INT_P = INT_FULLB / N compared with INT_FULLLB stored in S1013 in FIG. 10, and DA_PB after adjustment is added to DA_PB. Write to DA_PA and DA_PB corrected in S2019. The process ends in S2020.
[0057]
In the present embodiment, since the pre-emission light amount adjustment for the full emission uses the integration circuit inside the flash device, there is no need to make an adjustment using an existing external light meter. Of course, it may be adjusted using an existing light meter.
[0058]
Further, the outputs of the DA_A and DA_B terminals are changed as the pre-light emission light amount adjusting means, but the outputs of the light receiving circuits 334A and 334B may be adjusted with the outputs of the DA_A and DA_B terminals kept constant.
[0059]
(Processing during flash)
The light emission processing of the flash device in response to a light emission instruction from the camera when actually taking a picture will be described with reference to the flow of FIG. In response to a light emission instruction from the camera, the flash device starts a light emission process (S3001). In S3002, it is determined whether to perform pre-light emission. If pre-lighting is performed, the process proceeds to S3003. If not, the process proceeds to S3004. In S3003, pre-emission processing is performed and the process proceeds to S3005. In S3004, the main light emission process is performed, and the process proceeds to S3005 after completion. In step S3005, the light emission processing routine ends.
[0060]
(Pre-flat emission process)
Next, the operation at the time of flat light emission as pre-light emission will be described with reference to the flow of FIG. When a pre-emission command is received from the camera microcomputer 100, flat emission processing is started (S3101). In S3102, it is determined whether the discharge tube 310A emits light. If it emits light, the process proceeds to S3103, and if not, the process proceeds to S3106. In S3103, it is determined whether the discharge tube 310B emits light. If light is emitted, the process proceeds to S3104, and if not, the process proceeds to S3108.
[0061]
In S3106, only one lamp of the discharge tube 310B emits light, and the amount of pre-emission is set to DA_PB stored in the storage unit 340 in the DA_B terminal, and the process proceeds to S3107. . In step S3107, the SEL_A and SEL_B terminals of the flash unit microcomputer 338 are set to L and H, and only the discharge tube 310B is allowed to emit light.
[0062]
In S3108, only one lamp of the discharge tube 310A emits light, and the amount of pre-emission is set to DA_PA stored in the storage means 340 in the DA_A terminal, and the process proceeds to S3109.
In S3109, the SEL_A and SEL_B terminals of the flash device microcomputer 338 are set to H and L, and only the discharge tube 310A is allowed to emit light.
[0063]
In S3104, the two lamps of the discharge tubes 310A and 310B emit light, and the pre-emission light amount is the DA value of DA_PA that is one step lower than the DA_PA stored in the storage unit 340 (a value that becomes the pre-emission light amount / 2 of one discharge tube 310A). Is set to the DA_A terminal, and the DA value of DA_PB that is one step lower (the pre-light emission amount of one discharge tube 310B / 2) is set to the DA_B terminal, and the process proceeds to S3105. The emission intensities H3A and H3B of the pre-emission for one lamp are as shown in the pre-emission waveform (3a in FIG. 9) of the discharge tube 310A during two-lamp pre-emission and the pre-emission emission waveform (3b in FIG. 9) of the discharge tube 310B. The light emission intensity is ½ of H1, and the charging voltage of the main capacitor is also a voltage that can emit light as in 3c (dotted line 3c in FIG. 9). Less than do not become.
[0064]
In S3105, the SEL_A and SEL_B terminals of the flash device microcomputer 338 are set to H and H, and light emission of both the discharge tubes 301A and 310B is permitted. In S3110, the data selectors 330A and 330B select the D2 input by outputting L and H to the X0 and X1 terminals. At this time, since the discharge tube is not emitting light, almost no photocurrent flows through the sensors 333A and 333B that are directly monitoring the discharge tube, and the outputs of the comparators 331A and 331B are H and pass through the data selectors 330A and 330B. The IGBTs of the control circuits 312A and 312B are in a conductive state (if SEL_A or SEL_B is L, the Y output of the data selector whose EN terminal is L remains L and the IGBT is nonconductive).
[0065]
By setting the TRIG terminal of the flash unit microcomputer 338 to a predetermined time H in S3111, a high pressure is generated from the trigger means 311A if SEL_A is H, and a high pressure is generated from the trigger means 311B if SEL_B is H, and the discharge tube 310A that has received a high pressure from the trigger means. , 310B starts light emission.
[0066]
Wait for a predetermined time in S3112 . In S3113, INT_A and INT_B terminals are set to L and integration is started. The reason for waiting after outputting the trigger signal in S3112 is to prevent trigger noise from getting on the integrating circuits 317A and 317B.
[0067]
In S3114, a timer for determining the light emission time of flat light emission is started. When the light emission starts, the sensors 333A and 333B monitoring the discharge tubes 310A and 310B cause a photocurrent to flow according to the light generated by the discharge tubes 310A and 310B, and the output voltages of the light receiving circuits 334A and 334B are applied to the DA_A and DA_B terminals. When higher than the output control voltage, the outputs of the comparators 331A and 331B are inverted to L level, the IGBTs of the light emission control circuits 312A and 312B are cut off, and the energy accumulated in the coils 308A and 308B is discharged into the discharge tubes 310A and 310B. The current flowing through the discharge tubes 310A and 310B through the diodes 309A and 309B gradually decreases. At the same time, the amount of light emission decreases, becomes less than the predetermined light amount, and when the outputs of the receiving circuits 334A and 334B become lower than the values set at the DA_A and DA_B terminals, the comparators 331A and 331B are inverted again and become H level, and the light emission control circuits 312A and 312B. The IGBT becomes conductive again, and the light generated by the discharge tubes 310A and 310B increases. By repeating the above process, the flat light emission is maintained at a substantially constant light emission intensity.
[0068]
In S3115, when the light emission time of flat light emission elapses, the process proceeds to S3116. In S3116, the flash device microcomputer 338 sets the X0 and X1 terminals to L and L, the IGBTs of the light emission control circuits 312A and 312B are forcibly cut off, and light emission stops. To do. In S3117, INT_A and INT_B terminals are set to H, and integration is stopped.
[0069]
In S3118, the outputs of the integrating circuits 337A and 337B integrating the pre-light emission are read from the A / D input terminals AD_A and AD_B, A / D converted, and the integrated value, that is, the light emission amount during the pre-light emission is a digital value (INT_PA, INT_PB). Can be read as In step S3119, the pre-flash process ends.
[0070]
(Main flash processing)
The camera microcomputer 100 obtains an appropriate relative value (γ) for the pre-emission of the main emission amount from the subject reflected light luminance value from the multi-division photometry sensor 7 at the time of pre-emission, and sends it to the flash device microcomputer 338 to give an emission instruction. When output, the flash device microcomputer 338 starts main light emission processing. This will be described below with reference to the flowchart of FIG.
[0071]
The main light emission process is started in S3201, and it is determined in S3202 whether or not the discharge tube 310A emits light. If light is emitted, the process proceeds to S3203, and if not, the process proceeds to S3206. In S3203, it is determined whether the discharge tube 310B emits light. If light is emitted, the process proceeds to S3204, and if not, the process proceeds to S3208.
[0072]
In S3206, the main light emission of one discharge tube 310B is performed, and the flash device microcomputer 338 multiplies the photometric integration value (INT_PB) at the time of the pre-light emission by the appropriate relative value (γ) from the camera body to obtain the appropriate integral value (INT_MB). Obtain an appropriate integration value (INT_MB) for DA_B output, and proceed to S3207 . In S3207, the SEL_A and SEL_B terminals of the flash unit microcomputer 338 are set to L and H, and only the discharge tube 310B is allowed to emit light.
[0073]
In S3208, the main light emission of one discharge tube 310A is performed, and the flash device microcomputer 338 multiplies the photometric integration value (INT_PA) at the time of the pre-light emission by the appropriate relative value (γ) from the camera body to obtain the appropriate integral value (INT_MA). Obtain an appropriate integral value (INT_MA) for DA_A output, and proceed to S3209 . In S3209, the SEL_A and SEL_B terminals of the flash device microcomputer 338 are set to H and L, and only the discharge tube 310A is allowed to emit light.
[0074]
In S3204, the main light emission of both the discharge tubes 310A and 310B is performed, and the flash device microcomputer 338 multiplies the DA_A output by the photometric integration value (INT_A) at the time of the pre-light emission and the appropriate relative value (γ) from the camera body. Determine and set the appropriate integral value (INT_MA) of one step drop, and multiply the DA_B output by the photometric integral value (INT_B) at the time of pre-emission and the appropriate relative value (γ) from the camera body. An appropriate integral value (INT_MB) is obtained and set. In S3205, H and H are set to the SEL_A and SEL_B terminals to allow the discharge lamps 310A and 310B to emit light.
[0075]
In S3210, the data selectors 330A and 330B select the D1 input by outputting H and L to the X0 and X1 terminals. At this time, since the discharge tubes 310A and 310B are not emitting light, almost no high current flows through the sensors 335A and 335B that directly monitor the discharge tubes, and the integration circuits 337A and 337B prohibit the integration. The outputs of 332A and 332B are H, and the IGBTs of the light emission control circuits 312A and 312B become conductive through the data selectors 330A and 330B (if SEL_A or SEL_B is L, the Y of the data selector whose EN terminal is L) The output remains L and the IGBT is non-conductive). By setting the TRIG terminal of the flash device microcomputer 338 to H for a predetermined time in S3211, a high voltage is generated from the trigger means 311A if SEL_A is H, and a high voltage is generated from the trigger means 311B if SEL_B is H, and a discharge tube that has received a high pressure from the trigger means. 310A and 310B start light emission. After waiting for a predetermined time in S3212, the INT_A and INT_B terminals of the flash device microcomputer 338 are set to L in S3213, and the integration circuits 337A and 337B start integration. Note that the trigger generation and the integration start timing are shifted because the light emission of the discharge tube is somewhat delayed from the generation of the trigger, and the integration circuits 337A and 337B prevent the integration circuits 337A and 337B from erroneously integrating the noise generated by the trigger. Because. When the integration amount becomes higher than a predetermined control voltage set at the DA_A and DA_B terminals, the outputs of the comparators 332A and 332B are inverted to the L level, and the IGBTs of the light emission control circuits 312A and 312B are cut off and accumulated in the coils 8A and 8B. The generated energy is circulated through the diodes 309A and 309B, the current flowing through the discharge tube is rapidly reduced, and the light emission is stopped.
[0076]
If it is detected in step S3214 that the IN_A and IN_B terminals of the flash device microcomputer 338 are set to L and L and light emission is completed, the process advances to step S3215.
[0077]
In step S3215, the X0 and X1 terminals are set to L and L to completely stop light emission. In step S3216, the INT_A and INT_B terminals are set to H and H to stop the integration. In step S3217, the flash device microcomputer 338 reads the integration outputs of the integration circuits 337A and 337B from the AD_A and AD_B terminals. In step S3218, the main light emission process is stopped. Note that by reading the integral value in S3217, it is possible to detect how much the light emission amount of the flash device actually deviates from the value instructed by the camera. In this way, the main light emission can be controlled to an appropriate light emission amount.
[0078]
Next, an operation flowchart of the flash device camera system embodying the present invention will be described with reference to FIGS. In # 101, when the operation of the camera starts in FIG. 6, the camera microcomputer 100 first detects SW1 that is turned on by the first stroke of the release button. This operation is repeated until SW1 is detected. When SW1 is detected, the process proceeds to the next step (# 101).
[0079]
In # 102, the camera microcomputer 100 obtains subject luminance information of a plurality of areas in the screen by A / D conversion from the above-described photometric circuit 106. Based on this luminance information, a shutter speed and an aperture value used for an exposure operation described later are obtained by calculation. In # 103, the camera microcomputer 100 drives the focus detection circuit 105 to perform a focus detection operation by a known phase difference detection method. As described above, there are multiple points for focus detection (ranging points). Therefore, there are two methods: a method that allows the photographer to set a distance measuring point arbitrarily and a well-known automatic selection algorithm method based on near point priority. There are cases.
[0080]
In # 104, the camera microcomputer 100 adjusts the focus of the lens by communicating with the lens side so that the selected distance measuring point is in focus. Further, the camera microcomputer 100 can obtain the absolute distance information of the lens in-focus position by communication.
[0081]
In # 105, the camera microcomputer 100 determines whether or not the SW2 that is turned on by the second stroke of the release button is ON. If it is OFF, the operation from step 101 to 104 is repeated, and if SW2 is ON, the process proceeds to a release operation after step 106.
[0082]
In # 106, when the release operation is started, first, a light emission amount calculation subroutine of the flash device described later is called. In step # 107, an exposure operation is performed, and the process ends in step # 108.
[0083]
Here, the flash device emission amount calculation subroutine will be described with reference to FIG. In # 201, the camera microcomputer 100 obtains the subject brightness by the photometry circuit 106 immediately before the pre-flash. The brightness value is for each area.
EVa (i) i = 0-18
Is stored in the RAM.
[0084]
In # 202, the camera microcomputer 100 issues a pre-flash command to the flash device side. In accordance with this command, the flash device microcomputer 338 performs the pre-light emission operation as described above.
[0085]
The camera microcomputer 100 obtains the subject brightness by the photometry circuit 106 while the pre-emission flat emission continues. The brightness value is for each area.
EVf (i) i = 0-18
Is stored in the RAM.
[0086]
In # 203, the camera microcomputer 100 extracts the luminance value only for the pre-light-emission reflected light from EVa and EVf.
[0087]
EVdf (i) = EVf (i) -EVa (i) i = 0-18
Is stored in the RAM.
[0088]
In # 204, the camera microcomputer 100 selects a central area in which calculation is performed in order to appropriately control the flash device light amount. There are a method of selecting the area as it is, and a method of selecting the area where the EVdf value indicating the area of the subject close to the camera is maximized. When an area is selected, another area used for weighting calculation described later is selected as shown in FIG. The other areas are adjacent to the central area where the calculation is performed, but are not limited to this area, and may be all remaining areas. In addition, two or more areas may be selected as the central area where the calculation is performed.
[0089]
In # 205, the camera microcomputer 100 calculates and determines the weighting coefficients a and b from the information regarding the distance of the subject. As the information regarding the distance of the subject, the EVdf value of the area selected in # 204 is used. Since EVdf is a luminance value only for the pre-emission reflected light, it is a data regarding the distance such that the EVdf value becomes ¼ when the distance is doubled.
[0090]
FIG. 8 is a graph showing how the weighting coefficients a and b are determined. The coefficient a is a weighting coefficient for the central area where the calculation is performed, and the coefficient b is a weighting coefficient for the other areas.
[0091]
The coefficient a is decreased and the coefficient b is increased as the subject distance is closer and the EVdf value is increased. Conversely, when the distance is increased and the EVdr value is decreased, the coefficient a is increased and the coefficient b is decreased. . However, since the determination of the coefficients a and b is based on a standard shooting operation, for example, when shooting a bounce flash device, a multi-flash device, a wireless flash device or a macro shooting, It is quite possible that the value will change. The distance data may be simply the absolute distance information obtained by the camera microcomputer 100 communicating with the lens in # 104.
[0092]
In # 206, the camera microcomputer 100 calculates an appropriate flash device light amount for each of the selected areas to be weighted averaged.
[0093]
P = {TGT-EVa (i)} / EVdf (i)
TGT: Proper exposure
EVa: subject brightness due to external light
EVdf: luminance of pre-emission reflected light only
P: Flash device light amount appropriate for each area
Then, P (P1) of the selected center area and P (P2) of the other areas are obtained by a simple average based on the value of P of each area (average if there is one selected center area) But it is the value itself).
[0094]
Furthermore, a weighted average is performed according to the following formula.
[0095]
Wave = a × P1 + b × P2 (both a and b ≦ 1)
In # 207, the camera microcomputer 100 performs an operation for converting the value of Wave into an appropriate relative value (γ), and sends the value of γ to the flash device side by communication. Here, the flash device emission amount calculation subroutine is completed, and the flow returns to FIG.
[0096]
In # 107, the camera microcomputer 100 performs an exposure operation. That is, the main mirror 2 is raised and both the sub mirror 25 are moved away from the photographing optical path, the lens is controlled to control the aperture, and the shutter control circuit 107 is controlled so that the determined shutter speed value (TV) is obtained. At this time, the SWX is turned ON in synchronization with the fully open shutter, and is transmitted to the flash device side, which becomes the main light emission command. The flash device microcomputer 338 performs the main light emission control as described above to an appropriate amount based on γ sent from the camera.
[0097]
Finally, the main mirror 2 and the like moved away from the photographing optical path are lowered and inclined to the photographing optical path again, and the film is wound up by one frame by the motor control circuit 108 and the film running detection circuit 109.
[0098]
In the flash device having M (M = 2) discharge tubes according to the present invention, when pre-emission is performed with M discharge tubes, each discharge tube emits light when each discharge tube emits full light / (M × It is possible to perform pre-emission with the light quantity of N).
[0099]
(Second Embodiment)
The configuration of the camera flash device system of the second embodiment of the present invention is the same as that of the first embodiment of FIGS. 1, 2, and 3, and the operation on the camera side is also the same as that of the first embodiment. The light amount adjustment of the pre-light emission which is the difference will be described with reference to FIGS.
[0100]
In the first embodiment, the light emission amount of the pre-light emission of the discharge tubes 310A and 310B is adjusted to be 1 / N of the full light emission of each of the discharge tubes 310A and 310B. However, in this embodiment, the discharge tube The light amounts of the discharge tubes 310A and 310B are adjusted so as to be 1 / N when both A and the discharge tube B emit full light simultaneously. The following will be described in order.
[0101]
(Full emission intensity)
A process in the case where the discharge tubes 310A and 310B are made to emit full light simultaneously will be described with reference to the flow of FIG. In S1102, maximum values are set in the DA_A and DA_B terminals of the flash device microcomputer 338. In S1103, H and H are set in the SEL_A and SEL_B terminals to allow the discharge lamps 310A and 310B to emit light. In S1104, H and L are set to the X0 and X1 terminals to cause the data selectors 330A and 330B to select D1. In S1105, H is output to the TRIG terminal for a predetermined time to generate a high voltage from the trigger means 311A and 311B, and light emission of the discharge tubes 310A and 310B is started. In step S1106, the process waits for the time for which full light emission ends. In step S1107, the X0 and X1 terminals are set to L and L, the IGBTs of the light emission control circuits 312A and 312B are cut off, and light emission is completely stopped. The full light emission quantity at this time is measured using an existing light quantity meter and is set as MAX_FL.
[0102]
(Pre-light intensity)
The operation of adjusting the pre-emission light amount is almost the same as the flow of FIG. 11 of the first embodiment. The difference is that the pre-emission amount of each discharge tube is measured using an existing light meter and the pre-emission light amount is determined. In the calculation of DA_PA in S2017 of FIG. 11 using PA_FL and PB_FL, a correction value is added to DA_PA so that the pre-emission light amount PA_FL becomes MAX_FL / N from the measured pre-emission light amount PA_FL, and the corrected DA_PA is calculated. In the calculation of DA_PB in S2018, a correction value is added to DA_PB so that the pre-light emission amount becomes MAX_FL / N from the measured pre-light emission amount PB_FL, and DA_PB after correction is calculated.
[0103]
In the flash device having M (M = 2) discharge tubes according to the above-described embodiment, when pre-emission is performed with M discharge tubes, the amount of light when each discharge tube is fully lit with M discharge tubes / (M × N) light can be pre-flashed.
[0104]
(Third embodiment)
The configuration of the camera flash device system of the third embodiment of the present invention is the same as that of FIGS. 1, 2, and 3, and the operation on the camera side is also the same as that of the first embodiment. The operation of the flash device during photographing, which is a difference, will be described below.
[0105]
FIG. 16 is a flowchart of the pre-light emission operation of the third embodiment. The difference from the pre-light emission operation flow diagram 13 in the first embodiment is set in the DA_A and DA_B terminals in S3304, S3306, and S3308. When calculating the value to be calculated, if the charging voltage of the main capacitor 3 before the pre-light emission is monitored at the ADI terminal of the flash device microcomputer 338, the voltage correction amount (VCOMP) is added if it is less than full charge,
In S3306
DA_B = DA_PB + VCOMP
In S3308
DA_A = DA_PA + VCOMP
In S3304
DA_A = DA_PA-1 stage + VCOMP
DA_B = DA_PB-1 stage + VCOMP
As a pre-light emission amount is lowered.
[0106]
For voltage correction (VCOMP (number of stages)), assuming that the full charge voltage is VMAX and the voltage before pre-emission is Vp
VCOMP = Log ₂ (Vp ² / VMAX ² )
The correction amount may be referred from a table corresponding to the charging voltage.
[0107]
Next, a flowchart of processing during main light emission will be described with reference to FIG. The main light emission processing of the first embodiment is different from that of FIG. 14 in S3404, S3406, and S3408. When the values set in the DA_A and DA_B terminals at the time of main light emission are calculated, the voltage correction amount (VCOMP) calculated at the time of pre-light emission is calculated. To reduce the amount of pre-emission light.
[0108]
In S3406
DA_B = γ × INT_PB + VCOMP
In S3408
DA_A = γ × INT_PA + VCOMP
In S3404
DA_A = γ × INT_PA + 1 stage − VCOMP
DA_B = γ x INT_PB + 1 stage-VCOMP
The main light emission amount is determined as follows.
[0109]
According to the above embodiment, in the flash device having M (M = 2) discharge tubes, when pre-emission is performed with M discharge tubes, each discharge tube is set according to the charging voltage of the main capacitor. It is possible to perform pre-light emission with a light amount of full light emission / (M × N) light amount.
[0110]
【The invention's effect】
As described above, even when pre-light emission is performed with a plurality of light emitting means, pre-light emission is performed with one light emitting means When Almost the same energy is consumed from the main capacitor, and the main capacitor charge voltage is the voltage that can be emitted during main light emission. Less than It is possible to prevent the main light emission from becoming impossible.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a flash device camera system embodying the present invention.
FIG. 2 is an electric circuit block diagram of a camera body of a flash device camera system embodying the present invention.
FIG. 3 is an electric circuit block diagram of the flash device of the flash device camera system embodying the present invention.
FIG. 4 is a screen division diagram of a photometry circuit of a flash device camera system embodying the present invention.
FIG. 5 is a diagram showing an area selection table for performing weighted averaging of the flash device camera system embodying the present invention.
FIG. 6 is a flowchart of the flash device camera system according to the first embodiment of the present invention.
FIG. 7 is a flowchart of the flash device camera system according to the first embodiment of the present invention.
FIG. 8 is a diagram showing a determination graph of weighting coefficients.
FIG. 9 is a diagram showing a flash waveform of pre-light emission and a charging voltage of a main capacitor in the conventional example and the present invention.
FIG. 10 is a flowchart showing a full light emission operation of each discharge tube during adjustment of the first embodiment of the present invention.
FIG. 11 is a flowchart showing a pre-light emission operation during adjustment according to the first and second embodiments of the present invention.
FIG. 12 is a flowchart showing a light emission operation at the time of photographing by the flash device embodying the present invention.
FIG. 13 is a flowchart showing a pre-light emission operation at the time of photographing by the flash device embodying the present invention.
FIG. 14 is a flowchart showing a main light emission operation at the time of photographing by the flash device embodying the present invention.
FIG. 15 is a flowchart showing a full light emission operation of all the discharge tubes during adjustment according to the second embodiment of the present invention.
FIG. 16 is a flowchart showing the pre-light emission operation of the third embodiment of the present invention.
FIG. 17 is a flowchart showing an operation of main light emission according to the third embodiment of the present invention.
[Explanation of symbols]
100 camera microcomputer
303 Main capacitor
304,305 Voltage divider resistance
308A, 308B Current limiting coil
310A, 310B Discharge tube
338 Flash device microcomputer

Claims (10)

A flash device that performs pre-flash prior to main flash during flash photography,
A main capacitor for storing electrical energy;
A plurality of light emitting means for emitting light using electrical energy stored in the main capacitor;
A light emission control means for controlling the pre-emission light quantity at the time of pre-emission of the light emitting means ,
The light emission control means emits light in accordance with an increase in the number of light emission means that emit light during pre-light emission so that the charging voltage of the main capacitor does not become less than the charging voltage required for performing main light emission. A flash device characterized in that the pre-emission light quantity at the time of pre-emission of the light emitting means is reduced . When the number of the light emitting means that emit light at the time of pre-emission is singular, the light emission control means sets the pre-emission light quantity to 1 / N of the full emission quantity when the light emitting means emits a single light, and emits light at the time of pre- emission. The number of the light emitting means to be emitted is a plurality of light emitting means, and a light quantity obtained by combining the pre-light emission quantity of the light emitting means to emit light is set to 1 / N of the full light emission quantity. The flash device described. When the number of the light emitting units that emit light at the time of pre-emission is singular, the light emission control unit sets the pre-emission light amount to 1 / N of the total light emission amount when the light emitting unit emits a plurality of lights. When the number of the light emitting means that emit light at the time of pre-emission is plural, the combined light quantity of the pre-emission light quantity of the light emitting means that emits light is 1 / N of the full light emission quantity when the light emitting means emits a single light. The flash device according to claim 1, wherein a light amount is set. When the number of the light emitting means that emit light at the time of pre-emission is singular, the light emission control means sets the pre-emission light quantity to 1 / N of the full emission quantity when the light emitting means emits a single light, and emits light at the time of pre- emission. When the number of the light emitting means to be emitted is plural, the total light quantity of the pre-emission light quantity of the light emitting means to emit light is 1 / N of the total light quantity when the light emitting means is made to emit a plurality of light. The flash device according to claim 1, wherein a light amount is set. When the number of the light emitting units that emit light at the time of pre-emission is singular, the light emission control unit sets the pre-emission light amount to 1 / N of the total light emission amount when the light emitting unit emits a plurality of lights. When the number of the light emitting means that emit light at the time of pre-light emission is plural, the light quantity that is combined with the pre-light emission quantity of the light emitting means that emits light is 1 / N of the light quantity that is combined with the full light emission quantity. The flash device according to claim 1.   6. The flash device according to claim 2, wherein the full light emission is a full light emission corresponding to a voltage state of the main capacitor at the time of light emission.   6. The flash device according to claim 2, wherein full light emission is full light emission when the voltage of the main capacitor during light emission is in a fully charged state. 8. The flash device according to claim 1, wherein when the number of the light emitting units that emit light at the time of pre-light emission is plural, the pre-light emission amounts of the light emitting units that emit light are equal to each other. 9. An imaging device that performs pre-flash prior to performing main flash during flash photography,
A main capacitor for storing electrical energy;
A plurality of light emitting means for emitting light using electrical energy stored in the main capacitor;
A light emission control means for controlling the pre-emission light quantity at the time of pre-emission of the light emitting means ,
The light emission control means emits light in accordance with an increase in the number of light emission means that emit light during pre-light emission so that the charging voltage of the main capacitor does not become less than the charging voltage required for performing main light emission. An imaging apparatus, wherein the pre-emission light amount at the time of pre-emission of the light emitting means is reduced . Have a plurality of light emitting means for emitting light using the electrical energy stored in the same main capacitor, a light emission control method of the flash apparatus which performs pre-emission prior to performing the main emission during flash photography,
In order to prevent the charging voltage of the main capacitor from becoming less than the charging voltage required for main light emission, the pre-emission of the light emitting means to emit light as the number of the light emitting means to emit light during pre-emission increases. A light emission control method for a flash device, characterized in that the amount of pre-light emission during light emission is reduced .

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