JP2550385B2 - Red-eye prevention control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION A. Field of Industrial Application The present invention relates to a red-eye prevention control device for preventing a red-eye phenomenon during flash photography.

B. Conventional Technology The red-eye phenomenon means that the human eye shines red or gold in color photography using an electronic flash device. This phenomenon occurs when the flash light of the light emitting portion of the electronic flash device that has passed through the pupil of the eye is reflected by the retina portion and the reflected light is reflected on the film. There are many capillaries in the retina of the eye, and the hemoglobin in the blood is red, so the reflected light appears reddish.

It has been empirically known that the red-eye phenomenon is prominent in photographs under the following conditions.

1) When the shooting environment is dark The size of the pupil of the human eye changes depending on the brightness of the surroundings, and when it is dark, its diameter expands to about 7-8 mm. At this time, since the amount of incident light and the amount of reflected light on the eye are large, the red-eye phenomenon is naturally conspicuous.

2) When the distance between the light emitting part of the electronic flash device and the optical axis of the photographing lens is short The retina part of the eye has a considerably high reflectance and at the same time the directivity of reflection is also high. Therefore, if the light emitting unit of the electronic flash device and the optical axis of the photographing lens are close to each other and there are three elements (the light emitting unit, the photographing lens, and the eye) in the positional relationship in which the specularly reflected light from the retina is likely to enter the photographing lens, Eyes develop strongly. That is, when the pupil of the person who is the subject sees the photographing lens and the light emitting portion of the flash light source at an angle smaller than a certain small angle, the red eye always occurs. Empirically, this angle is about 2-2.5 degrees. Therefore, if the light emitting section of the electronic flash device is separated from the optical axis of the photographing lens, the occurrence of red eye is prevented, but there is a limit due to the distance from the camera to the subject (hereinafter referred to as the subject distance), and the subject distance is equal to or greater than a predetermined value. It is difficult to avoid red eyes.

Therefore, a technique for preventing the red eye phenomenon has been conventionally known. For example, in the July 1952 issue of "psa JOURNAL,"
A method is disclosed in which the eyes are habituated to a bright environment before shooting, and a red light is prevented by hitting a flash with the pupil reduced to 3 mm or less. Further, Japanese Patent Publication No. 58-48088 discloses that a pre-irradiation is performed by a pre-irradiation lamp before photographing for a time required for the pupil to close, and the main flash device of A technique is disclosed in which a light emitting unit emits light to take a photograph. In addition,
In Japanese Patent No. 58-9130, two flash discharge tubes are provided, one discharge tube is pre-lighted to close the pupil, and then the second discharge tube is main-lighted (main flash) for actual photographing. A method of doing is disclosed.

A camera equipped with such a conventional device is usually equipped with a lamp that detects the charging state of the main flash device under flash shooting conditions and notifies the completion of charging. Therefore, generally, the camera operator confirms the completion of charging with the lamp and then performs the release operation.

However, there are times when it is desirable to perform a release operation before charging is completed, and a camera that adopts the release priority method allows flash photography by the release operation even if charging is not completed. On the other hand, there is a high possibility that the battery will be underexposed when the charging is not completed, so a camera that releases the lock before charging is also known.

On the other hand, as the above-mentioned pre-irradiation method, (a) light is emitted for pre-irradiation by pressing the release halfway,
A camera that emits the main flash device for illuminating the subject with subsequent full-press operation, or (b) Pre-illumination emission for the first time by pressing the release button fully,
There is a camera that causes the main flash device to emit light after a predetermined time has elapsed.

(C) Alternatively, an operation button for pre-irradiation provided separately from the release button is provided, and before operating the release button, the illumination hole for pre-irradiation is projected onto the subject by the operation of this operation button to reduce the pupil. A camera that performs a flash operation by performing a release operation is also known.

C. Problems to be Solved by the Invention However, in the release-priority type camera, if the above-mentioned red-eye prevention pre-irradiation is always performed prior to the main flash during flash photography, Even though the main capacitor allows photography even if the charging is not completed, there is a possibility that a photo delay occurs from the pre-irradiation for red-eye prevention to the main flash, and a photo opportunity may be missed.

Even in a camera that locks the shutter when charging is not completed, if the pre-irradiation method of (b) above is adopted, the shutter will be locked halfway and pre-irradiation will be performed by pressing halfway, which is a waste. The battery is exhausted. Also, in the case of adopting the pre-irradiation method of the above (c), the pre-irradiation is performed by the pre-irradiation operation member even though the release is locked, and the battery is wasted.

An object of the present invention is to prevent light emission for red-eye prevention so as not to miss a photo opportunity when the main flash device is not fully charged, and to prevent unnecessary battery consumption. It is to provide a control device.

D. Means for Solving the Problems Explaining with reference to FIG. 1 (a) which is a diagram corresponding to claims, the red-eye prevention control device for a camera according to the invention of claim 1 outputs a flash command output means for outputting a main flash command. 101, a main capacitor 10a, an electronic flash device 10 that illuminates the subject with illumination light by causing the arc tube Xe1 to emit light by the charge stored in the main capacitor 10a in response to a main flash command, and red-eye generation based on shooting conditions The presence or absence of the red eye, the red eye determination means 102 that outputs a red eye prevention command when the occurrence of red eye is determined, and a red eye prevention light emitting device 11 that emits red eye prevention irradiation light to the subject based on the red eye prevention command, Main capacitor 10a
The first charging state detecting means 103 for detecting the charging state of the second eye and outputting the first charging completion signal when the charging is completed, the red-eye prevention command and the main flashing command are output when the release operation is performed, and When the charge completion signal of 1 is output,
The red-eye prevention light-emitting device 11 is activated, and then the electronic flash device 10 is activated when a predetermined time elapses; the first-eye command is issued even if the red-eye prevention command and the main flash command are output when the release operation is performed. When the charging completion signal is not output, the above problem is solved by including the control means 104 that operates the electronic flash device 10 without operating the red-eye preventing light emitting device 11.

Explaining with reference to FIG. 1 (b) which is a claim correspondence diagram, the red-eye prevention control device for a camera according to the invention of claim 3 includes a main flash command output means 101 for outputting a main flash command,
An electronic flash device 10 that has a main capacitor 10a and that illuminates the subject with illumination light by causing the arc tube Xe1 to emit light by the charge stored in the main capacitor 10a according to the main flash command, and a red-eye prevention command output that outputs a red-eye prevention command. Means 202 and the red-eye prevention light-emitting device 11 for irradiating the subject with red-eye prevention irradiation light based on the red-eye prevention command, and the charging state of the main capacitor 10a are detected, and a first charging completion signal is output when charging is completed. If the first charging completion signal is output when the red-eye prevention command is output and the first charge-state detecting unit 103, the operation of the red-eye prevention light-emitting device 11 is permitted, and the red-eye prevention command is output. When the first charging completion signal is not output during the operation, the control means 104 for inhibiting the operation of the red-eye preventing light emitting device 11 is provided to solve the above problems.

E. Action In the present invention, the red-eye prevention light-emitting device 11 operates under the condition that the red-eye prevention signal, the main flash command, and the first charging completion signal are output, and so-called pre-irradiation is performed, and thereafter, When a predetermined time has elapsed, the electronic flash device 10 can be operated to perform flash photography. In the apparatus according to the first aspect, the presence / absence of red-eye occurrence is automatically determined on the camera side according to the shooting conditions.

F. Example-First Example-A first example of the present invention will be described with reference to FIGS.

In FIG. 2 showing the overall configuration, a lens drive circuit 2, a focus detection circuit 3, a photometric circuit 4, and a camera control circuit 5 are connected to a CPU 1 by a signal transmission line BL1. The focus detection circuit 3 has a pair of light receiving elements such as CCDs,
A pair of subject images are formed on these light receiving elements through the taking lens RE and a pair of lenses (not shown), and the image forming surface of the subject and the planned image forming surface are formed based on the electric signals from the respective light receiving elements. A focus detection signal indicating the shift amount and its direction is output to the CPU 1. The photometric circuit 4 has a light receiving element that receives light from a subject, and outputs the output of this light receiving element to the CPU 1 as photometric data.

An exposure control device 6 such as an aperture and a shutter and a display device 7 such as a liquid crystal display are connected to the camera control circuit 5. The camera control circuit 5 displays information related to photographing such as an exposure value and a shutter speed on the display device 7 according to a command from the CPU 1 and drives the exposure control device 6 to perform photographing.

A motor 9 for driving the focusing lens 8 is connected to the lens driving circuit 2. The motor 9 is driven and controlled by a lens driving signal from the CPU 1 to drive the focusing lens 8 to perform focusing. Here, the lens drive signal is a signal formed by the CPU 1 based on the focus detection signal described above.

The CPU 1 includes an external electronic flash device 10 and a red-eye prevention light emitting device integrally formed with the electronic flash device 10.
11 is connected. The electronic flash device 10 controls a xenon tube Xe1 as a light emitting element, a main capacitor 10a for storing a charge for emitting the xenon tube Xe1, a charging circuit 10b for charging the main capacitor 10a, and the start and end of light emission of the xenon tube Xe1. Light emitting circuit 10c. The charging circuit 10b outputs a charging completion signal (first charging completion signal) to the CPU 1 when the charging of the main capacitor 10a is completed and the xenon tube Xe1 can emit light. When this charging completion signal is input, the CPU 1 outputs a light emission start signal to the light emitting circuit 10c when the full-press switch SW2 described later is turned on. In response to this, the light emitting circuit 10b supplies the charge charged in the main capacitor 10a to the xenon tube Xe1 to start the light emission of the xenon tube Xe1. The light emission amount of the xenon tube Xe1 is measured by the dimming circuit 12, and is input to the CPU 1 as dimming light emission data. The light emission amount data for light control is compared with a reference light emission amount determined by film sensitivity, etc., and when the measured light emission amount exceeds the reference light emission amount, a light emission stop signal is issued from the CPU 1 by the light emission circuit 10
Entered in c. This light emission stop signal from CPU1 is the light emission circuit 1
When input to 0c, the light emitting circuit 10c cuts off the charging charge supplied to the xenon tube Xe1 and stops the emission of light from the xenon tube Xe1.

The red-eye prevention light emitting device 11 includes a xenon tube Xe2 that irradiates light that reduces the pupil of the human eye, a condenser 11a, and
It has a charging circuit 11b and a light emitting circuit 11c for controlling the start of light emission. When an operation signal is input from the CPU 1 to the light emitting circuit 10c, the xenon tube Xe2 emits light to perform so-called pre-irradiation. The charging circuit 11b outputs a charging completion signal (second charging completion signal) to the CPU 1 when the charging of the main capacitor 11a is completed and the emission of the xenon tube Xe2 becomes possible. When this charging completion signal is input, the CPU 1 outputs a light emission start signal to the light emitting circuit 11c when the full-press switch SW2 described later is turned on. In response to this, the light emitting circuit 11b supplies the charge charged in the main capacitor 11a to the xenon tube Xe2 to cause the xenon tube Xe2 to emit light.

Further, a release switch SW linked to the operation of a release button (not shown) is connected to the CPU 1. The release switch SW includes switches SW1 and SW2. The switch SW1 is turned on when the release button is half-pressed, and the switch SW2 is turned on when the release button is fully pressed. When the switch SW1 is turned on, the CPU 1 activates the focus detection circuit 3 and the photometric circuit 4 described above, and calculates the distance (distance information) D (FIG. 8) from the focus detection signal input from the focus detection circuit 3 to the subject. At the same time, the lens drive amount for guiding the focusing lens 8 to the in-focus position is calculated. Next, a lens drive signal is output to the lens drive circuit 2 for driving the focusing lens 8 to the in-focus position based on this lens drive amount.
When the switch SW1 is turned on, the subject brightness (luminance information) B is calculated based on the photometric data from the photometric circuit 4.
After that, when the switch SW2 is turned on, the camera control circuit 5
The exposure control device 6 is driven via the camera to perform photographing, and at this time, the electronic flash device 10 or the red-eye preventing light emitting device 11 is operated as required.

Further, at the time of flash photography, the CPU 1 determines, based on the calculated subject distance D and subject brightness B, whether or not a shooting condition under which the red-eye phenomenon occurs as described later. Then, if it is determined that the shooting condition is such that red eye occurs, and the first charging completion signal is output, the red eye determination signal is output to set the red eye prevention mode, and the red eye is responded to when the switch SW2 is turned on. The prevention light emitting device 11 is activated, and after 0.75 seconds has elapsed, the exposure control device 6 is driven via the camera control circuit 5 and a light emission start signal is output to the light emission circuit 10c.

In the configuration of the above embodiment, the CPU 1 constitutes the main flash command output means 101, the red eye determination means 102 and the control means 104, and the charging circuit 10b constitutes the first charge detection means 103.

Next, the CP based on the flowcharts of FIGS.
The control procedure by U1 will be described.

When the half-push switch SW1 is turned on, the programs shown in FIGS. 3 and 4 are started. First, in step S1 of FIG. 3, the memory is reset to the initial value and each circuit is reset. Thereby, the focus detection circuit 3 and the photometry circuit 4
Converts the detection result of each light receiving element into an electric signal
Input to CPU1. Next, in step S2, the focus detection circuit 3
The focus detection signal from is read, the subject distance D is calculated in step S3, and the process proceeds to step S4.

In step S4, the focusing lens 8 is determined based on the image shift amount and shift direction obtained by the above-described focus detection signal.
Is calculated to output a lens drive signal to the lens drive circuit 2 in step S5.
The focusing lens 8 is driven to the in-focus position by the motor 9.

Next, in step S6, the photometric data from the photometric circuit 4 is read, in step S7 the subject brightness B is calculated based on this photometric data, and in step S8 of FIG. 4, the subject brightness B and ISO sensitivity are used to determine the shutter speed. And the aperture value are calculated. These shutter speed and aperture value are output to the camera control circuit 5 in step S9. The camera control circuit 5 displays these values on the display device 7.

Next, the process proceeds to step S10, where it is determined whether or not shooting is performed using the electronic flash device 10. This is determined, for example, by whether or not the use of the electronic flash device 10 is prohibited by an electronic flash device use prohibition switch (not shown), or whether it is necessary to use the electronic flash device 10 based on whether the subject brightness B is high or low. . If step S10 is positive, the process proceeds to step S15, and if negative, the red-eye prevention mode is canceled in step S14 and the process returns to step S2. In step S15, charging of the main capacitor 10a of the electronic flash device 10 is started and
Proceed to 11.

In step S11, it is determined whether or not the shooting conditions are such that red eyes occur. In this embodiment, the possibility of red-eye occurrence is determined based on the subject distance D and the brightness B.

If step S11 is positive, charging of the capacitor 11a of the red-eye prevention light emitting device 11 is started in step S16.
Next, in step S12, it is determined whether or not the first charging completion signal is output from the charging circuit 10b of the electronic flash device 10 and the second charging completion signal is output from the charging circuit 11b of the red-eye preventing light emitting device 11. To judge. That is, it is determined whether or not charging of the main capacitor 10a of the electronic flash device 10 and the capacitor 11a of the red-eye preventing light emitting device 11 has been completed. If the first and second charging completion signals are respectively output from both charging circuits 10b and 11b, step S11 is affirmed and the operation proceeds to step 13, the red-eye mode is set, and one of the charging completion signals is not output. If step S11 is denied, the process proceeds to step S14 to cancel the setting of the red-eye mode.

Here, the determination of the presence / absence of red-eye occurrence in step S11 will be described.

As shown in FIG. 8, when the pupil P is photographed on the photograph, a straight line l ₁ (equivalent to the optical axis of the camera) passing through the centers of the pupil P and the taking lens RE, and the pupil P and the electronic flash device 10 are displayed. Many red eyes occur when the angle θ with the straight line l ₂ passing through the center of the xenon tube Xe 1 becomes about 2 degrees or less. Now, if the distance between the optical axes of the taking lens RE and the xenon tube Xe1 is H, the angle θ
Is expressed by tan θ = H / D, and the subject distance D can be expressed by D = H / tan θ (1) from this equation. So, for example, a photographic lens
Set the distance H between the optical axes of RE and the electronic flash unit 10 xenon tube Xe1
When it is defined that red-eye occurs when θ is set to 0.1 m and θ = 2 degrees or less, it can be considered that red-eye occurs when the subject distance D is substantially equal to or greater than D = 28.6 × 0.1 m = 2.86 m. Therefore,
The subject distance D obtained by the equation (1) can be used as a reference value for determining the shooting condition for red eye occurrence.

On the other hand, when the subject brightness is high enough to exceed the predetermined reference value, the pupil is closed, so that the red-eye phenomenon hardly occurs due to the catch light effect by the eyes reflecting the flash light. In other words, it can be said that red eye occurs when the subject brightness is equal to or lower than a predetermined reference value such that the human pupil becomes so large as to cause red eye.

As described above, in the present embodiment, it is determined that red eye occurs when the detected subject distance D is equal to or greater than the reference value of 2.86 m and the subject brightness B is equal to or less than the predetermined reference value. The above-described distance H is calculated by the CPU 1 by, for example, inputting a signal corresponding to the height position of the xenon tube Xe1 from the electronic flash device 10 side to the camera side.

When the full-press switch SW2 (FIG. 2) is turned on in this state, the interrupt routine shown in FIGS. 5 to 7 is started,
First, in step S21 in FIG. 5, it is determined whether the red-eye prevention mode is set. If a positive determination is made, step S2
In step 2, an operation signal is output to the red-eye prevention light emitting device 11 to cause the xenon tube Xe2 to flash and illuminate the subject.
As a result, the person who is the subject sees the flash of the xenon tube Xe2, and the pupil of the eye closes.

Next, in step S23, it is determined whether or not the time (for example, 0.75 seconds) when the pupil opening of the subject becomes minimum has elapsed after the light emission of the xenon tube Xe2. This is measured by operating a timer at the same time as a light emission start command to the xenon tube Xe2. If negative, step S2 until affirmative
It stays at 3 and waits for the above-mentioned delay time, and if a positive determination is made, the process proceeds to step S24. In step S24, the camera control circuit 5
Then, the main mirror is raised in step S25, and the shutter first curtain is driven in step S26. After that, in step S27 of FIG.
0 Judge the use.

If step S27 is denied, the process proceeds to step S31, and it is determined whether a predetermined shutter opening time has elapsed. If the step S31 is negative, the process stays in the step S31 until it is affirmed and waits for a predetermined shutter opening time, and if the step S31 is affirmative, the shutter rear curtain is made to travel in the step S34 of FIG.
Then, the main mirror is brought down and the process is completed. As described above, normal shooting is performed without flash light emission.

When step S27 is affirmed, the process proceeds to step S28, and it is determined whether or not the shutter is fully opened. If step S28 is denied, it stays in step S28 until it is affirmed and waits for the full opening of the shutter. To start. Thereafter, the process proceeds to step S30, in which it is determined whether or not the shutter opening time has reached the synchronization tuning second. If the result is affirmative, the process proceeds to step S34.

If step S30 is denied, the process proceeds to step S32, and it is determined whether the light emission amount of the xenon tube Xe1 has reached a predetermined value. This is performed based on the light emission amount data which is measured by the light control circuit 12 and is input to the CPU 1. Step S3
If 2 is denied, the process returns to step S30, and if affirmative, a light emission stop signal is output to the light emitting circuit 10c in step S33 to stop the light emission of the xenon tube Xe1. After that, the process is step S3.
Go to 4, S35. As a result, flash photography is performed when the pupil of the eye is minimized, so that the occurrence of red eyes is prevented.

According to the procedure described above, the main capacitor 10a of the electronic flash device 10 and the red-eye preventing light emitting device 1 at the time of flash photography are used.
It is determined that red-eye occurs when the subject distance D is θ <2 and the subject brightness B is lower than a predetermined reference value when both capacitors 11a of 1 are completely charged. However, prior to the main flash, the red-eye prevention light-emitting device 11
In other cases, that is, when not using flash photography, when one of the capacitors 10a and 11b is uncharged, and when the condition for generating red eye is not determined, the red eye preventing light emitting device 11 is activated. I did not let it. Further, even if the main capacitor 10a is not completely charged, the xenon tube Xe1 is caused to emit light by the release full-press operation to perform flash photography. Therefore, when the so-called release priority method is adopted, it is possible to prevent the shutter chance from being missed by undesired pre-irradiation. In addition,
The red-eye prevention light-emitting device 11 may be activated if the charging state of the capacitor 11a of the red-eye prevention light-emitting device 11 is not detected and the main capacitor 10a is completely charged.

-Second Embodiment- A second embodiment of the present invention will be described with reference to Figs. 9 and 10.

9 and 10 show the processing procedure of the second embodiment.

The procedure of FIG. 9 is used instead of steps S8 to S14 shown in FIG. 4, and the procedure of FIG. 10 is step S21 shown in FIG.
It is used in place of S26 to S26, and the same parts as those in FIGS. 4 and 5 are designated by the same reference numerals and will be described.

In FIG. 9, when the process proceeds from step S9 to step S41, the electronic flash device 1 is operated in the same manner as step S10.
It is determined whether or not the condition uses 0. If negative, the flag is reset in step S47 and the process proceeds to step S2 in FIG. 3, and if positive, the charging of the main capacitor 10a of the electronic flash device 10 is started in step S42. Next, in step S43, it is determined in the same manner as in step S11 whether or not the photographing condition causes the red eye, and if negative, the main flash flag FLG1 indicating the use of only the electronic flash device 10 is set in step S46. Proceed to step S2 in FIG. If step S43 is positive, the red-eye prevention light emitting device 1
The charging of the first capacitor 11a is started, and in the next step S45, the red-eye flag FLG2 indicating that both the red-eye preventing light emitting device 11 and the electronic flash device 10 are used is set, and the process proceeds to step S2 in FIG. .

That is, in the second embodiment, the half-press switch SW
When 1 is turned on, step S1 in FIG. 3 is executed, and thereafter, steps S2 to S9 → S41 to S47 shown in FIGS. 3 and 9 are repeatedly performed until the full-press switch SW2 is turned on.

When the full-press switch SW2 is turned on, the procedure of FIG. 10 is interrupted, and first, at step S51, the flag F
It is determined whether LG1 is set, and if a negative determination is made, the process proceeds to step S52, and it is determined whether the flag FLG2 is set. If step S52 is positive, the process proceeds to step S53, where the condenser 11a of the red-eye prevention light emitting device 11
Has completed charging, and if affirmative, in step S54 it will be determined whether the capacitor 10a of the electronic flash device 10 has completed charging. If affirmative, the steps S22 to S26 are executed in the same manner as described above to execute the steps shown in FIG.
Proceed to S34, S35. If step S51 is positive, the process proceeds to step S54. On the other hand, when steps S53 and S54 are denied, the routine proceeds to step S55, where the release lock is applied and the routine returns.

According to the second embodiment, under the photographing condition using both the red-eye preventing light emitting device 11 and the electronic flash device 10,
When any of the capacitors 11a or 10a is not fully charged, the release lock is performed, and the photographing is prohibited without pre-irradiation.

Further, even under the shooting condition using only the electronic flash device 10, if the main capacitor 10a is not completed yet, the release lock is performed to prohibit the shooting.

-Modification- In the above, the photographing condition for the occurrence of red eye is automatically determined based on the brightness B and the distance D to the subject, and the red eye prevention command is output to enable the operation of the red eye prevention light emitting device 11. The red-eye prevention command first notifies the shooting condition that red-eye has occurred with a warning device, and the operator gives an operation command for operating the red-eye prevention light-emitting device 11 from a separately installed switch, and a main flash command and charging are performed. The red-eye preventing light emitting device 11 may be activated when the completion signal is output. Alternatively, the notification device may not be provided, and only the operation member that gives an operation command of the red-eye prevention light emitting device may be provided.

Further, in the above, when the subject distance D is equal to or larger than the value given by the expression (1) and the subject brightness B is equal to or smaller than the predetermined value, it is determined that the photographing condition is such that red eye occurs. Since it is highly probable that a red eye will occur if at least one of them is satisfied, it may be determined that the photographing condition is such that a red eye occurs.

Further, in the above, it is determined that when the brightness B is equal to or less than the predetermined value and the subject distance D is equal to or more than the predetermined value, the shooting condition is such that red-eye occurs. However, in the brightness range of the reference brightness or less, it is relatively bright as in the evening. Considering that red eyes are less likely to occur and conversely red eyes are likely to occur when it is considerably dark such as darkness, the reference value of the subject distance is used if it is relatively bright within the brightness range below the predetermined reference value. May be farther away and closer if dark.

Furthermore, the single-lens reflex camera that obtains the subject distance D from the amount of displacement and the displacement direction between the image plane of the subject and the planned image plane obtained by the pair of light receiving elements has been described. For example, light is projected onto the subject, The present invention can also be applied to a camera that receives the reflected light with a light receiving element and performs an active distance measurement method in which a subject distance is obtained from a detection signal of the light receiving element.

Furthermore, although an example in which an external electronic flash device is mounted has been described, the present invention can also be applied to a camera having a built-in electronic flash device. Further, although the electronic flash device is shown as an example of being automatically activated when the subject is dark, it is possible to manually operate the electronic flash device to instruct whether or not to use the electronic flash device and to emit light in synchronization with the release operation. Good.

Furthermore, for the electronic flash device 10 capable of emitting light at a plurality of light emitting positions, at each position, a signal indicating the height position of the light emitting tube is taken into the camera, whereby
By calculating the distance H between the optical axis of the arc tube and the photographing lens, the limit photographing distance D according to the equation (1) can be changed.

G. Effect of the Invention According to the present invention, the operation of the red-eye preventing light emitting device is prohibited at least when the main capacitor of the electronic flash device is not fully charged, so that so-called release priority that enables flash photography even if the main capacitor is not fully charged. In the camera of the system, the delay time due to the pre-irradiation for preventing red eye does not occur, and there is no risk of missing a shutter chance. Also, in a camera that locks the release when the main capacitor of the electronic flash device is not fully charged, it is prevented that only the pre-irradiation for red eye prevention is performed according to the operation of the release button, and the battery Useless consumption is prevented.

Further, according to the first aspect of the present invention, the presence or absence of the occurrence of red eye is automatically determined on the camera side, so that the usability is further improved.

[Brief description of drawings]

FIGS. 1 (a) and 1 (b) are complaint correspondence diagrams. 2 to 8 show a first embodiment of the present invention, FIG. 2 is a block diagram of a red-eye preventing light emitting device of a camera according to the present invention, and FIGS. 3 to 7 show processing procedures respectively. The flowchart shown in FIG. 8 is an explanatory diagram for explaining the shooting conditions under which the red-eye effect occurs. 9 and 10 are flow charts showing the second embodiment of the present invention. 1: CPU, 3: Focus detection circuit 4: Photometric circuit 5: Camera control circuit 8: Focusing lens 10: Electronic flash device 10a: Main condenser 10b: Charging circuit 11: Red-eye prevention light-emitting device 11a: Red-eye condenser 11b: Red-eye condenser Charging circuit 101: Flash command output means 102: Red eye determination means 103: Charge state detection means 104, 204: Control means 202: Red eye prevention command output means

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Toshio Dobashi 1-6-3 Nishioi, Shinagawa-ku, Tokyo Inside Nihon Optical Industry Co., Ltd. (72) Inventor Nobuaki Sasaki 1-6, Nishioi, Shinagawa-ku, Tokyo No. 3 inside Nihon Kogaku Kogyo Co., Ltd.

Claims (6)

(57) [Claims] 1. A flash command output means for outputting a main flash command, and a main capacitor, wherein a light-emitting tube is caused to emit light by a charge charged in the main capacitor in response to the main flash command to illuminate an object with illumination light. An electronic flash device, a red-eye determination unit that determines whether red-eye has occurred based on shooting conditions, and outputs a red-eye prevention command when red-eye has been determined, and operates based on the red-eye prevention command to prevent red-eye on a subject. A red-eye prevention light emitting device for irradiating the main illumination light, a first charge state detecting means for detecting a charge state of the main capacitor and outputting a first charge completion signal when the charge is completed, and a release operation When the red-eye prevention command and the main flash command are output and the first charge completion signal is output, the red-eye prevention light-emitting device is activated, and then a predetermined time elapses. Then, the electronic flash device is activated, and the red-eye prevention is performed if the first charge completion signal is not output even if the red-eye prevention command and the main flash command are output when the release operation is performed. And a control means for operating the electronic flash device without operating the light emitting device. 2. The red-eye preventing light-emitting device is a flash device that has a red-eye preventing capacitor and causes the arc tube to emit light by the charge of the red-eye preventing capacitor. A second charging state detecting means for detecting and outputting a second charging completion signal at the time of completion of charging, wherein when the second charging completion signal is not output,
The red-eye prevention control device according to claim 1, wherein the operation of the red-eye prevention flash device is prohibited even if the red-eye prevention command is output during a release operation. 3. A main flash command output means for outputting a main flash command, and a main capacitor, and in accordance with the main flash command, the charge of the main capacitor causes the arc tube to emit light to illuminate an object. An electronic flash device, a red-eye prevention command output unit that outputs a red-eye prevention command, a red-eye prevention light-emitting device that emits red-eye prevention irradiation light to a subject based on the red-eye prevention command, and a charging state of the main capacitor. First charge state detecting means for detecting and outputting a first charge completion signal when charging is completed; and for preventing red eye when the first charge completion signal is output when the red eye prevention command is output. When the operation of the light emitting device is permitted and the red-eye prevention command is output, the first
Control means for inhibiting the operation of the red-eye preventing light emitting device when the charging completion signal is not output. 4. The red-eye prevention control device according to claim 3, further comprising an operation member that outputs the red-eye prevention command when operated. 5. If the release operation is performed while the red-eye prevention command is being output by operating the operating member, the control is performed if the main flash command and the first charge completion signal are output. The light emitting device for preventing red eye is operated by means.
The red-eye prevention control device according to the item. 6. When the red-eye prevention command is output by operating the operation member, and if the first charge completion signal is output, the control means controls the red-eye prevention light-emitting device regardless of the release operation. The red-eye prevention control device according to claim 4, which is operated.