JPH0961904A - Stroboscopic control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a stroboscopic control system which adequately controls a flash emitted light quantity by calculating the emitted light quantity of normal light emission in accordance with the exposure and proper exposure value at preliminary light emission. SOLUTION: An MPU 100 determines the proper integrated value of the normal emitted light quantity from the integrated value of the preliminary light emission and the luminance value of the light reflected from a subject of a multidivision photometric sensor 7 at the time of the preliminary light emission, etc., and sets this proper integrated value in a D/A converter 20 via stroboscope light circuit 200. An integrating circuit 211 is set in an initial state and starts light emission by a trigger circuit 203. The light emission luminance of a xenon tube 19 measured by a monitor sensor 32 is integrated by this integrating circuit 211. The output of a comparator 205 switches from HI to LOW and the light emission is stopped by a light emission stopping circuit 204 when the integrated output attains the set proper integrated value. The emitted light quantity of the normal light emission is thus controlled to the proper emitted light quantity determined by the calculation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a strobe control system for performing an exposure operation by adjusting a light emission amount so that a proper light exposure is automatically obtained by emitting light toward a subject.

[0002]

2. Description of the Related Art Heretofore, various strobe control camera systems have been proposed which perform an exposure operation by adjusting a light emission amount so as to automatically obtain a proper exposure by emitting light toward a subject, and reach a film surface at the time of exposure. The so-called TT that obtains an appropriate amount of light by measuring the reflected light on the film surface
L dimming is common.

FIG. 9 shows a conceptual diagram of an optical system for TTL light control. The subject image is taken from the film surface 9 by the taking lens 32.
Is imaged and exposed. The main mirror 2 is retracted to a position higher than the position shown in the figure at the time of exposure, but is tilted as shown in the figure at the time of observation before the exposure, and the photographing lens 32 is placed on the focusing plate 3.
To form an image plane. Reference numeral 4 denotes a penta roof prism, which provides a viewfinder image of the subject image formed on the focusing plate 3.
The optical path is changed so that the observer looking from the inside looks like a regular positional relationship.

Denoted at 23 and 24 are an imaging lens and a dimming sensor for measuring the light reflected on the film surface at the time of exposure. The strobe light emission at the time of exposure is measured by the dimming sensor 24 to reach a predetermined amount. If it is determined that the strobe light is emitted, the strobe light emission is stopped and the emission amount is controlled.

Further, in performing the above-mentioned TTL dimming, a system is known in Japanese Patent Laid-Open No. 4-331935, in which a strobe is preliminarily emitted before exposure to correct the TTL dimming during main light emission.

[0006]

However, the above T
Since the TL light control system uses diffused reflected light from the film surface, it has a drawback that the exposure is not stable because the reflectance differs depending on the type of film.

Further, in the conventional flash of the preliminary light emission system, the preliminary light emission amount is set to a predetermined value. For example, when the charging voltage of the capacitor for light emission is different, the preliminary light emission amount is actually different from the expected value. If it is different, the amount of light emitted during main flashing will be different and the exposure value will change, and if the predetermined preliminary flash is performed when the charge capacity is low, sufficient light emission energy during main flashing will not be obtained. There was a flaw. Further, since the preliminary light emission is emitted by a predetermined amount regardless of the state of the subject, there is a drawback that the preliminary light emission is dazzling and is not easy for a person to be photographed, such as when the subject is a person in a dark place and close to the camera.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in view of the above matters, and in a first aspect, in a strobe control system for performing preliminary light emission before main light emission at the time of shooting,
Photometric means for photometrically measuring the light reflected from the subject due to preliminary light emission, and arithmetic means for obtaining the luminescence amount data in the main flash based on the first photometric data and exposure data corresponding to the photometric value detected by the photometric means. There is provided a strobe control system which calculates the light emission amount of main light emission based on the exposure amount of the preliminary light emission and the appropriate exposure value, and performs appropriate flash light emission amount control.

In the second and third aspects, the appropriate exposure amount is
(EN) Provided is a strobe control system for performing appropriate flash light emission amount control using brightness information or a control aperture value and an exposure value assumed by shutter speed.

In the fourth to sixth aspects, the light emission amount of the main light emission is obtained based on the difference or ratio between the exposure value in the preliminary light emission and the proper exposure value, or based on the ratio and the flash light emission amount in the preliminary light emission. (EN) Provided is a strobe control system for performing an appropriate flash light emission amount control.

According to a seventh aspect of the present invention, there is provided a strobe control system for performing proper flash light emission amount control by causing main light emission until the actual light emission amount reaches a value according to the calculated flash light amount. is there.

According to an eighth aspect of the present invention, in a strobe control system for performing main light emission toward an object and performing an exposure operation, there is provided means for performing preliminary light emission toward the object, and the light reflected from the object is measured during the preliminary light emission. And a second photometric means for measuring the preliminary light emission amount from an optical path different from the first photometric means at the time of the preliminary light emission, and a photometric value by the first photometric means. According to the above, it has a calculation means for calculating a relative main light emission amount with respect to the preliminary light emission amount measured by the second light measurement means, and in the main light emission,
Provided is a strobe control system for performing proper flash light emission amount control by controlling the main light emission amount based on the calculation result by the calculation unit by measuring the main light emission amount by the second light measuring unit.

According to the ninth and the seventeenth aspects, the preliminary light emission is performed by the flat light emission to obtain appropriate photometric value data. A strobe control system for performing main light emission toward an object and performing an exposure operation according to claim 11, further comprising means for performing preliminary light emission toward the object, and first light metering means for measuring reflected light from the object during the preliminary light emission. And a means for detecting a predetermined state of the camera system, wherein the light amount of the preliminary light emission is varied according to the predetermined state, and the main light emission amount is changed according to the photometric value by the first photometric means. When the main light emission is performed, the main light emission amount is controlled on the basis of the calculation result by the calculation means to obtain the main light emission amount after optimizing the preliminary light emission.
It is intended to provide a strobe control system for performing appropriate preliminary light emission.

According to the twelfth to fourteenth and sixteenth aspects of the present invention, there is provided a strobe control system which determines the preliminary light emission amount based on the charge value of the main capacitor, the subject brightness value or the subject distance value to optimize the preliminary light emission amount. is there.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a cross-sectional view mainly illustrating the optical configuration of a strobe control camera system implemented by applying the present invention to a single-lens reflex camera.

Reference numeral 1 denotes a camera body, in which optical parts, mechanical parts, electric circuits, films and the like are housed so that a picture can be taken. Reference numeral 2 denotes a main mirror which is inclined or retreated to a photographing optical path according to an observation state and a photographing state. Also, when the main mirror 2 is a half mirror and is inclined, the main mirror 2 transmits about half of the light beam from the subject to a focus detection optical system described later. Reference numeral 3 denotes a focusing plate arranged on a predetermined image forming plane of the photographing lenses 12 to 14, 4 denotes a pentaprism for changing a finder optical path, 5 denotes a finder, and a photographer observes the focusing plate 3 from this window to obtain a photographing screen. Can be observed. Reference numerals 6 and 7 denote an image forming lens and a multi-division photometric sensor (photometric means) for measuring the brightness of the subject in the observation screen, and the image forming lens 6 is multi-division with the focusing plate 3 via the reflection optical path in the penta roof prism 4. The photometric sensor 7 is associated with the conjugate.

Now, the function of the multi-division photometric sensor 7 will be described in detail. FIG. 2 shows a photometric area division diagram on the photographing screen. Numeral 40 represents the entire photographing screen. Reference numeral 41 denotes an area division for photometry on the photographing screen of the multi-segment photometric sensor 7, which divides the photographing screen into six areas such as E0, E1, E2, E3, E4, and E5. The multi-segment photometric sensor 7 associated with the photographic screen in this manner can divide the photographic screen, measure the respective brightness values, and output it.

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 inclined, it transmits about half of the light rays from the subject. Reference numeral 25 denotes a sub-mirror which bends a light beam from a subject downward and guides it toward the focus detection unit 26.

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. A secondary imaging mirror 27 and a secondary imaging lens 28 form a focus detection optical system, and a secondary imaging surface of the imaging optical system is connected to a focus detection line sensor 29. The focus detection unit 26 detects the focus state of the subject in the photographic screen by a known phase difference detection method by the processing of an electric circuit described later, and realizes an automatic focus detection device by controlling the focus adjustment mechanism of the photographic lens. ing.

This automatic focus detection device detects the focus state of three predetermined points on the screen. FIG. 2 shows the positions of the three points. The distance measuring points P0, P1 and P2 are the positions.

Reference numeral 10 is a mount contact which serves as an interface between a known camera and a lens, and 11 is a lens barrel mounted on the camera body. Reference numerals 12 to 14 denote photographing lenses, and 12 denotes a first group lens, which can be moved left and right on the optical axis to adjust the focus position of the photographing screen. Reference numeral 13 denotes a two-group lens, which is movable left and right on the optical axis, thereby changing the magnification of the photographing screen and changing the focal length of the photographing lens. Reference numeral 14 is a third group fixed lens. Reference numeral 15 is a photographic lens diaphragm.

Reference numeral 16 is a first group lens driving motor,
The focus position can be automatically adjusted by moving the first lens group 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 close the photographing lens diaphragm.

Reference numeral 18 denotes an external strobe, which is attached to the camera body 1 and controls light emission in accordance with a signal from the camera. A xenon tube 19 as a flash tube converts current energy into luminescence energy. Reference numerals 20 and 21 denote a reflection plate and a Fresnel lens, respectively, which serve to efficiently collect light emission energy toward a subject. 22
Is a known contact point that serves as an interface between the camera body 1 and the external strobe 18.

Reference numeral 30 is a glass fiber as a light transmitting means, which guides the light emitted from the xenon tube 19 to a monitor sensor (PD1) 31. Sensor (PD1) 3
Reference numeral 1 directly measures the amount of light for preliminary flash emission and main flash emission. A sensor (PD2) 32 also monitors the light emitted from the xenon tube 19. The light emission current of the xenon tube 19 is limited by the output of the sensor (PD2) 32, and the strobe can perform flat light emission.

In FIG. 1, among the members necessary for realizing the present invention, only the optical mechanical member is shown, and an electric circuit member is necessary in addition to these, but it is omitted here. FIG.
An electric circuit block diagram of a strobe control camera system embodying the present invention is shown in FIG. Members corresponding to those in FIG. 1 are designated by the same reference numerals.

The MPU is internally operated by a processing circuit such as a microcomputer based on a clock generated by the oscillator 101.

The EEPROM 100b can store film information such as a film counter. A / of 100c
D (analog / digital converter) is the focus detection circuit 10
5. The analog signal from the photometry circuit 106 is A / D converted, and the MPU sets various states by signal processing the A / D value.

The MPU 100 includes 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 sense circuit 110, and an LCD drive circuit 111 are connected. In addition, a signal is transmitted to the lens control circuit 112 arranged in the photographing lens via the mount contact 10, and a signal is transmitted to the external strobe from the strobe control circuit 200 via the contact shoe 22. .

The line sensor 29 is a known CCD line sensor composed of three sets of line sensors Line-L, Line-C, and Line-R corresponding to the three distance measuring points on the finder as described above. The focus detection circuit 105 controls accumulation and reading of these line sensors 29 according to the signal of the MPU 100, and outputs pixel information of each to the MPU 100. MPU100
Performs A / D conversion of this information and performs focus detection by the well-known phase difference detection method.

The MPU 100 adjusts the focus of the lens by exchanging signals with the lens control circuit 112 according to the focus detection information.

The photometric circuit 106 outputs to the MPU 100 the output from the multi-division photometric sensor 7, which divides the screen into six areas as described above, as the luminance signal of each area in the screen. The photometric circuit 106 outputs a luminance signal in both a steady state in which the flash light is not preliminarily emitted toward the subject and a preliminary light emission state in which the preflash is emitted, and the MPU 1
00 performs A / D conversion of the luminance signal, calculates the aperture value for adjusting the exposure of photographing, the shutter speed, and the strobe main light emission amount at the time of exposure.

The shutter control circuit 107 uses the MPU 10
According to the signal from 0, the shutter front curtain (MG-1),
It is responsible for the exposure operation by running the shutter rear curtain (MG-2).

The motor control circuit 108 controls the motor in accordance with the signal from the MPU 100 to raise / lower the main mirror 2, charge the shutter, and feed the film.

The film running detection circuit 109 detects whether the film is wound up by one frame at the time of feeding the film,
Send a signal to the MPU 100.

SW1 is a switch which is turned on by the first stroke of a release button (not shown) to start photometry and AF.
SW2 is a switch that is turned on by the second stroke of the release button to start the exposure operation. Signals from SW1, SW2 and other operation members of the camera (not shown) are detected by the switch sense circuit 110 and sent to the MPU 100.

The liquid crystal display circuit 111 is an LC in the viewfinder.
Display the D24 and the LCD 42 for monitoring (not shown) on the MPU
It controls according to the signal from 100.

The lens control circuit 112 communicates with the MPU 100 through the lens mount contact 10 to operate the first group lens drive motor 16 and the lens diaphragm motor 17 to control the focus adjustment and diaphragm of the lens. Reference numerals 35 and 36 are a photodetector and a pulse plate, and the lens control circuit 112 can obtain the positional information of the first group lens by counting the number of pulses, and the focus of the lens can be adjusted. Further, the absolute distance information of the subject is transmitted to the MPU 100 from the position information of the first group lens.

The strobe control circuit 200 is a circuit for emitting strobe light toward a subject in accordance with a signal from the MPU 100, and can control the amount of light emission, the peak value of flat light emission, and the light emission time.

Reference numeral 201 denotes a DC / DC comparator as a boosting circuit, which can boost the battery voltage according to an instruction from the strobe control circuit 200 and store about 300 V in the main capacitor C1. R1 / R2 is the main capacitor C
1 is a voltage dividing resistor provided for the strobe control circuit 200 to monitor the voltage of 1. Strobe control circuit 200
The A / D converter 202 converts the divided voltage into A / D
By converting the voltage of C1 indirectly,
The DC / DC converter 201 is made non-differential to stop boosting, monitor the current charging voltage,
Can be communicated to. Reference numeral 203 is a trigger circuit for exposure M
The PU 100 outputs a trigger through the strobe control circuit 200 to generate a high voltage in the xenon tube 19 and the charge energy stored in the main capacitor C1 is discharged through the xenon tube 19 to cause the strobe to emit light. Let it start. 204 is a light emission stop circuit,
When the trigger is output, the light emission is started and the light emission is started.
After that, the light emission of the xenon tube 19 is stopped. Next, the circuit will be described while explaining each operation of the strobe.

<Flat light emission> Strobe control circuit 200
Is a D / A converter (digital / analog converter) 207
Set a predetermined value to. At this time, since the xenon tube 19 has not yet started to emit light, the photocurrent of the monitor sensor 32 (PD2) is small and the output of the monitor circuit 209 input to the inverting input terminal of the comparator 206 is low. Therefore, the comparator 206 outputs HI to the light emission stop circuit 204.

When the trigger is output, the xenon tube 1
9 starts emitting light, and immediately the peak value of the light emission rises, the photocurrent of the monitor sensor 32 (PD2) increases, and the monitor circuit 2
09 output rises and comparator 206 output goes LO
W. When the output of the comparator 206 becomes LOW, the light emission stop circuit 204 operates and the discharge loop of the xenon tube 19 is cut off, but the diode D1 and the coil L1 form a circulation loop, and the peak value does not drop instantaneously and gradually. Falling down. When the peak value drops, the monitor sensor 3
Since the photocurrent of 2 (PD2) decreases, the output of the comparator 206 turns to HI again, the discharge loop of the xenon tube 19 is formed, and the peak value rises. In this way, the output of the comparator 206 repeatedly increases and decreases the crest value in a short cycle, and as a result, it is possible to control the flat light emission in which the light emission is continued at a substantially constant crest value.

To terminate the flat emission, the strobe control circuit 200 directly outputs a signal to the emission stop circuit 204. In addition, the peak value of the flat light emission is changed by changing the voltage input to the non-inverting input terminal of the comparator 206 according to the digital value given to the D / A converter 207.
The operation point of the photocurrent of 2) can be changed and controlled to a desired value. The light emission time can also be controlled to a desired time.

<Preliminary Light Emission and Integration> In the preliminary light emission, the above-described flat light emission is performed at a predetermined peak value for a predetermined time. At this time, the monitor sensor 31 (PD1) is measuring the emission photometric brightness of the xenon tube 19, the strobe control circuit 200 instructs the integration circuit 211 to start integration, and the integration circuit 211 reserves the output from the monitor circuit 210. Start the integration of luminescence. The light emission stop circuit 204 has a comparator 205 to which the output of the integration circuit 211 is input to the inverting input terminal.
Although the output of is input, this is the strobe control circuit 2
It is set to be ignored by a signal from 00, so that the above-mentioned control of flat light emission is not hindered.

When the preliminary light emission for a predetermined time ends, the strobe control circuit 200 A / D-converts the output of the integration circuit 211, which integrates the preliminary light emission, by the A / D converter 202, and reads the integrated value as a digital value. I can.

<Main Light Emission Control> The MPU 100 has the above-mentioned integrated value of the preliminary light emission, and the multi-division photometric sensor 7 at the time of the preliminary light emission.
The proper integrated value of the main light emission amount is obtained from the subject reflected light brightness value and the like, and the proper integrated value is set in the D / A converter 207 via the strobe control circuit 200. Integrating circuit 21
1 is set to the initial state, and the trigger circuit 203 starts light emission. The light emission brightness of the xenon tube 19 measured by the monitor sensor 31 (PD1) is integrated by the integration circuit 211, and when the integrated output reaches the set proper integrated value, the output of the comparator 205 switches from HI to LOW and the light emission is stopped. Light emission is stopped by the circuit 204. At this time, the output of the comparator 206 is set to be ignored by the signal from the strobe control circuit 200. In this way, it is possible to control the light emission amount of main light emission to an appropriate light emission amount calculated.

Next, the operation flow of the strobe control camera system embodying the present invention will be described with reference to FIGS. 5 and 6. FIG. 5 is a flow mainly illustrating the operation of the MPU 100, and FIG. 6 is a flow explaining the arithmetic processing. First, FIG.
When the operation of the camera is started at, the MPU 100 first detects SW1 which is turned on by the first stroke of the release button (# 01). This operation is repeated until SW1 is detected, and when SW1 is detected, the next operation is performed.

In step (# 02), the MPU 100 reads various operation switches of another camera (not shown) from the switch sense circuit 110 and sets various shooting modes such as how to determine the shutter speed and how to determine the aperture.

In step (# 03), focus detection operation is performed. This is due to the well-known phase difference detection method by the focus detection circuit 105 as described above. The MPU 100 controls the lens control circuit to adjust the focus of the lens according to the focus state by the focus detection operation. As described with reference to FIG. 2, there are three points for focus detection on the screen, but which of these points the subject should be focused on may be set arbitrarily by the photographer, or the near point priority is the basic method. A well-known automatic selection algorithm method based on the idea may be used.

In step (# 04), the MPU 100 obtains the subject brightness values of the six areas on the screen from the photometric circuit 106.

In step (# 05), the MPU 100 determines the exposure amount according to a known algorithm from the subject brightness values in the six areas, and determines the shutter speed value and the aperture value according to the set photographing mode. Next, in step (# 06), it is determined whether or not SW2 which is turned on by the second stroke of the release button is turned on. O
If it is FF, the process returns to step (# 01) and (# 0
The operations from 1) to (# 06) are repeated. SW2 is ON
If so, the operation proceeds to # 07 and thereafter.

In step (# 07), the MPU 100 obtains the charging voltage information of the current strobe main capacitor C1 by the information transmission from the strobe control circuit 200, and the absolute information from the camera of the subject by the information transmission from the lens control circuit 112. The distance information is obtained, and the subject brightness information from the photometric circuit 106 is obtained.

In step (# 08), the MPU 100 determines the amount of preliminary light emission based on the obtained charging voltage information, absolute distance information, and subject brightness information. The amount of light emission is determined such that, for example, the higher the charging voltage, the longer the distance, and the brighter the brightness, the greater the amount of light emission. Step again (# 0
Perform photometry as in 4).

In step (# 09), the MPU 100 issues a command to the strobe control circuit 200 to control the preliminary light emission so that the determined preliminary light emission amount is achieved. In the preliminary light emission, the preliminary light emission by the flat light emission described above is performed, and as the preliminary light emission amount determined in step (# 08), the peak value of the flat light emission, that is, the non-inverting input terminal of the comparator 206 is used for the above step ( The value corresponding to the light emission amount determined in # 08) is set so that the larger the light emission amount is, the larger the value becomes. Further, this preliminary light emission operation is stopped when the issuance stop circuit 204 is activated by a signal from the strobe control circuit 200 after a lapse of a predetermined time, and the subsequent light emission is prohibited.

In step (# 10), M is emitted at the same time as preliminary light emission.
The PU 100 uses the multi-division photometric sensor 7 to measure the reflected light of the subject caused by the preliminary light emission. Further, during the preliminary light emission, the strobe control circuit 200 measures the direct light of the xenon tube 19 with the monitor sensor 31 (PD1), integrates it with the integrating circuit 211, and when the preliminary light emission ends, the integrated value is A / D. Convert and read.

In step (# 11), the MPU 100 calculates the proper integral value of the main light emission from the integral value of the preliminary light emission, the subject reflected light photometric value of the preliminary light emission, the exposure value and the like.

In step (# 12), the main mirror 2 is raised and both the sub-mirror 25 and the sub-mirror 25 are moved out of the photographing optical path prior to the exposure operation.

In step (# 13), the MPU 100 issues a command to the lens control circuit 112 so that the aperture value is based on the determined exposure amount, and drives the shutter control circuit 107 so that the shutter speed value is determined. Control by doing.

In step (# 14), the strobe control circuit causes the strobe main light emission to be performed during the exposure according to the driving of the shutter (the main light emission is started in synchronization with the turning on of the X contact when the shutter front curtain has finished traveling). Controlled by 200. This main light emission is controlled to the light emission amount obtained by the calculation in step (# 11).

When the exposure operation is completed in this way, step (#
In 15), the main mirror 2 and the like, which have been moved away from the shooting optical path, are moved down to be obliquely installed again in the shooting optical path, and the motor control circuit 108
By the film traveling detection circuit 109, one frame of film is wound and the operation of the strobe control camera system of the present invention is completed.

Next, referring to FIG. 6, an arithmetic expression and a flow of the calculation of the proper main light emission amount and the calculation of the preliminary light emission amount, which are the points of the strobe control camera system of the present invention, will be described. The step (S01) corresponds to the step (# 04) in the flow of FIG. 5, and the subject brightness under natural light is measured and the weighted average of the six areas is taken.

[0062]

[Outside 1] W (i), which is a weighting coefficient, depends on the metering mode of the flash main flash control and the distance measuring point of automatic focus detection.
It changes and is set as shown in FIG. 10, for example. According to FIG. 10, when the light metering mode of the main flash emission control is weighted average light metering, the weighted average is obtained by weighting the distance measurement points for automatic focus detection. When the metering mode is partial metering, the weighting coefficient is applied only to the area including the distance measuring points, and the weighted average is calculated with all other areas set to 0. As a result, EVb of one area is calculated.
(I) is EVb as it is.

When weighted averaging is performed, the LOG-compressed value EVb (i) of the brightness value of each area is expanded by taking a power of 2 and expanded, and the weighted average is obtained, and finally 2
It is LOG compressed at the bottom.

More specifically, in FIG. 10, i (0 to 0
5) is each area Ei (0 to 5) of the multi-division photometric sensor 7
Is represented. Since focus adjustment by autofocus is performed in step (# 03) before this step is executed, the distance measuring point has already been determined. (For example, in the case of automatic selection, one of P0 to P2 is determined based on a predetermined algorithm, and when manually set, one of P0 to P2 is determined by the photographer's intention.) In step S01,
Using the determined distance measuring point as a factor, the photometric output EVb (i) (i is 0 to 5) in each area is weighted with respect to each area Ei.

For example, the distance measuring point is automatically selected, or
If P0 is selected as a distance measuring point by manual selection, the weighting of the photometric area E0 at that point is set to 7, the area E1 adjacent to the area E3 is 3, the area E2 adjacent to the area E1 is 1, and E3 is 3, Other areas are weighted to 1. Then, the weighted average photometric value EVb is obtained.

If the metering mode for strobe main flash control is set to partial metering, the metering value for one area of the selected distance measuring point becomes EVb. In any case, a large weighting process is performed centering on the selected point to obtain the weighted average photometric value. The denominator of the above formula

[0067]

[Outside 2] Is the sum of the weighting values of FIG. 10 determined as described above. The value EVb calculated in this way is
It is used in the main light emission proper ratio calculation (S09) described later.

The step (S02) corresponds to the step (# 02) in the flow of FIG. 5, in which the photographing mode such as the shutter speed priority mode and the aperture value priority mode and the control value are input according to the intention of the photographer. Then, step (S0
3) (step (# 05) in the flow of FIG. 5), EVb (i) of the input shooting mode or control value and subject brightness
Then, the exposure value (EVs) of the shutter speed (TV) and the aperture value (AV) is determined.

EVs = TV + AV (EVs is an exposure value determined by a shutter and an aperture) To determine this exposure value, the weighted average value EVb obtained in step (S01) may be used as EVs. A well-known division photometric calculation algorithm may be used. The step (S04) corresponds to the step (# 08) in the flow of FIG. 5, and the subject brightness immediately before the preliminary light emission is measured and the weighted average is taken.

[0070]

[Outside 3] (However, EVa (i) is the photometric value of each area) The calculation method is the same as in step (S01), and the following is the reason why the same photometry and calculation as in step (S01) are performed again.

First, there is a possibility that the photographer changes the framing and the state of the subject changes depending on the state when SW1 is ON and the state when SW2 is about to start the exposure operation. To be. Subsequent preliminary light emission needs to be performed in a short time in order to prevent energy waste and to reduce glare on the side to be photographed. Therefore, photometry also needs to be performed in a short time. Therefore, in order to reduce the influence of flicker in consideration of the case where an image is taken with a fluorescent light source as shown in FIG. 7, a step (S01)
In the photometry, the photometry in each area is repeated for a relatively long time (the time corresponding to the period of the flicker of the fluorescent lamp), and the average of the photometry values is used as the individual photometry value EVb (i) in each area. The photometry in (S04) is as short as the photometry during the subsequent preliminary light emission, and it is necessary to shorten the time interval between the photometry during the preliminary light emission as much as possible.

The calculated Eva is the main light emission proper ratio calculation (S) described later in order to calculate the object reflected light of only the preliminary light emission.
09). Next, step (S07) (# in FIG. 5)
In step 09), the preliminary light emission is controlled, and the light emission amount of the preliminary light emission is determined by the procedure of step (S05) and step (S06). The step (S05) is (# 0 in FIG.
Corresponding to 7), the main-con charge voltage Vc, the subject brightness information EVb, the subject distance information Dist are input, and the step (S0) corresponding to (# 08) in FIG. 5 is performed.
In 6), the preliminary light emission amount Q is calculated.

Q = k × F ₁ (Vc) × F ₂ (EVb) × F
₃ (Dist) k is a constant that makes the amount of preliminary light emission appropriate. The functions F1, F2, and F3 will be described with reference to FIG. FIG. 8A is a graph of the function F1. The higher the charging voltage of the main capacitor, the larger the amount of light emission of preliminary light emission. this is,
The larger the amount of preliminary light emission, the larger the dynamic range of photometry of reflected light from the subject, which is advantageous. However, when the charging voltage of the main capacitor is low, the purpose is to prevent the energy for main light emission from being taken away by the preliminary light emission.

FIG. 8B is a graph of the function F2. If the subject brightness under natural light is high, the reflected light from the subject due to preliminary light emission may be buried in the brightness under natural light, so it is necessary to increase the amount of preliminary light emission. On the other hand, if the subject brightness is low under natural light, the person taking the picture suddenly emits strobe light, which is dazzling. Therefore, it is necessary to keep the amount of preliminary light emission low. It is difficult to increase / decrease the preliminary light emission amount when the brightness is higher than a certain level and when it is low, and therefore it is kept constant. (C) of FIG.
Is a graph of the function F3. If the absolute distance of the subject from the camera is short, the photographed side is dazzling, so it is necessary to reduce the amount of preliminary light emission. On the contrary, if the distance is far, the preliminary light emission does not reach the subject and the photometry of the reflected light from the subject cannot be performed. Therefore, it is necessary to increase the preliminary light emission amount. When the absolute distance is more or less than a certain distance, the amount of preliminary light emission is constant like the function F2. The increase or decrease of the preliminary light emission amount is controlled by the height of the peak value of the flat light emission as described above. The step (S08) corresponds to the step (# 10) in the flow of FIG. 5, in which the brightness of the reflected light from the subject during the preliminary light emission is measured and the weighted average is taken.

[0075]

[Outside 4] (However, EVf (i) is the photometric value of each area) The timing is as shown in FIG. 7, and the weighted average is the same as in step (S01) and step (S04). The step (S09) corresponds to the step (# 11) in the flow of FIG. 5, and calculates the emission amount of the main emission that is appropriate for the preliminary emission.

R = LN ₂ ( ₂ EVs− ₂ EVb) −LN
₂ ( ₂ EVf− ₂ EVa) The first term of this formula is obtained by expanding the subject brightness photometric value (EVb) from the exposure value (EVs) by taking a power of 2 and taking the difference, and finally taking the base of 2. It is LOG compressed with. By this calculation, the amount of exposure EVs regulated by the camera, which is insufficient for the subject brightness EVb under natural light, is calculated. In other words, the total exposure of the subject is performed with the idea that the brightness under natural light is added to the brightness under natural light to obtain a proper exposure. Next, in the second term of this equation, the subject reflected light luminance (EVf) at the time of preliminary light emission is similarly extended from the subject luminance immediately before the preliminary light emission (EVa), and the difference is taken and compressed. In this calculation, the subject reflected light of only the flash preliminary light emission is obtained by subtracting the subject brightness under natural light.

Then, by subtracting the second term from the first term, the calculation is a compression system. Therefore, in order to obtain a proper total exposure, how much should the emission amount of the main emission be increased with respect to the preliminary emission? The ratio of whether to reduce it is required.

In step (S10), which corresponds to step (# 10) in the flow of FIG. 5, the integrated value obtained by direct photometry of the xenon tube 19 for preliminary light emission is set as pre_int.

The step (S11) corresponds to the step (# 11) in the flow of FIG. 5, and calculates the proper integral value of the main light emission.

Main_int = pre_int + r +
TV-t_pre + c All variables are compression system variables.

For the peak value of the preliminary light emission, step (S
09), the flat value may be emitted while the shutter is open at the peak value of the value obtained by adding the ratio r, but since this is converted to an integral value, the shutter time (TV) -pre-emission duration ( The time factor of t_pre) may be added. This is also explained in FIG. 7.

Finally, a correction coefficient c such as a light control correction amount set by the photographer is added. Step (S1
2) is a portion corresponding to the step (# 14) in the flow of FIG. 5, in which the main light emission amount is controlled based on the proper integrated value of the main light emission calculated. That is, the above main_in
The main light emission is controlled by setting a value corresponding to t to the non-inverting input terminal of the comparator 205 and controlling the light emission until the output of the integration circuit 211 for the main light emission reaches the set value.

As described above, according to the present invention, it is not dazzling for a person to be photographed by changing the amount of preliminary light emission, and the reflected light of the subject at the time of preliminary light emission is measured by the multi-division photometric sensor, and the direct light of the strobe is integrated by photometry. In this way, by obtaining an appropriate integral value of the main flash and controlling the main flash, a strobe control camera system that can stably obtain the proper exposure without being influenced by the condition of the subject or the type of film is realized. .

FIG. 4 illustrates an electric circuit block diagram of another embodiment of the strobe control system embodying the present invention.

FIG. 4 shows only the portion different from the circuit block shown in FIG. An integrating circuit 120 integrates the output from the photometric circuit 106. MPU
100 can read the photometric integrated value of each area of the multi-division photometric sensor 7.

The external strobe circuit is unnecessary in some cases as compared with the above-described embodiment shown in FIG. 3. In this embodiment, since flat light emission is not used for preliminary light emission, the monitor sensor 32 (PD2), The monitor circuit 209, the comparator 206, and the diode D1 are unnecessary. In this embodiment, the preliminary light emission replaces the flat light emission with the flash light,
The integrating circuit 120 is added to the photometry circuit for reflected light from the subject, and only the photometry from the normal subject is replaced by the integration type. The calculation is performed in exactly the same manner as in the example of FIG. The integrated value can be obtained. The preliminary light emission duration time (t_pre) in FIG. 3 may be calculated by replacing it with the integration time of the integration circuit 120.

According to the present example, since the preliminary light emission is a flash light, the flat light emission does not have to be performed, and the circuit for the flat light emission can be omitted, and the control is simple, and the integral type has a smaller light emission amount. Since the preliminary light emission can be completed with, the strobe control camera system is realized without wasting the energy for the main light emission and is dazzling and gentle to the person taking the picture.

<Correspondence between Examples and Claims> The calculating means and the preliminary light emission amount determining means of claim 16 are constituted by the MPU 100. The photometric means of claim 1 and the first photometric means of claims 8 and 11 are composed of a multi-division photometric sensor 7 and a photometric circuit 106. The monitor means of claim 5 and the second photometric means of claim 8 are composed of a monitor sensor 31 (PD1) and a monitor circuit 210. The means for performing flat light emission is a monitor sensor 32 (PD2), a monitor circuit 209,
It is composed of a comparator 206. The integrating means is the integrating circuit 120.

The means for detecting a predetermined state of the camera system according to claim 11 is a means for detecting the charging voltage of the main capacitor C1 constituted by the strobe control circuit 200, the A / D converter 202, and the dividing resistors of R1R2. Means for detecting subject brightness, which is composed of the multi-division photometric sensor 7 and the photometric circuit 106, the lens control circuit 112, and the photodetector 3.
5, a means for detecting object distance information constituted by the pulse plate 36. The multi-division photometry means is composed of the multi-division photometry sensor 7 and the photometry circuit 106. Further, in the present invention, the calculation from the multi-division photometric means is a weighted average calculation, but of course the invention is not limited to this, and various methods such as a method of calculating based on the maximum area of the reflected light of the strobe light can be considered.

In the part for obtaining the distance information of the object, even a camera of a system for manually focusing instead of automatic focus detection can be applied as long as the absolute distance information of the manually adjusted lens can be obtained.

Of course, the present invention is not limited to a single-lens reflex camera, but can be applied to a lens shutter camera and other cameras.

[0092]

As described above, claims 1 to 6, 8 to 10 and 1
According to the invention described in 7, it is possible to obtain an appropriate amount of main light emission with a novel configuration based on the preliminary light emission. According to the invention described in claims 11 to 15, the preliminary light emission amount can be adjusted to an appropriate light amount, and the person to be photographed can perform the preliminary light emission without being dazzled.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an example of an embodiment of a strobe control system according to the present invention.

FIG. 2 is a configuration diagram showing a photometric area configuration in a strobe control system according to the present invention.

3 is a circuit diagram showing a circuit configuration in the control system shown in FIG.

FIG. 4 is a circuit diagram showing an example of another embodiment of the present invention.

FIG. 5 is a flowchart showing an overall flow of a strobe control system embodying the present invention.

FIG. 6 is a flowchart showing a calculation flow of a strobe control system embodying the present invention.

FIG. 7 is a timing chart of light emission and photometry for blinding the operation of the strobe control system of the present invention.

FIG. 8 is an explanatory diagram showing a light emission amount calculation function of preliminary light emission.

FIG. 9 is a conceptual diagram of a conventional TTL dimming optical system.

FIG. 10 is an explanatory diagram showing data of photometry weighting processing in the strobe control system according to the present invention.

[Explanation of symbols]

 19, xenon tube 31, monitor sensor (PD1) 7, multi-segment photometric sensor 100, MPU 200, strobe control circuit 203, trigger circuit 204, emission stop circuit 205 & 6, comparator 211, integrating circuit C1, main capacitor

Claims (17)

[Claims] 1. A strobe control system for performing preliminary light emission before main light emission at the time of shooting, and a photometric device for photometry of reflected light from a subject due to the preliminary light emission; A strobe control system having a calculation means for obtaining light emission amount data in main light emission based on one photometric data and exposure data. 2. The strobe control system according to claim 1, wherein the exposure data is data of a value corresponding to a subject brightness and a subject brightness in a state in which the flash emission is not performed. 3. The flash control system according to claim 1, wherein the exposure data is exposure value data corresponding to an aperture value and a shutter speed value set at the time of shooting. 4. The flash control system according to claim 1, 2, or 3, wherein the calculation means obtains the light emission amount data according to a difference or a ratio between the exposure data and the first photometric data. 5. The system has preliminary light emission amount monitor means for monitoring light emission from a flash tube in the preliminary light emission to obtain a light emission amount in the preliminary light emission, and the arithmetic means calculates the exposure data and the first photometric data. The strobe control system according to claim 4, wherein the light emission amount data of the main light emission is obtained based on the difference or ratio and the light emission amount obtained by the monitor means. 6. The light emission amount data of main light emission is calculated by multiplying the ratio of the exposure data and the first photometric data by the light emission amount obtained by the monitor device. Strobe control system 7. The strobe control system monitors the light emission from the flash tube due to the main light emission, and stops the main light emission when the light emission amount reaches a value according to the light emission amount data obtained by the calculation means. 2. A main light emission control means for
Strobe control system described in 2, 3, 4, 5, 6 8. A strobe control system for performing main light emission toward an object and performing an exposure operation, comprising: means for performing preliminary light emission toward the object, and first light metering for measuring reflected light from the object during the preliminary light emission. And a second photometric means for measuring the amount of preliminary light emission from an optical path different from the first photometric means at the time of the preliminary light emission, and depending on the photometric value by the first photometric means. The main light emission amount relative to the preliminary light emission amount measured by the second light measurement device, and the main light emission amount is measured by the second light measurement device during the main light emission. A strobe control system for controlling the amount of main light emission based on a calculation result by the calculation means. 9. The strobe control system according to claim 8, wherein the preliminary light emission is a flat light emission in which the peak value is kept substantially constant for a predetermined time. 10. An integrating means for integrating the photometric output of the first photometric means, wherein the computing means computes a main light emission amount relative to the preliminary light emission amount according to the integration result. The strobe control system according to claim 8, characterized in that 11. A strobe control system for performing main light emission toward an object and performing an exposure operation, comprising: means for performing preliminary light emission toward the object, and first light metering for measuring reflected light from the object during the preliminary light emission. And a means for detecting a predetermined state of the camera system, wherein the light amount of the preliminary light emission is varied according to the predetermined state, and the main light emission amount is determined according to the photometric value by the first photometric means. A strobe control system, characterized in that the flash control system has a calculating means for calculating 12. The preliminary light emission or the main light emission is to emit light by causing a current to flow from a capacity for storing electric charge to a light emitting portion, and the predetermined state of the camera system means the amount of electric charge stored in the capacity. 12. The flash-controlled camera system according to claim 11, wherein 13. The flash control system according to claim 11, wherein the predetermined state of the camera system is subject brightness information under constant light. 14. The flash control system according to claim 11, wherein the predetermined state of the camera system is information on a subject distance from the camera system. 15. The strobe control system according to claim 8, wherein the first photometric means is a multi-division photometric means for performing photometry by dividing the screen into a plurality of areas. 16. The method according to claim 1, further comprising a preliminary light emission amount determining means for determining a light emission amount in the preliminary light emission according to a charging voltage of a main capacitor, a subject brightness or a subject distance.
7. Strobe control system according to 7. 17. The preliminary light emission is a flat light emission in which the peak value is kept substantially constant for a predetermined period of time to emit light.
6, strobe control system