JP3703183B2 - Strobe device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a strobe device that performs preliminary light emission, and more particularly to a strobe device that takes measures against noise generated in flat preliminary light emission.
[0002]
[Prior art]
The exposure control method of the conventional flash light emitting device called so-called external measuring light, which received the strobe reflected light from the subject by an optical system different from the shooting lens, and integrated the received light amount to reach a predetermined amount The one that stops the flash firing at that point.
[0003]
Or, it is called TTL dimming, and it is widely used to stop the flash emission when it reaches a predetermined amount by photometric integration of the strobe reflected light from the subject through reflection from the film surface through the taking lens during strobe shooting. It is done.
[0004]
[Problems to be solved by the invention]
However, in the external metering light of the above-mentioned conventional example, the center of the lens and the metering center of the strobe are difficult to match, and in a camera in which the lens can be replaced, the photographing region of the photographing lens may not match the metering region of the strobe There was a problem that dimming errors were likely to occur. In the TTL film surface reflection dimming, the shooting area and the dimming area of the shooting lens coincide with each other, but there is a problem that the strobe exposure level changes due to the difference in film reflectance.
[0005]
In order to solve these problems, a strobe system of a camera that performs preliminary light emission toward the subject, measures the reflected light from the subject at the time of the preliminary light emission, and calculates the light emission intensity of the main light emission according to the photometry result is provided. Proposed by the applicants.
[0006]
This proposal will be described with reference to a block diagram of a conventional strobe device shown in FIG. In the figure, 19 is a xenon tube which is a light emitting tube, 20 is a reflection shade, 21 is a Fresnel lens, 31 and 32 are light receiving elements, 200 is a microcomputer (strobe) control means, and 201 is 300 numbers. A DC / DC converter for generating a high voltage of 10 V, 202 is a trigger circuit for giving a high voltage of several thousand V to the xenon tube 19 to start light emission, 203 is a light emission control circuit, 204 and 205 are comparators, and 206 is Data selectors 207 and 209 are monitor circuits for amplifying the output of the light receiving element, and 208 is an integrating circuit for integrating the output of the light receiving element 31.
[0007]
In this proposal, first, in order to perform predetermined flat preliminary light emission, when the data selector 206 selects the comparator 205 and triggers from the trigger circuit 202, light emission is started, and the light emission intensity of the flat light emission is just the non-inversion of the comparator 205. Flat light emission is sustained at a light emission intensity centered on the voltage set at the input terminal.
[0008]
The amount of light emitted during this period is received by the light receiving element 31 and integrated by the integrating circuit 208 via the monitor circuit 207. After completion of the preliminary light emission, the output of the integration circuit 208 is read at the analog / digital conversion input terminal of the flash microcomputer 200, and the digital output is obtained by adding / subtracting the difference between the light emission amount of the preliminary light emission and the main light emission to the output of the integration circuit read during flash main light emission. The data is output to DA0, which is the conversion output, and the comparator 204 is selected by the data selector 206. When a light emission trigger is given from the trigger circuit 202, the light emission is started, and the integration circuit 208 outputs an integrated voltage in the same manner as in the preliminary light emission. When the voltage exceeds the DA0 output, the comparator 204 is inverted to stop light emission. That is, if the preliminary light emission and the main light emission have the same light emission amount, the same light emission amount should be obtained by setting the voltage read in the previous A / D conversion as it is in the previous D / A conversion output.
[0009]
The light emission waveform in this case will be described with reference to the waveform diagram of FIG. FIG. 12A shows the light emission waveform, and FIG. 12B shows the output of the integration circuit 208. In the figure, when the flat preliminary light emission is started at time t0, the integrated voltage b rises to the voltage level c by the end of light emission. This integrated voltage is read by AD which is an A / D conversion input of the microcomputer 200. Next, when light is emitted so that the main light emission has the same integral amount, the same light amount as the preliminary light emission can be obtained by setting the same voltage level to the D / A conversion output DA0 of the microcomputer 200.
[0010]
However, when performing flat preliminary light emission, switching elements such as IGBTs are switched at a fast frequency, and the cut-off current at that time reaches 100 amperes or more. Even in the circuit, an error signal is integrated due to the influence of noise, and if the integral amount of the preliminary light emission is measured in this way, there arises a problem that the light emission amount of the main light emission is distorted. This state will be described with reference to FIG.
[0011]
FIG. 13 shows the relationship between preliminary light emission and main light emission in the same operation as FIG. FIG. 4A shows the light emission waveform, and FIG. 4B shows the output of the integration circuit 208. When the preliminary light emission is correctly performed, the line b should have a waveform as shown by a dotted line. However, when the IGBT is switched for controlling the emission intensity of the flat light emission, the integrated waveform is affected by the noise. Becomes a solid line b '. As a result, the light emission level of the main light emission is shifted to the position indicated by d, resulting in a problem of overexposure.
[0012]
Therefore, the object of the invention of claim 1 is Place An object of the present invention is to provide a strobe device that has an integral output storage means for storing the output of the integration means under a constant light emission condition and can perform proper strobe photography even when the integration is not performed correctly due to light emission noise.
[0013]
Furthermore, the object of the invention described in claim 2 is Place Integral output storage means for storing the output of the integration means according to a constant light emission condition, and accurate flash photography that is not affected by noise generated by the light emission control means at the time of preliminary light emission control is possible. An object of the present invention is to provide a strobe device that can be simplified.
[0014]
Furthermore, the object of the invention described in claim 3 is as follows: Place Providing a strobe device that has integral amount adjustment means that adjusts the output of the integration means to a predetermined amount under constant light emission conditions, and can perform proper strobe photography even if integration is not performed correctly due to light emission noise There is to do.
[0015]
Furthermore, the object of the invention described in claim 4 is as follows. Place Integral amount adjustment means that adjusts the output of the integration means under a constant light emission condition to be a predetermined amount, and accurate flash photography that is not affected by noise generated by the light emission control means during preliminary light emission control is possible Another object is to provide a strobe device capable of greatly simplifying the circuit.
[0016]
Furthermore, an object of the invention described in claim 5 is to provide a strobe device capable of performing preliminary light emission by flat light emission and controlling the light emission amount of the main light emission based on an integral amount obtained by integrating the light emission amount. .
[0017]
Furthermore, an object of the invention described in claim 6 is to provide a strobe device capable of controlling the main light emission by obtaining a reference integral amount under the condition where the main capacitor voltage is a flash full light emission in a fully charged state as a predetermined light emission condition. .
[0018]
Furthermore, an object of the invention described in claim 7 is to provide a strobe device that can determine a pre-light emission condition from information such as subject distance, subject brightness, or voltage of a main capacitor, and obtain a computation integration amount by computation. It is in.
[0020]
Further, the object of the invention described in claim 8 is that the reference integration amount is obtained by measuring the integration amount at the time of full flash emission when the main capacitor is fully charged at each zoom position. Integral output An object of the present invention is to provide a strobe device which is stored in a storage means and used as information for main light emission control.
[0021]
Further claims 9 It is an object of the present invention to provide a strobe device that controls a main light emission by adding a preliminary light emission reference integral correction amount to a reference integral amount to obtain an operation integral amount.
[0022]
[Means for Solving the Problems]
In order to achieve the above object, the present invention performs preliminary light emission to measure the reflected light from the subject and integrate the light emission amount of the arc tube, and the light emission of the main light emission based on the photometry result of the preliminary light emission and the integrated amount. In the strobe device that determines the amount, Record By comparing the calculated integral amount calculated from the reference integral amount stored in the memory with the integral amount obtained by integrating the actual light during the preliminary light emission, the validity of the integral during the preliminary light emission is verified, and the integral is normal. If this is done, the main light emission is controlled based on the integral amount at the time of preliminary light emission, and if the integration is not performed normally, the main light emission is controlled based on the calculated integral amount to eliminate the influence of noise. It is configured as follows.
[0023]
Also, product Comparing the calculated integral amount calculated from the reference integral amount adjusted by the dose adjustment means with the integral amount obtained by integrating the actual light during the preliminary flash, verifies the validity of the integral during the preliminary flash, and the integration is normal In this case, the main light emission is controlled based on the integral amount at the time of preliminary light emission, and if the integration is not normally performed, the main light emission is controlled based on the calculated integral amount. Even in this case, the influence of noise can be eliminated.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
According to a first aspect of the present invention, there is provided a photometric means for measuring the reflected light from the subject at the time of the preliminary light emission. In a strobe device having a calculation means for calculating the light emission intensity of the main light emission according to the photometry result from the photometry means, a monitor means for monitoring the light of the light emission means, an integration means for integrating the output of the monitor means, Place An integral output storage means for storing the output of the integration means under a constant light emission condition as a reference integral amount; and a predetermined light emission based on a reference integral amount stored in the integral output storage means while performing the preliminary light emission during photographing. A calculation integration amount calculation means for calculating a calculation integration amount as a light emission integration expected amount in the preliminary light emission condition, and a difference between an output of the integration means in the preliminary light emission and a calculation integration amount by the calculation integration amount calculation means within a predetermined value In this case, the light emission amount of the main light emission is controlled based on the output of the integrating means, and when the difference between the outputs exceeds a predetermined value, the light emission amount for controlling the light emission amount of the main light emission based on the calculated integral amount by the calculation integral amount calculating means. A strobe device comprising a control means.
[0025]
According to this configuration, by comparing the actual integral amount at the time of preliminary light emission and the calculated integral amount calculated based on the stored reference integral amount, the validity of the integral of the preliminary light emission is judged, and the preliminary light emission is determined. When the time integration is normally performed, the main light emission is controlled based on the integral amount at the time of preliminary light emission, and when the integration is not normally performed, the main light emission is controlled based on the calculated integral amount. The main light emission control that is not affected by noise becomes possible.
[0026]
According to another aspect of the present invention for realizing the object of the present invention, as set forth in claim 2, it has means for performing preliminary light emission toward the subject, and photometry is performed for measuring reflected light from the subject during the preliminary light emission. And a strobe device having a calculating means for calculating the light emission intensity of the main light emission according to the photometric result from the photometric means, a monitor means for monitoring the light generated from the light emitting means, and an integrating means for integrating the output of the monitor means When, Place An integral output storage means for storing the output of the integration means under a constant light emission condition as a reference integral amount; and a predetermined light emission based on a reference integral amount stored in the integral output storage means while performing the preliminary light emission during photographing. A calculation integration amount calculation means for calculating a calculation integration amount as a light emission integration expected amount in the preliminary light emission condition, and a light emission for controlling the light emission amount of the main light emission based on the calculation integration amount by the calculation integration amount calculation means in the main light emission. A strobe device comprising a control means.
[0027]
According to this configuration, the integral amount at the time of preliminary light emission is not used, and the light emission control of the main light emission is always performed using the calculated integral amount obtained by the calculation of the calculation integral amount calculation means. The main light emission can be controlled without being influenced by noise generated by the means.
[0028]
According to another aspect of the present invention for realizing the object of the present invention, as described in claim 3, there is provided a means for performing preliminary light emission toward the subject, and photometry for measuring reflected light from the subject during the preliminary light emission. And a strobe device having a calculation means for calculating the light emission intensity of the main light emission according to a photometric result from the photometry means, a monitor means for monitoring the light of the light emission means, an integration means for integrating the output of the monitor means, Place Integral amount adjusting means for adjusting the output of the integrating means under a predetermined light emission condition to be a predetermined reference integral amount, and performing preliminary light emission at the time of shooting and predetermined based on the adjusted reference integral amount A calculation integration amount calculating means for calculating a calculation integration amount as a light emission integration expected amount under the preliminary light emission conditions, and a difference between an output of the integration means in the preliminary light emission and a calculation integration amount by the calculation integration amount calculation means is a predetermined value. If the difference is within the range, the light emission amount of the main light emission is controlled based on the output of the integration means, and if the difference between the outputs exceeds a predetermined value, the light emission amount of the main light emission is controlled based on the calculation integration amount by the calculation integration amount calculation means. A strobe device comprising a light emission control means.
[0029]
According to this configuration, by comparing the actual integration amount at the time of preliminary light emission with the calculated integration amount calculated by the calculation integration amount calculation unit from the reference integration amount adjusted by the integration amount adjustment unit, To determine the appropriateness, if the integral is normal, the main flash is controlled by the integral amount of the preliminary flash, and if the integral is not normal, the main flash is controlled by the calculated integral amount. Even a strobe device having no storage means can control the main light emission without being affected by noise.
[0030]
According to another aspect of the present invention for realizing the object of the present invention, as described in claim 4, there is provided means for performing preliminary light emission toward the subject, and photometry for measuring reflected light from the subject during the preliminary light emission. And a strobe device having a calculation means for calculating the light emission intensity of the main light emission according to a photometric result from the photometry means, a monitor means for monitoring the light of the light emission means, an integration means for integrating the output of the monitor means, Place Integral amount adjusting means for adjusting the output of the integrating means under a predetermined light emission condition to be a predetermined reference integral amount, and performing preliminary light emission at the time of shooting and predetermined based on the adjusted reference integral amount A calculation integral amount calculating means for calculating a calculation integration amount as a light emission integral expected amount under the preliminary light emission conditions, and controlling the light emission amount of the main light emission based on the calculation integration amount by the calculation integral amount calculation means at the time of main light emission. A strobe device comprising a light emission control means.
[0031]
According to this configuration, the main light emission is controlled by the calculation integration amount calculated by the calculation integration amount calculation means from the reference integration amount adjusted by the integration amount adjustment means without using the integration amount at the time of preliminary light emission. Even in a strobe device that does not have a storage means for storing the integral amount, it is possible to control the main light emission that is not affected by noise generated by the light emission control means during the preliminary light emission control.
[0032]
A specific configuration for realizing the object of the invention according to the present invention is characterized in that, as described in claim 5, the preliminary light emission is flat light emission performed at a predetermined light emission intensity for a predetermined light emission time. Item 5 is the strobe device according to one of Items 1 to 4.
[0033]
According to this configuration, the main light emission can be controlled by an integral amount obtained by integrating the light emission amount of the preliminary light emission by the flat light emission.
[0034]
Another specific configuration for realizing the object of the present invention is as described in claim 6, Place 5. The strobe device according to claim 1, wherein the constant light emission condition is a flash full light emission when a voltage of a main capacitor for accumulating light emission energy is in a fully charged state.
[0035]
According to this configuration, it is possible to obtain the reference integration amount with the flash full emission when the voltage of the main capacitor is fully charged as the predetermined emission condition.
[0036]
According to another specific configuration for realizing the object of the invention according to the present invention, as defined in claim 7, the predetermined preliminary light emission condition is at least one of subject distance, subject brightness, or main-denser voltage. 5. The strobe device according to claim 1, wherein the strobe device is determined by information.
[0037]
According to this configuration, it is possible to determine the preliminary light emission condition from information such as the subject distance, subject luminance, main capacitor voltage, and the like to obtain the calculation integration amount.
[0039]
According to another specific configuration for realizing the object of the present invention, as set forth in claim 8, the reference integration amount is an integration amount at the time of flash full emission when the main capacitor is fully charged, at each zoom position. Measure every time Integral output Claims are stored in storage means. 1 or 2 In the strobe device described in 1.
[0040]
According to this configuration, the integration amount for each zoom position under the flash full emission condition when the main capacitor is fully charged can be stored in the storage unit as the reference integration amount.
[0041]
Other specific configurations realizing the object of the present invention are as follows. 9 5. The calculation integration amount is obtained by adding a preliminary light emission reference integration correction amount calculated based on a voltage of a main capacitor to the reference integration amount. In the strobe device described in 1.
[0042]
According to this configuration, it is possible to calculate the calculation integration amount to be obtained with a predetermined preliminary light emission intensity by adding the preliminary light emission reference integral correction amount to the reference integral amount.
[0043]
【Example】
(First embodiment)
FIG. 1 is a cross-sectional view of a camera equipped with a strobe device according to a first embodiment of the present invention. FIG. 1 is an example in which the strobe device of the present invention is applied to a single-lens reflex camera, and is a cross-sectional view mainly illustrating an optical configuration.
[0044]
In FIG. 1, 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 disposed on the photographing optical path or moved away depending on 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 taking lenses 12 to 14, 4 denotes a finder optical path changing pentaprism, 5 denotes a finder, and the photographer observes the focusing plate 3 through this window, thereby displaying a shooting screen. Can be observed. Reference numerals 6 and 7 denote an imaging lens and a photometric sensor for measuring the luminance of the object in the observation screen. The imaging lens 6 associates the focus plate 3 and the photometric sensor 7 in a conjugate manner via the reflected light path in the penta roof prism 4. ing.
[0045]
Reference numeral 8 denotes a shutter, and reference numeral 9 denotes a photosensitive member 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. A sub-mirror 25 bends the light beam from the 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. 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 to be described later, and realizes an automatic focus detection device by controlling the focus adjustment mechanism of the shooting lens. ing.
[0046]
Reference numeral 10 denotes a mount contact group serving as an interface between the camera and the lens, and 11 denotes a lens barrel installed on the camera body. Reference numerals 12 to 14 denote photographing lenses, and reference numeral 12 denotes a first group lens. The focal position of the photographing screen can be adjusted by moving back and forth on the optical axis. Reference numeral 13 denotes a two-group lens, which moves to the 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. Reference numeral 16 denotes a previous first group lens drive motor, which can automatically adjust the focus position by moving the first group lens back and forth in accordance with an automatic focus adjustment operation. Reference numeral 17 denotes a lens diaphragm drive motor, which can drive the photographing lens diaphragm to a desired diaphragm diameter.
[0047]
Reference numeral 18 denotes an external strobe (flash device) which is attached to the camera body 1 and performs light emission control in accordance with a signal from the camera. Reference numeral 19 denotes a xenon tube as a luminous tube, which converts current energy into luminous energy. Reference numerals 20 and 21 denote a reflector and a Fresnel lens, each of which plays a role of efficiently condensing light emission energy toward a subject. A strobe contact group 22 serves as an interface between the camera body 1 and the external strobe 18. Reference numeral 30 denotes a light transmission means such as a glass fiber, which is led to a light receiving element 31 as a monitoring means such as a photodiode which is a light receiving means for monitoring the light emitted from the xenon tube 19. Reference numeral 31 directly measures the amount of preliminary light emission and main light emission of the strobe. Reference numeral 32 denotes monitor means for monitoring the light emitted from the xenon tube 19 and is a light receiving element such as a photodiode. The light receiving element 32 controls the flat light emission by limiting the light emission current of the xenon tube 19 by the output. Reference numerals 20a and 20b are light guides integrated with the reflective shade 20, and reflect and guide the light of the xenon tube to the light receiving element 32 or the fiber 30.
[0048]
FIG. 2 is an electric circuit block diagram of the camera shown in FIG.
In FIG. 2, a camera microcomputer (microcomputer) 100 as a camera-side control means performs an internal operation based on a clock generated by an oscillator 101. The EEPROM 100b as a storage means can store film counter and other shooting information. An A / D (analog / digital converter) 100c A / D converts analog signals from the focus detection circuit 105 and the photometry circuit 106, and the camera microcomputer 100 performs various signal processing on the A / D values. Set.
[0049]
The camera microcomputer 100 is connected to a focus detection circuit 105, a photometry circuit 106, a shutter control circuit 107, a motor control circuit 108, a film travel detection circuit 109, a switch sense circuit 110, and an LCD drive circuit 111. Signals are transmitted to the microcomputer (microcomputer) 112 as a lens control circuit disposed in the photographing lens via the mount contact 10, and the external strobe is connected to the strobe side via the strobe contact group 22. Signal transmission is performed with a strobe microcomputer (microcomputer) 200 as processing means.
[0050]
The focus detection circuit 105 performs accumulation control and readout control of a CCD line sensor 29 that is a known distance measuring element in accordance with a signal from the camera microcomputer 100, and outputs each pixel information 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. Based on the focus detection information, the camera microcomputer 100 exchanges signals with the lens microcomputer 112 to adjust the focus of the lens.
[0051]
The photometry circuit 106 outputs an output from the photometry sensor 7 to the camera microcomputer 100 as a luminance signal of the subject. The photometry circuit 106 outputs a luminance signal in both the steady state where the strobe light is not preliminarily emitted toward the subject and the preliminary emission state where the preflash is emitted, and the camera microcomputer 100 performs A / D conversion of the luminance signal. Then, the aperture value and shutter speed are calculated to adjust the exposure for photographing, and the flash emission amount at the time of exposure is calculated.
[0052]
The shutter control circuit 107 runs the shutter front curtain drive magnet MG-1 and the shutter rear curtain drive magnet MG-2 constituting the focal plane shutter 8 in accordance with a signal from the camera microcomputer 100, and performs an exposure operation. The motor control circuit 108 controls the motor in accordance with a signal from the camera microcomputer 100, thereby performing up / down of the main mirror 2, charging of the shutter, and feeding of the film.
[0053]
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. 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 independently performs preliminary light emission, which will be described later. SW1, SW2, SWFELK and other signals from camera operation members (not shown) are detected by the switch sense circuit 110 and transmitted to the camera microcomputer 100. . The liquid crystal display circuit 111 controls display on the in-viewfinder LCD 24 and the monitor LCD 42 according to a signal from the camera microcomputer 100. SWX is a strobe light emission start switch, which is turned on simultaneously with the completion of shutter front curtain travel.
[0054]
Next, the strobe and lens interface terminals of the camera microcomputer 100 will be described. SCK is a synchronous clock output terminal for serial communication with the strobe, SDO is a serial data output terminal for serial communication with the strobe, SDI is a data input terminal for serial communication with the strobe, and SCHG is a strobe of the strobe. Input terminal for detecting the completion of charging, LCK is an output terminal for a synchronous clock for serial communication with the lens, LDO is a serial data output terminal for serial communication with the lens, and LDI is a serial communication terminal for the lens. This is a data input terminal.
[0055]
Next, the configuration of the lens will be described. The camera body 1 and the lens are electrically connected to each other via a lens mount contact 10. This lens mount contact 10 is L0 which is a power contact for the focus drive motor 16 and the aperture drive motor 17 in the lens, L1 which is a power contact for the lens microcomputer 112 as lens control means, and known serial data communication. Contact L2 for clock transmission, contact L3 for data transmission from the camera to the lens, contact L4 for data transmission from the lens to the camera, L5 which is the ground contact for the motor to the power supply for the previous motor, the previous lens microcomputer 112 It is comprised by L6 which is a ground contact with respect to the power supply for operation.
[0056]
The lens microcomputer 112 is connected to the camera microcomputer 100 via these lens mount contacts 10 to operate the first group lens driving motor 16 and the lens aperture motor 17 to control the lens focus adjustment and the aperture. Reference numerals 35 and 36 denote a photodetector and a pulse plate, and the lens microcomputer 112 counts the number of pulses to obtain position information of the first lens group, thereby adjusting the focus of the lens.
[0057]
FIG. 3 is an electric circuit block diagram of the strobe shown in FIG.
Next, the structure of the strobe will be described with reference to FIG. A strobe microcomputer 200 as a strobe control means is a circuit for controlling a strobe in accordance with a signal from the camera microcomputer 100, and controls the amount of light emission, control of light emission intensity and time of flat light emission, control of light emission angle, etc. Do.
[0058]
A DC / DC converter 201 as a booster circuit boosts the battery voltage to several hundred volts in accordance with an instruction from the stroboscopic microcomputer 200 and charges the main capacitor C1. R1 / R2 are voltage dividing resistors provided for the strobe microcomputer 200 to monitor the voltage of the main capacitor C1. The strobe microcomputer 200 performs A / D conversion on the divided voltage by the A / D converter with a built-in strobe microcomputer, indirectly monitors the voltage of the main capacitor C1, and controls the operation of the DC / DC converter 201. The voltage of the main capacitor C1 is controlled to a predetermined voltage.
[0059]
Reference numeral 202 denotes a trigger circuit, which outputs a trigger signal via the strobe microcomputer 200 in response to an instruction from the camera microcomputer 100 when strobe light is emitted, and discharges the xenon tube 19 by applying a high voltage of several thousand volts to the trigger electrode of the xenon tube 19. And the charge energy stored in the main capacitor C1 is released as light energy through the xenon tube 19. Reference numeral 203 denotes a light emission control circuit using a switching element such as an IGBT. The current of the xenon tube 19 is turned on when a trigger voltage is applied during light emission, and the current of the xenon tube 19 is cut off when light emission is stopped. Stop flashing.
[0060]
Reference numerals 204 and 205 denote comparators, 204 is used to stop light emission during flash emission described later, and 205 is used to control light emission intensity during flat light emission described later. A data selector 206 selects inputs D0 to D2 and outputs them to Y in accordance with selection signals SEL1 and SEL0 from the flash microcomputer 200. Reference numeral 207 denotes a flash light emission control monitor circuit that logarithmically compresses the output of the light receiving element 31 and outputs the amplified signal.
[0061]
Reference numeral 208 denotes an integration circuit corresponding to integration means for integrating the output of the monitor circuit 207. A flat light emission control monitor circuit 209 amplifies the output of the light receiving element 32. Reference numeral 210 denotes an EEPROM corresponding to an integral output storage means for storing a flat light emission time, a reference integral amount, and the like. 211 is a known motor drive circuit, 212 is a zoom drive motor, 213 is a pinion gear, 214 is a rack gear, 215 is a zoom position detection encoder for detecting the position of the reflective shade 20, and 216 is an LED indicating that light emission is possible.
[0062]
Next, each terminal of the flash microcomputer 200 will be described.
CK is an input terminal for a synchronous clock for serial communication with the camera, DI is an input terminal for serial communication data, DO is a data output terminal for serial communication, and CHG is an output terminal for transmitting the strobe light emission state to the camera as a current. , X are light emission signal input terminals from the camera.
[0063]
ECK is a terminal for outputting a communication clock for serial communication with a writable memory such as an EEPROM or a flash ROM of the storage means 210 connected to the outside of the flash microcomputer 200, and EDI is a serial data input from the storage means 210. A terminal, EDO is a serial data output terminal to the storage means 210, and SELE is an enable terminal that permits communication with the storage means 210. The terminal is enabled at Hi and disabled at Lo. In this embodiment, the integral output storage means 210 is installed outside the strobe microcomputer 200, but the same is true for a structure built in the strobe microcomputer 200.
[0064]
POW is an input terminal for inputting the state of the power switch 217, OFF is an output terminal for turning off the strobe when connected to the power switch 217, and ON is used for turning on the strobe when connected to the power switch 217. In the power ON state, the POW terminal is connected to the ON terminal, in which case the ON terminal is in the high impedance state and the OFF terminal is in the Lo state. The opposite is true in the power-off state. The LED 216 is a display output terminal for displaying that light can be emitted.
[0065]
STOP is an input terminal for a light emission stop signal, and the light emission stop state is set at Lo. SEL0 and SEL1 are output terminals for instructing input selection of the data selector 206. When the combination of SEL0 and SEL1 is (SEL1, SEL0) = (0, 0), the D0 terminal is connected to the Y terminal, and (0, In the case of 1), the D1 terminal is connected to the Y terminal, and in the case of (1, 0), the D2 terminal is connected to the Y terminal.
[0066]
DA0 is a D / A output terminal incorporated in the flash microcomputer 200, and outputs the comparator level of the comparators 204 and 205 as an analog voltage. TRIG is a trigger signal output terminal for instructing the trigger circuit 202 to emit light, and CNT is an output terminal for controlling the oscillation start / stop of the DC-DC converter 201. Charging starts with Hi, and oscillation stops with Lo. INT is a terminal for controlling the start / prohibition of integration of the integration circuit 208. The integration is prohibited by Hi and the integration is enabled by Lo.
[0067]
AD0 and AD1 are A / D input terminals for converting the input voltage into digital data so that it can be processed inside the microcomputer 200. AD0 monitors the voltage of the main capacitor C1, and AD1 is the integration circuit 208. This is an input terminal for monitoring the integrated output voltage. Z0 and Z1 are control output terminals for controlling the control circuit 211 for driving the zoom drive motor 212, ZM0, ZM1 and ZM2 are input terminals for inputting the zoom position detection encoder 215, and COMO is set to the ground level of the zoom position detection encoder 215. This is a common terminal for drawing the corresponding current.
[0068]
If each means in the present invention is shown in terms of hardware configuration, the camera microcomputer 100 and the flash microcomputer 200 correspond to the calculation means for calculating the light emission intensity of the present invention, and the flash microcomputer 200 corresponds to the calculation integration amount calculation means. . The light emission control means includes the strobe microcomputer 200, the light emission control circuit 203, the data selector 206, the comparators 204 and 205, the light receiving elements 31 and 32, the monitor circuits 207 and 209, and the integration circuit 208.
[0069]
Next, the light emission operation will be described.
First, regarding [preliminary light emission], when the strobe is ready to emit light, the camera communicates the light emission intensity and the light emission time of the preliminary light emission to the strobe via the communication terminal 22 to instruct the preliminary light emission.
[0070]
The microcomputer 200 sets a predetermined voltage in DA0 according to a predetermined light emission intensity signal instructed from the camera body. Next, Lo and Hi are output to SEL1 and SEL0 to select the input D1. At this time, since the xenon tube 19 has not yet emitted light, the photocurrent of the light receiving element 32 hardly flows, and the output of the monitor circuit 209 that is input to the inverting input terminal of the comparator 205 does not occur, so the output of the comparator 205 becomes Hi. The light emission control circuit 203 is turned on. Next, when a trigger signal is output from the TRIG terminal, the trigger circuit 202 generates a high voltage to excite the xenon tube 19 and light emission is started.
[0071]
On the other hand, the strobe microcomputer 200 instructs the integration circuit 208 to start integration after a predetermined time from the occurrence of the trigger, and the integration circuit 208 integrates the output of the monitor circuit 207, that is, the logarithmically compressed photoelectric output of the light receiving element 31 for light intensity integration. Simultaneously with the start, a timer for counting a predetermined time is started. The reason why the start of the integration is delayed for a predetermined time from the occurrence of the trigger is to prevent the integration circuit 208 from integrating noise other than the optical signal due to the noise caused by the occurrence of the trigger. This is because there is a delay of 10 or more μsec later.
[0072]
When the preliminary light emission is started, the photocurrent of the light receiving element 32 for controlling the light emission intensity of flat light emission increases, the output of the monitor circuit 209 increases, and a predetermined comparator set as the non-inverting input of the comparator 205 is obtained. When it becomes higher than the rate voltage, the output of the comparator 205 is inverted to Lo, and the light emission control circuit 203 cuts off the light emission current of the xenon tube 19 and the discharge loop is cut, but the diode D1 and the coil L1 form a reflux loop, The light emission current gradually decreases after the overshoot due to the circuit delay is settled.
[0073]
Since the light emission intensity decreases as the light emission current decreases, the photocurrent of the light receiving element 32 decreases and the output of the monitor circuit 209 decreases. When the output drops below a predetermined comparator level, the output of the comparator 205 is inverted to Hi again, the light emission control circuit 203 is turned on again, a discharge loop of the xenon tube 19 is formed, the light emission current increases, and the light emission intensity. Will also increase. As described above, the comparator 205 repeats increasing and decreasing the emission intensity in a short period around the predetermined comparator voltage set to DA0, and as a result, the flatness continues to emit light at the desired substantially constant emission intensity. Light emission control becomes possible.
[0074]
When the above-mentioned light emission time timer is counted and the predetermined preliminary light emission time elapses, the flash microcomputer 200 sets the SEL1 and SEL0 terminals to Lo and Lo, and the input of the data selector 206 is selected as D0, that is, the Lo level input is output. Is forcibly set to Lo level, and the light emission control circuit 203 interrupts the discharge loop of the xenon tube 19 and ends the light emission.
[0075]
At the end of light emission, the flash microcomputer 200 reads the output of the integration circuit 208 integrating the preliminary light emission from the A / D input terminal AD1 and performs A / D conversion, and reads the integrated value, that is, the light emission amount at the time of preliminary light emission as a digital value. it can.
[0076]
Here, during the preliminary light emission, the camera body side measures the exposure amount EVF during the preliminary light emission from the output of the light receiving element by the reflected light from the subject from the output of the light receiving element, and sets the strobe light to an appropriate light amount with respect to the natural light. The operation of the camera itself is performed to calculate the main light emission amount at the time of shooting and determine the strobe light emission amount of the main light emission following the preliminary light emission.
[0077]
Next, “main light emission control” will be described.
In the main light emission sequence, when the shutter speed of the camera is faster than the strobe synchronization speed, the light emission intensity and light emission time for light emission by flat light emission are instructed from the camera side by serial communication via the communication lines S0 to S2. The emission intensity in the main emission is defined as relative information with respect to the emission intensity in the preliminary emission.
[0078]
First, in the case of [Flat main light emission control], the flash microcomputer 200 obtains an appropriate light emission intensity of the main light emission amount based on the light emission intensity corresponding to the instructed main light emission amount, and a predetermined voltage that gives the appropriate light emission intensity to the DA0 output. Set. That is, if the light emission intensity is the same as that of the preliminary light emission, the same control voltage as that of the preliminary light emission is output from the DA0 output terminal of the flash microcomputer 200. If there is a difference from the preliminary light emission, the voltage obtained by adding or subtracting the difference is output from the DA0 output terminal.
[0079]
Subsequently, Lo and Hi are output to SEL1 and SEL0 to select the input D1. At this time, since the xenon tube 19 has not yet emitted light, the photocurrent of the light receiving element 32 hardly flows and the output of the monitor circuit 209 input to the inverting input terminal of the comparator 205 is not generated, so the output of the comparator 205 is Hi. The light emission control circuit 203 is turned on. Next, when a trigger signal is output from the TRIG terminal, the trigger circuit 202 generates a high voltage and excites the xenon tube 19 to start light emission. The flash microcomputer 200 starts a timer that counts the time instructed from the camera when the light emission starts. Note that the emission intensity control of flat emission is the same as the preliminary emission control, and thus the description thereof is omitted.
[0080]
After the light emission time timer is counted and the predetermined light emission time has elapsed, the stroboscopic microcomputer 200 sets the SEL1 and SEL0 terminals to Lo and Lo, selects the input of the data selector 206 as D0, that is, the Lo level input, and forces the output. The light emission control circuit 203 cuts off the discharge loop of the xenon tube 19 and ends the light emission.
[0081]
Next, in the case of [flash main light emission control], the flash microcomputer 200 calculates an appropriate light emission amount of the main light emission amount based on the light emission intensity corresponding to the main light emission amount instructed from the camera, and outputs the appropriate light emission amount to the DA0 output. A predetermined voltage is set. This predetermined voltage is obtained by adding or subtracting a voltage corresponding to the relative light emission amount with respect to the integral output read from AD1 at the end of the preliminary light emission.
[0082]
Subsequently, Hi and Lo are output to SEL1 and SEL0 to select the input D2. At this time, since the integration circuit is in an operation-inhibited state, the output of the integration circuit 208 input to the inverting input terminal of the comparator 204 is not generated, and the output of the comparator 204 is Hi, so that the light emission control circuit 203 is in a conductive state. Next, when a trigger signal is output from the TRIG terminal, the trigger circuit 202 generates a high voltage to excite the xenon tube 19 and light emission is started.
[0083]
In addition, the strobe microcomputer 200 sets the trigger noise due to the trigger application and sets the integration start terminal INT to Lo level 10 seconds after the actual light emission starts, and the integration circuit 208 outputs the output from the sensor 31 to the monitor circuit 207. Integrate via When the integrated output reaches a predetermined voltage set by DA0, the comparator 204 is inverted, the light emission control circuit 203 is cut off through the data selector 206, and light emission stops. On the other hand, the stroboscopic microcomputer 200 monitors the STOP terminal, and when the STOP terminal is inverted and the light emission is stopped, the SEL1 and SEL0 terminals are set to Lo and Lo to make the forced emission prohibited state and the integration start terminal is inverted. The integration is terminated and the light emission process is terminated.
[0084]
Next, verification of the validity of the integral amount at the time of preliminary light emission, which is the central processing of the present invention, will be described in detail.
[0085]
In the case of flat main light emission relative to the previous flat preliminary light emission, the output of the integration circuit 208 is not used because the light emission intensity of preliminary light emission and main light emission can be controlled only by setting a predetermined control voltage to the D / A conversion output. When the main light emission is flash light emission, as described in the conventional example, the output voltage of the integration circuit at the time of the flat preliminary light emission is read from the A / D conversion terminal DA0, and the voltage corresponding to the difference in the light amount of the main light emission is first read. By adding / subtracting to the integral voltage, the light emission amount of the main light emission is controlled.
[0086]
However, if the integration circuit malfunctions due to switching noise that occurs when flat pre-emission is performed and flat emission is maintained, accurate main emission control is not performed, and proper photography is impossible. In order to avoid this inconvenience, in this embodiment, a process for verifying the validity of the integration amount at the time of preliminary light emission is added, and if the integration circuit may malfunction due to noise, the integration amount at the time of preliminary light emission is used. However, the main light emission is controlled by using the “calculated integral amount” obtained by calculation based on the “reference integral amount” stored in the storage means at the time of adjustment as the predicted emission integral amount.
[0087]
If the light emission intensity (brightness) is originally stable when the flat preliminary light emission is performed, the light emission integral quantity can be obtained by the product of the light emission intensity and the light emission time. If the correspondence relationship between the preliminary light emission integral amount, which is the product of the predetermined light emission intensity and the light emission time at the time of light emission, is determined, the light emission integral amount at the time of preliminary light emission can be obtained by calculation.
[0088]
However, in actuality, the amount of light emission is slightly different for each light emission due to the circuit delay and the discharge being unstable at the beginning of the discharge of the arc tube. When calculated, there is some variation in the actual light emission amount. Therefore, in this embodiment, the "calculation integral amount" calculated by calculating the expected light emission integral amount during the preliminary light emission based on the stored "reference integral amount" is compared with the actual light emission integral amount as verification data, If the difference is within the predetermined amount, it is determined that the integration has been performed normally, and the main light emission is controlled based on the actual preliminary light emission integration amount. If the difference is greater than the predetermined value, the integration is normally performed due to noise. By determining that it is not performed and controlling the main light emission based on the “calculation integration amount”, even if the integration circuit does not operate normally due to noise, exposure accuracy that does not cause a practical problem is obtained. I am doing so.
[0089]
The procedure for calculating the “calculation integration amount” will be specifically described below.
FIG. 4 is a flowchart of the integration validity check by the stroboscopic microcomputer shown in FIG.
Referring to FIG. 4, as described in [Preliminary light emission], preliminary light emission is performed at a predetermined light emission intensity, and the light emission amount is integrated by the integration circuit 208 (S101).
[0090]
As a first step for obtaining the “calculation integral amount”, a difference between the light emission intensity and the preliminary light emission intensity when a reference integral amount described later is stored (S102).
As a second step for obtaining the “calculation integral amount”, a “preliminary light emission integral amount voltage correction value” is obtained based on the voltage of the main capacitor C1 (S103). Here, in practice, the light emission intensity is controlled so that the light emission amount of the preliminary light emission becomes a predetermined value of the main light emission regardless of the voltage of the main capacitor C1. This is because the amount of preliminary light emission is made variable in proportion to the energy stored in the main capacitor C1, so that the amount of preliminary light emission is reduced when the voltage of the main capacitor C1 is low, thereby avoiding wasteful consumption of energy. In addition, it is possible to easily determine whether or not the main light emission can be performed by a simple rule that the main light emission amount can be obtained up to a predetermined value times the preliminary light emission at any voltage.
[0091]
The “preliminary light emission integral amount voltage correction value” indicates that the energy U stored in the main capacitor C1 is U = 1/2 · CV where the voltage of the main capacitor C1 is V and the capacitance is C. ² If the preliminary light emission is not performed in a fully charged state, it changes as the square of the light emission amount voltage. Therefore, since the light emission integral amount indicating the light emission amount also changes with the square of the voltage as a count, the “preliminary light emission integral amount voltage correction value” is calculated from the following equation. Voltage correction value = LOG ₂ (K · Vmc ² / Vfull ² )
However,
Vfull: voltage of main capacitor C1 at full charge
Vmc: Current voltage of the main capacitor C1
k: Loss correction coefficient due to internal resistance of light emission control element and power supply
(This integration amount voltage correction value is stored in a ROM (not shown) in the flash microcomputer 200 as a result of calculation corresponding to the main capacitor voltage, and stored in accordance with the main capacitor voltage. May be used as a map method).
[0092]
Subsequently, the light emission intensity difference obtained in S102 and the “preliminary light emission integral amount voltage correction value” calculated in S103 are added to obtain “preliminary light emission integral correction amount” as a final correction amount (S104).
The “reference integration amount” corresponding to the zoom position read from ZM0 to ZM2 and the predetermined light emission intensity is read from EEPROM 0M210 which is a writable storage means (S105). The setting of the “reference integration amount” will be described later.
By adding the “reference integral amount” read in S105 and the “preliminary light emission integral correction amount” obtained in S104, the “calculation integral amount” of the expected light emission integral amount to be obtained with a predetermined preliminary light emission intensity is obtained (S106). ).
[0093]
When the difference obtained by subtracting the “calculation integral amount” obtained in S106 from the actual integral amount obtained during the preliminary light emission in S101 is equal to or larger than a predetermined value, that is, when the actual integral amount during the preliminary light emission is larger than the predetermined value. If it is determined that the integration during preliminary light emission may cause malfunction due to noise, the process proceeds to S109. If the difference is within the predetermined value, it is determined that the integration has been normally performed, and the process proceeds to S108 (S107).
The integral amount at the time of actual preliminary light emission is used as a preliminary initial weather integral amount that becomes a reference when performing main light emission by flash light emission (S108).
[0094]
The “calculation integral amount” used in S106 is used as a preliminary light emission integral amount used as a reference when performing main light emission by flash light emission (S109).
The amount of light emission during main light emission is received from the camera side via the serial communication terminal 22 (S110).
[0095]
Based on the preliminary light emission integral amount obtained in S108 or S109 and the main light emission amount received in S110, as described in the previous section [Flash main light emission control], a predetermined voltage at which proper main light emission is obtained at the DA0 output. Is set (S111).
Flash main light emission control is performed (S112).
[0096]
Next, the setting of “reference integration amount” at the time of adjustment will be described.
“Reference integration amount” is an output voltage of the integration circuit 208 under a predetermined light emission condition, that is, a predetermined light emission irradiation angle, a predetermined main capacitor voltage, and a predetermined light emission intensity. The “reference integration amount” is the integration amount at the time of full flash, and the integration amount is measured by the light receiving means built in the strobe at each zoom position and stored in the EEPROM 210 (this is the standard integration amount). It is also possible to measure and store the integrated quantity measurement results for the light emission intensity and light emission time under typical flat preliminary light emission conditions for each zoom position).
[0097]
FIG. 5 is a flowchart of the reference integration amount setting process by the strobe microcomputer shown in FIG.
Referring to FIG. 5, the zoom position drive target is determined at the first zoom position to be adjusted (S201).
[0098]
The current zoom position read by the zoom position detection encoder 215 is compared with the zoom drive target position, a predetermined drive signal is output to Z1 and Z0, the zoom drive motor 212 is driven, and the reflector 20 is moved to the predetermined zoom position. The light emitting unit including the arc tube 19 is moved (S202).
The divided voltage of the main capacitor C1 input to the AD0 port is A / D converted, and the voltage of the main capacitor C1 is read (S203).
If the voltage of the main capacitor C1 is in a fully charged state, the process proceeds to S205, and if it is equal to or lower than the full charged voltage, the process returns to S203 to wait for a full charged state (S204).
[0099]
In order to emit full light at the time of full charge, the maximum voltage is output to the DA0 terminal (S205).
The comparator 204 is selected by outputting Hi and Lo to the SEL1 and SEL0 terminals (S206).
A trigger generation signal is output from the TRIG terminal to start light emission of the xenon tube 19, and at the same time, a timer (not shown) in the stroboscopic microcomputer 200 that measures the time until the light emission ends is started (S207).
[0100]
Trigger noise due to the high voltage trigger is settled, and integration is started by setting the integration terminal INT to Lo 10 seconds after the actual light emission is started (S208).
The timer started in S207 is counted and waits for a predetermined time until the light emission is completed (S209).
The output of the integration circuit 208, that is, the light emission integral amount is read from the AD1 terminal (S210).
The “reference integration amount” obtained by the above-described processing is written in the EEPROM 210 as a writable storage means in correspondence with the zoom position, and the reference integration amount measurement processing at the first zoom position is ended (S211).
[0101]
In order to repeat the above process for each zoom position, the current zoom position is compared and if it is not the final position, the process proceeds to S213, and when the process is completed up to the final position, the "reference integration amount" writing process is terminated (S212). .
In order to move to the next zoom position, a predetermined amount is added to the current zoom position, the next zoom position is set, the process returns to S202, and the above is repeated until the “reference integration amount” at all zoom positions is stored. The process is repeated (S213).
[0102]
Note that this process may be performed only for representative zoom positions, and “reference integration amounts” at other zoom positions may be obtained based on differences from integral values obtained in advance at zoom positions.
[0103]
Based on the “reference integration amount” obtained in this way, the “calculation integration amount” is calculated, and the malfunction of the integration circuit due to the generation of integration noise during preliminary light emission is verified.
[0104]
As described above, according to the first embodiment, as means for verifying the validity of the integral amount of light emission during preliminary light emission for correcting the integral error due to noise during preliminary light emission, a predetermined light emission amount (each Integration amount storage means configured by the EEPROM 210 or the like for storing the output of the integration circuit 208 (integration amount at the time of full flash by full charge at each zoom position), and the integration amount stored as the reference = “reference integration amount” ”To calculate the“ calculated integral amount ”as the expected integral amount of the light emission intensity at the previous preliminary light emission, and compare the calculated“ calculated integral amount ”with the integrated output obtained by integrating the actual light emission at the preliminary light emission. If the difference is greater than or equal to a predetermined value as a result of the comparison, it is determined that there is an integration error during preliminary light emission, and the main light emission is generated based on the `` calculation integral amount ''. Since it is configured to control an amount, even if integrated by the noise emission means at the time of the preliminary light emission control occurs is not performed correctly, has allowed proper flash photography.
[0105]
(Second embodiment)
Next, a second embodiment of the present invention will be described.
[0106]
In the previous embodiment, only when an integration error due to noise during preliminary light emission occurs, the main light emission is controlled by the “calculated integral amount”. In the second embodiment, the main light emission is always controlled by the “calculated integral amount”. It is what you do.
[0107]
As described in the first embodiment, the light emission amount during flat preliminary light emission is obtained as the product of the light emission intensity and the light emission time if the light emission intensity (light emission luminance) is stable. However, in actuality, the amount of light emission slightly changes for each light emission due to the delay of the circuit and the discharge being unstable at the beginning of the discharge of the arc tube, etc., and when the main light emission amount is set as a relative amount, The main light emission amount is determined based on the “calculation integral amount” that is a fixed value, and there is a problem that the main light emission amount varies somewhat.
[0108]
However, the variation in the amount of preliminary light emission depends on the selection of the light emitting tube 19 and the position of the light receiving means 32 that performs preliminary light emission control, that is, the light receiving sensor 32 is disposed so as to receive the entire light of the light receiving tube 19. In practice, the above-described considerations are made in the second embodiment, and the “calculated integration amount” calculated based on the “reference integration amount” without performing the preliminary light emission integration. The light emission control of the main light emission is performed only by “”.
[0109]
Note that the hardware configuration of the strobe device of the second embodiment is the same as the electric circuit block diagram of the previous embodiment shown in FIG. 3, and therefore, a redundant description of the configuration is omitted, and FIG. It shall be diverted as it is.
[0110]
FIG. 6 is a flowchart of the light emission operation of the strobe device according to the second embodiment of the present invention.
Hereinafter, the light emission operation will be described with reference to FIG.
The stroboscopic microcomputer 200 performs preliminary light emission with a predetermined light emission intensity according to the program in the same procedure as described in the [preliminary light emission] control of the previous embodiment. At this time, the integration by the integration circuit 208 is not particularly performed (S301).
[0111]
As a first step for obtaining the “calculation integral amount”, a difference between the reference light emission intensity at the time of measuring the “reference integral amount” and the preliminary light emission intensity at the time of preliminary light emission is obtained (S302).
As a second step for obtaining the “calculation integral amount”, a “preliminary light emission integral amount voltage correction value” based on the voltage of the main capacitor C1 is obtained. The calculation method is based on the procedure of S103 of the previous embodiment (S303).
A “preliminary light emission integral correction amount” obtained by adding the light emission intensity difference obtained in S302 and the “preliminary light emission integral amount voltage correction value” calculated in S303 is obtained as a correction amount (S304).
[0112]
Next, the “reference integration amount” corresponding to the zoom position is read from the EEPROM 210 which is a writable storage means (S305).
By adding the “reference integral amount” read in S305 and the “preliminary light emission integral correction amount” obtained in S304, an “calculated integral amount” that is a predicted light emission integral amount at a predetermined preliminary light emission intensity is obtained (S306). .
[0113]
The amount of light emission during main light emission is received from the camera via the serial communication terminal 22 (S307).
Based on the “calculated integral amount” obtained in S306 and the main light emission amount obtained in S307, a predetermined voltage that provides an appropriate main light emission intensity is set to the DA0 output by the procedure described in [Light main light emission control] ( S308).
Subsequently, the main light emission control is performed (S309).
[0114]
As described above, according to the second embodiment, since the main light emission is controlled without using the integral of the actual light emission amount that may cause a malfunction due to the influence of noise during the preliminary light emission, it is stored in the EEPROM 210 at the time of adjustment. Based on the “reference integral amount”, the “calculation integral amount” is calculated, and the light emission amount of the main light emission is controlled based on the “calculation integral amount”. Advantages of being able to perform accurate strobe photography without being affected, and to greatly simplify the circuit by eliminating the need for circuit shielding and guard ring processing to suppress circuit noise during preflash. There is also.
[0115]
(Third embodiment)
Next, a third embodiment of the present invention will be described.
[0116]
The third embodiment is a variable that is an integration level adjusting means so that the integrated output voltage becomes a predetermined value at the time of adjustment for a strobe device having no storage means such as the writable storage means EEPROM 210 as in the previous embodiment. Adjusted by resistance, the “calculation integral amount” is calculated based on the adjusted predetermined level (reference integral amount), and compared with the integral amount at the time of actual preliminary light emission, the validity of the integral is judged. When it is determined to be normal, the main light emission is controlled based on the actual preliminary light emission integral amount, and when it is determined that the integration is not performed normally, the main light emission is controlled by the “calculation integral amount”. Is.
[0117]
FIG. 7 is an electric circuit block diagram of a strobe device according to the third embodiment of the present invention. In FIG. 7, reference numeral 318 denotes a variable resistor as an integration amount adjusting means for adjusting the integration level to a predetermined amount as an alternative to the “reference integration amount” in the previous embodiment. In addition, the storage means EEPROM 210 is not installed this time. Other configurations are the same as those in FIG.
[0118]
FIG. 8 is a circuit diagram of the monitor circuit and the integration circuit shown in FIG.
In FIG. 8, reference numeral 301 constituting the monitor circuit 207 is an operational amplifier, and 302 and 303 are resistors, which constitute a first-stage amplifier that amplifies the photocurrent of the light receiving means 31. Reference numeral 304 denotes an operational amplifier, and reference numeral 305 denotes a diode, which is a LOG amplifier that logarithmically converts the photocurrent of the light receiving element 31. The integrating circuit 208 charges the capacitor 313 via the resistor 312 by the output of the operational amplifier 304 and integrates the logarithmically compressed photocurrent. This integration is controlled to be stopped and started by a switching means composed of resistors 309 and 310 and a transistor 311.
[0119]
This integrated output is amplified by a buffer amplifier including resistors 314 and 316 and an operational amplifier 315, and is output from an output terminal Iout. Further, the integral output is level-shifted by a variable resistor 318 for adjusting the integral output, one of which is connected to a reference voltage, so that the integral level is adjusted.
[0120]
FIG. 9 is a flowchart of the light emission operation of the strobe device shown in FIG.
Next, the light emission operation will be described with reference to FIG.
First, preliminary light emission is performed at a predetermined light emission intensity according to the previous [preliminary light emission] procedure, and the light emission amount is integrated by the integration circuit 208 (S401).
[0121]
As a first step for obtaining the “calculation integral amount”, a difference in light emission intensity between the light emission intensity when the integration level is adjusted by the resistor 318 and the preliminary light emission intensity is obtained (S402). As a second step for obtaining the “calculation integral amount”, a “preliminary light emission integral amount voltage correction value” based on the voltage of the main capacitor C1 is obtained. The calculation method is the same as S103 in the previous embodiment (S403).
The “preliminary light emission integral amount voltage correction value” calculated in S403 is added to the light emission intensity difference obtained in S402 to obtain a “preliminary light emission integral correction amount” (S404).
[0122]
At the predetermined light emission level, the output level (reference integration amount) of the integration circuit 208 adjusted to the predetermined integration level and the “preliminary light emission reference integral correction amount” obtained in S404 are added to obtain a predetermined preliminary light emission intensity. The “calculation integration amount” to be obtained in step S405 is obtained (S405).
[0123]
The actual integration amount obtained during the preliminary light emission in S401 is compared with the “calculation integral amount” obtained in S405. If the difference is equal to or greater than a predetermined value, the integration during the preliminary light emission may have malfunctioned due to noise. If it is determined that there is, the process branches to S408, and if the difference is within the predetermined value, it is determined that the integration has been normally performed, and the process branches to S407 (S406).
[0124]
The integral amount at the time of actual preliminary light emission is used as the preliminary light emission integral amount as a reference in flash main light emission (S407).
The “calculation integral amount” obtained in S405 is used as a preliminary light emission integral amount that becomes a reference in the flash main light emission (S408).
[0125]
The amount of light emitted during the main light emission is received from the camera via the serial communication terminal 22 (S409).
Based on the preliminary light emission integral amount obtained in S407 or 408 and the main light emission amount received in S409, a predetermined voltage that provides an appropriate main light emission intensity is set in the DA0 output by the flash main light emission control described above (S410). .
Flash main light emission control is performed (S411).
[0126]
As described above, according to the third embodiment, as a means for verifying the validity of the integral amount of light emission at the time of preliminary light emission for correcting the integral error due to noise at the time of preliminary light emission, the integrated output voltage is adjusted at the time of adjustment. The integration level adjustment unit 318 adjusts the value so as to obtain a predetermined value, obtains the “calculation integration amount” from the adjusted “reference integration amount”, and compares the output of the integration unit 208 during preliminary light emission with the “calculation integration amount”. Thus, the validity of the integration during the preliminary emission is verified, and if the compared difference is equal to or larger than the predetermined value, it is determined that an integration error has occurred during the preliminary emission, and the main emission is controlled based on the “calculated integral amount”. As a result, even in a flash device having no storage means such as the EEPROM 210, accurate flash photography can be performed without being affected by noise generated by the light emission control means during the preliminary light emission control.
[0127]
(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described.
[0128]
In the fourth embodiment, as described in the second embodiment, in the hardware configuration having no storage means such as an EEPROM as in the third embodiment shown in FIG. Thus, the main light emission is controlled.
[0129]
Since the hardware configuration of the fourth embodiment is the same as that of the third embodiment of FIG. 7, the description of the overlapping configuration is omitted, and FIG. 3 is used for the following operation description.
[0130]
FIG. 10 is a flowchart of the light emission operation of the strobe device according to the fourth embodiment of the present invention.
[0131]
Next, the light emission operation will be described with reference to FIG.
The strobe microcomputer 200 performs preliminary light emission at a predetermined light emission intensity by the [preliminary light emission] control as described above. At this time, the integration by the integration circuit 208 is not particularly required (S501).
[0132]
As a first step for obtaining the “calculation integration amount”, a difference between the reference emission intensity adjusted for the integration level by the integration adjusting resistor 318 and the emission intensity of the preliminary emission is obtained (S502).
As a second step for obtaining the “calculation integral amount”, a “preliminary light emission integral amount voltage correction value” is obtained from the voltage of the main capacitor C1. The method for obtaining is the same as the procedure obtained in the previous S103 (S503).
The “preliminary light emission integral correction amount” is obtained by adding the light emission intensity difference obtained in S502 and the “preliminary light emission integral amount voltage correction value” obtained in S503 (S504).
[0133]
The output level (reference integration amount) of the integration circuit 208 adjusted to a predetermined integration level at the predetermined emission level and the “preliminary emission integration correction amount” obtained in S504 are added to obtain the predetermined emission intensity. The power “calculation integration amount” is obtained (S505).
[0134]
The amount of light emission during main light emission is received from the camera via the serial communication terminal 22 (S506).
Based on the preliminary light emission integral amount obtained in S505 and the main light emission amount received in S506, a predetermined voltage that provides an appropriate main light emission intensity is set in the DA0 output based on the above-mentioned [flash main light emission control] (S507). .
The main light emission control is performed (S508).
[0135]
As described above, according to the fourth embodiment, in order to control the main light emission without using the integral of the actual light emission amount that may cause a malfunction due to the influence of noise during the preliminary light emission, the integrated output voltage during the adjustment is adjusted. Is adjusted by the integral level adjusting means 318 so that the value becomes a predetermined value, and from the adjusted integral amount = “reference integral amount”, the “calculated integral amount” in the light emission intensity at the time of preliminary light emission is calculated. Therefore, accurate flash photography is possible without being affected by the noise generated by the light emission control means during pre-flash control, and the effect of noise during pre-flash is controlled. There is an advantage that the circuit shielding and guard ring processing for suppression are unnecessary, and the circuit can be greatly simplified as compared with the third embodiment.
[0136]
【The invention's effect】
According to the first aspect of the present invention, preliminary light emission is performed and the reflected light from the subject is measured, and at the same time, the light emission amount of the arc tube is integrated, and the light emission amount of the main light emission is based on the photometry result and the integral amount of the preliminary light emission. In the strobe device for determining the reference, the reference integral amount under a predetermined light emission condition is stored in the storage means at the time of adjustment, and the actual preliminary light is integrated during preliminary light emission, and the light is emitted based on the reference integral amount stored in the storage means. Calculating the expected integral amount Calculate the integral amount, verify the appropriateness of the preliminary emission from the difference, and if the integral is determined to be normal, control the main flash by the integral amount of the preliminary emission, and if not, calculate Since the main light emission is controlled based on the integration amount, proper flash photography can be performed even when the integration is not normally performed due to the generated noise.
[0137]
According to the second aspect of the present invention, preliminary light emission is performed to measure the reflected light from the subject, and at the same time, the light emission of the main light emission is integrated based on the photometry result of the preliminary light emission and the integrated amount by integrating the light emission of the arc tube. In a strobe device that determines the reference integral amount under a predetermined light emission condition during adjustment, it is stored in the storage means, and the calculated integral amount is calculated from the stored reference integral amount as the predicted light emission integral amount during preliminary light emission. Controlling the main flash with the calculated integral amount enables accurate flash photography that is not affected by the noise generated by the flash control means during preliminary flash control, and greatly simplifies the circuit. Become.
[0138]
According to the third aspect of the present invention, preliminary light emission is performed and the reflected light from the subject is measured, and at the same time, the light emission of the arc tube is integrated, and the light emission amount of the main light emission is determined based on the photometry result of the preliminary light emission and the integrated amount. In the strobe device to be determined, as the estimated integral amount of preliminary light emission based on the reference integral amount adjusted by the integral adjusting unit that adjusts so that the output of the integrating unit under a predetermined light emission condition becomes a predetermined amount at the time of adjustment. Calculate the calculation integration amount and verify the validity of the preliminary flash based on the difference. If the preliminary flash integration is normal, the main flash is controlled by the integral of the preliminary flash, and the integration is performed normally. If not, the main flash is controlled based on the calculated integration amount, so that even if the flash unit does not have rewritable storage means, even if the integration is not performed correctly due to the flash noise, proper flash photography is possible. It can be carried out.
[0139]
According to the fourth aspect of the present invention, preliminary light emission is performed and the reflected light from the subject is measured, and at the same time, the light emission amount of the arc tube is integrated, and the light emission amount of the main light emission based on the photometry result and the integral amount of the preliminary light emission. In the strobe device that determines the light emission integral expected amount of the preliminary light emission based on the reference integral amount adjusted by the integral adjustment means that adjusts the output of the integration means under a predetermined light emission condition to be a predetermined amount at the time of adjustment. By calculating a certain calculation integral amount and controlling the main flash with this calculation integral amount, even in a strobe device having no rewritable storage means, the influence of noise generated by the light emission control means during the preliminary light emission control is reduced. This makes it possible to perform accurate strobe photography that is not received, and greatly simplifies the circuit.
[0140]
According to the fifth aspect of the present invention, since the preliminary light emission is performed by flat light emission performed at a predetermined light emission intensity for a predetermined time, the flat light emission is performed to integrate the light emission amount and the light emission amount of the main light emission. Can be controlled.
[0141]
According to the sixth aspect of the present invention, since the predetermined light emission condition at the time of adjustment is the flash full light emission when the main capacitor is fully charged, the flash full light emission when the main capacitor voltage is fully charged is the predetermined light emission. A reference integral amount can be obtained as a condition and used for the main light emission control.
[0142]
According to the seventh aspect of the present invention, the preliminary light emission condition is determined based on at least one piece of information on the subject distance, the subject luminance, or the voltage of the main capacitor. It is possible to determine the preliminary light emission conditions and calculate the calculation integration amount.
[0144]
Claim 8 According to the invention described in (4), as the reference integration amount, the integration amount at the time of flash full emission in the fully charged state of the main capacitor is measured for each zoom position and stored in the storage means. The integration amount under the conditions can be obtained as a reference integration amount for each zoom position, stored in the storage means, and used as reference information for the main light emission control.
[0145]
Claim 9 According to the present invention, the calculation integration amount is calculated by adding the preliminary light emission reference integration correction amount obtained based on the main capacitor voltage to the reference integration amount, so the calculation integration amount is calculated based on the reference integration amount. The amount of main light emission can be controlled by obtaining the integral amount.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a camera equipped with a strobe device according to a first embodiment of the present invention.
2 is an electric circuit block diagram of the camera shown in FIG. 1. FIG.
3 is an electric circuit block diagram of the strobe device shown in FIG. 1. FIG.
4 is a flowchart of integration validity check by the stroboscopic microcomputer shown in FIG. 3;
5 is a flowchart of a reference integration amount setting process by the strobe microcomputer shown in FIG.
FIG. 6 is a flowchart of the light emission operation of the strobe device according to the second embodiment of the present invention.
FIG. 7 is an electric circuit block diagram of a strobe device according to a third embodiment of the present invention.
8 is a circuit diagram of a monitor circuit and an integration circuit shown in FIG.
9 is a flowchart of integral validity check by the stroboscopic microcomputer shown in FIG.
FIG. 10 is a flowchart of the light emission operation of the strobe device according to the fourth embodiment of the present invention.
FIG. 11 is an electric circuit block diagram of a conventional strobe device.
12 is a diagram showing normal operation waveforms of the strobe device shown in FIG. 11. FIG.
13 is a diagram showing a malfunction waveform of the strobe device shown in FIG. 11. FIG.
[Explanation of symbols]
1 Camera body
2 Main mirror
3 Focus plate
4 Penta prism
5 Finder
7 Photometric sensor
8 Shutter
10 Mount contact
11 Lens barrel
12-14 lenses
15 Aperture
16 Lens drive motor
17 Aperture drive motor
18 External strobe
19 Xenon tube
20 Reflector
21 Fresnel lens
22 Strobe contact group
25 Submirror
26 Focus detection unit
31, 32 light receiving element
100 camera microcomputer
105 Focus detection circuit
106 Photometric circuit
107 Shutter control circuit
108 Motor control circuit
109 Film run detection circuit
110 Switch sense circuit
111 LCD drive circuit
112 Lens microcomputer
200 Strobe microcomputer
201 DC-DC converter
202 Trigger circuit
203 Light emission control circuit
204,205 Comparator
206 Data selector
207, 209 Monitor circuit
208 Integration circuit
210 EEPROM
211 Motor drive circuit
212 Zoom drive motor
215 Zoom position detection encoder
216 LED
217 Power switch
318 Variable resistor for adjustment

Claims (9)

A strobe having means for performing preliminary light emission toward the subject, photometric means for measuring reflected light from the subject during the preliminary light emission, and calculating means for calculating the light emission intensity of the main light emission according to the photometric result from the photometric means In the device
A monitor means for monitoring the light emitting means, an integrating means for integrating the output of said monitor means, an integration output storage means for storing as a reference integrated amount an output of said integrating means at Jo Tokoro of light emission condition, upon shooting A calculation integration amount calculating means for performing the preliminary light emission and calculating an operation integration amount as a predicted light emission integration amount under a predetermined preliminary light emission condition based on a reference integration amount stored in the integral output storage means; When the difference between the output of the integrating means in light emission and the calculated integral amount by the calculation integral amount calculating means is within a predetermined value, the light emission amount of the main light emission is controlled based on the output of the integrating means, and the difference between the outputs becomes a predetermined value. A flash device comprising light emission control means for controlling the light emission amount of the main light emission based on the calculation integration amount by the calculation integration amount calculation means when exceeding. A strobe having means for performing preliminary light emission toward the subject, photometric means for measuring reflected light from the subject during the preliminary light emission, and calculating means for calculating the light emission intensity of the main light emission according to the photometric result from the photometric means In the device
A monitor means for monitoring the generated light from the light emitting means, an integrating means for integrating the output of said monitor means, an integration output storage means for storing as a reference integrated amount an output of said integrating means at Jo Tokoro of light emission condition, A calculation integration amount calculating means for performing the preliminary light emission at the time of photographing and calculating an operation integration amount as a light emission integration expected amount under a predetermined preliminary light emission condition based on a reference integration amount stored in the integral output storage means; A strobe device comprising a light emission control means for controlling the light emission amount of the main light emission based on the calculation integration amount by the calculation integration amount calculation means at the time of main light emission. A strobe having means for performing preliminary light emission toward the subject, photometric means for measuring reflected light from the subject during the preliminary light emission, and calculating means for calculating the light emission intensity of the main light emission according to the photometric result from the photometric means In the device
A monitor means for monitoring the light emitting means, the integral amount of the output of the integrating means and said integrating means at Jo Tokoro of light emission condition for integrating the output of said monitor means is adjusted to reference integrated value of the predetermined amount An adjustment unit, an arithmetic integration amount calculation unit that performs the preliminary light emission at the time of photographing and calculates an arithmetic integration amount as an expected light emission integration amount under a predetermined preliminary light emission condition based on the adjusted reference integral amount; When the difference between the output of the integration means in the preliminary light emission and the calculated integration amount by the calculation integration amount calculation means is within a predetermined value, the light emission amount of the main light emission is controlled based on the output of the integration means, and the difference between the outputs is a predetermined value. A flash device comprising a light emission control means for controlling the light emission amount of the main light emission based on the calculation integration amount by the calculation integration amount calculation means when the value exceeds. A strobe having means for performing preliminary light emission toward the subject, photometric means for measuring reflected light from the subject during the preliminary light emission, and calculating means for calculating the light emission intensity of the main light emission according to the photometric result from the photometric means In the device
A monitor means for monitoring the light emitting means, the integral amount of the output of the integrating means and said integrating means at Jo Tokoro of light emission condition for integrating the output of said monitor means is adjusted to reference integrated value of the predetermined amount An adjustment integration means, an arithmetic integration amount calculation means for performing the preliminary light emission at the time of photographing and calculating an operation integration amount as an expected light emission integration amount under a predetermined preliminary light emission condition based on the adjusted reference integral amount; A strobe device comprising light emission control means for controlling a light emission amount of main light emission based on a calculation integration amount by the calculation integration amount calculation means at the time of main light emission.   5. The strobe device according to claim 1, wherein the preliminary light emission is flat light emission performed at a predetermined light emission intensity for a predetermined light emission time. Flash device according to one of claims 1 to 4 to the light emitting condition of the plant constant, wherein the voltage of the main capacitor for storing emission energy of the flash full emission at full charge.   5. The strobe device according to claim 1, wherein the predetermined preliminary light emission condition is determined based on at least one information of a subject distance, a subject luminance, or a voltage of a main capacitor. 3. The strobe device according to claim 1, wherein the reference integration amount is obtained by measuring an integration amount at the time of full flash emission when the main capacitor is fully charged at each zoom position, and storing the integration amount in an integration output storage unit. .   5. The strobe device according to claim 1, wherein the calculation integration amount is obtained by adding a preliminary light emission reference integration correction amount calculated based on a voltage of a main capacitor to the reference integration amount.

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