JP3063768B2 - Electronic still camera - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic still camera, and more particularly to a method for determining a flash emission time in a flash light emitting device of an electronic still camera.

2. Description of the Related Art As a control method for obtaining an appropriate exposure in flash photography of a photographing apparatus, a flashmatic method and an automatic strobe method are known. The flashmatic control is control means for charging the main capacitor of the strobe to a predetermined voltage so that the amount of light emitted from the strobe is constant and adjusting the amount of light emitted from the camera. The auto strobe control is control means for detecting the emitted strobe light itself by a light receiving sensor, integrating the light, and stopping the light emission when the light reaches a determination voltage.

[Problems to be Solved by the Invention] However, in the flash photography by the flashmatic control described above, the aperture is determined in relation to the subject distance, and the accuracy of the aperture cannot be increased in resolution. Further, the light emission amount of the strobe itself changes depending on the charging voltage of the light emitting main capacitor, and a desired light amount may not be obtained in some cases.

On the other hand, in the case of auto flash control, the average luminance in the photometry area can be captured as photometry information, but there are cases where exposure corresponding to the main subject cannot be obtained due to the reflectance or distance difference between the main subject and the background. there were. Further, in the case of this method, the light emission instruction is stopped when a predetermined light amount is reached. However, there is a variation in the light emission amount after the stop of the light emission instruction, and a disadvantage in accuracy is inevitable. In particular, in the case of an electronic camera with a narrow latitude, these points are particularly problematic.

The electronic still camera uses a solid-state imaging device having a smaller light receiving area than a camera using a silver halide film.
Accordingly, 1) the solid-state imaging device has a narrower dynamic range with respect to the fluctuation of the incident light than the silver halide film, and thus requires more precise exposure control.

2) Since the light receiving area is small, the photographing lens has a shorter focus. Therefore, the depth of field becomes deep. For this reason, the function of the diaphragm to adjust the amount of incident light becomes more important than the function of adjusting the depth of field.

On the other hand, in order to maintain the accuracy of the stop area, it is easier to change the size of the stop with a fixed aperture stepwise. However, when the strobe light emission is controlled by changing the light emission step by step, the control of the light emission amount is wrinkled. Also,
When switching from the auto focus to the manual focus and using the flash light, there is an inconvenience when only the distance measurement information by the conventional automatic focus adjustment can be used when using the strobe lighting.

SUMMARY OF THE INVENTION An object of the present invention is to provide an electronic still camera capable of realizing strobe photography with proper exposure that is highly accurate and that is not affected by background luminance, distance, and the like, in order to solve the above-described disadvantages. .

[Means and Actions for Solving the Problems] An electronic still camera according to the present invention is an image pickup device for photoelectrically converting a subject image, and a stepped device for adjusting the amount of incident light flux from the subject incident on the image pickup device. Aperture, automatic distance detecting means for automatically detecting the distance of the subject, manual lens position setting means capable of manually setting the photographing lens position, and when the manual lens position setting means is operated A means for detecting a subject distance corresponding to the lens position obtained by the manual distance detecting means; a means for detecting a charging voltage of a main capacitor for emitting a strobe; and a means for detecting a subject distance and the charging voltage at a predetermined aperture value. Means for storing the flash emission time corresponding to the combination; and means for storing the flash emission time corresponding to the subject distance based on the predetermined aperture value set for photographing. Means for selecting a flash emission time.

Hereinafter, the present invention will be described with reference to the illustrated embodiments.

FIG. 1 is a block diagram of an electronic still camera to which a flash control method according to an embodiment of the present invention is applied. The above-described camera includes an imaging system, a distance measuring system, a strobe device, and a system controller 10. The imaging system includes a photographing lens 1, an aperture 11, and an imager 2 serving as an image sensor.
And a variable resistor 4 which is a means for detecting the focusing position of the photographing lens 1. In addition, distance measurement system, distance measurement lens 5, AF (automatic focusing)
The strobe device is composed of a flash unit 7
And a strobe light emission circuit 8 including a charge storage main capacitor 8a for light emission, and an A / D conversion circuit 9 for a charging voltage of the main capacitor 8a.

The outline of the shooting operation of the camera is as follows. First, in accordance with a release operation (first-step trigger), the subject distance L _AF data from the AF unit 6 is taken into the system controller 10, and the shooting lens 1 corresponds to the distance data L _AF. Perform focusing operation. When the photographer manually changes the focus position of the lens 1, the focus lens position of the variable resistor 4 (or the focusing position sensor of the lens 1) (or
Output value L ^MF corresponding to the focus ring position) ^'is taken into the system controller 10, the value L ^MF' object distance L _MF for is calculated. Further, the charging voltage V _CHG of the main capacitor 8a already charged is converted into a charging voltage (digital value) V _CHD by the A / D conversion circuit 9 and input to the system controller 10.

On the other hand, the system controller 10 has a strobe light emission time for obtaining an appropriate exposure corresponding to each combination of each subject distance L _AF (or L _MF ) at a predetermined aperture value and each main capacitor charging voltage V _CHD. T (N) is stored. Subsequently, when the release operation of the second-stage trigger is performed, the strobe light emitting circuit 8 sets the flash light emitting tube 7 to the light emitting time T based on the instruction of the system controller 10.
Light is emitted during (N). The subject image due to the reflected light of the strobe light is taken into the video processing circuit 3 as a photographing signal via the imager 2 and recorded.

Next, a description will be given of a flash emission time T (N) in which an appropriate exposure is obtained for each of the above-described subject distance information and charging voltage information. FIG. 2 is a characteristic curve obtained by plotting the guide number GNo value when the light is emitted for each light emission time T at each voltage using the charging voltage V _CHG of the main capacitor 8a as a parameter. On the other hand, aperture FNo
2.8 is fixed, the object distance from 1 m to 4.36 m is divided by an EV value of 0.25, and a guide number GNo for each distance is obtained (described in the left column of Table 1). In addition, the practical range of the charging voltage V _CHG of the main capacitor between 330 V and 255 V is divided into six parts, and the digitized charging voltage values V _CHD of 1 to 6
(Described in the upper column of Table 1). Then, from the characteristic curve of the guide number with respect to the light emission time T in FIG. 2, the strobe light emission time T for satisfying the guide number GNo corresponding to each subject distance L is obtained for each charging voltage V _CHD as the aperture 2.8. It is shown in the strobe emission time correspondence table in the table.

As shown in Table 1, with respect to the light emission time corresponding to the values 1 to 6 of the digitized charging voltage value V _CHD ,
A group of light emission times T arranged on the right-downward side, for example, a group marked with *, can be regarded as showing substantially the same value. Therefore, the light emission time T as shown in the reference light emission time in Table 2 as a representative value of each group from Table 1
(N) Set the value of (N = 1 to 20).

Then, each reference light emission time T (N) in Table 2 which can be approximated to each light emission time T in Table 1 is applied,
Table 3 shows a reference light emission time T (N) for obtaining an appropriate guide number GNo for each subject distance L. Note that each subject distance L in the table is obtained by dividing the corresponding distance range at a stage of approximately the EV value of 0.25 similarly to Table 1, and by dividing the range by the system controller.
Each subject distance L is stored in the memory unit of 10 light control data, and
It is assumed that the strobe emission time T (N) shown in Table 3 corresponding to the charging voltage digital value V _CHD is stored.

Next, the flash photography processing of this embodiment will be described with reference to the flowchart of FIG.

When an instruction for flash photography is issued manually or automatically, the main condenser 8a for flash emission is charged. And. When the first-stage trigger signal linked to the release button is input, the above-mentioned capacitor at that time
The charging voltage V _{CHG of} 8a is digitally converted by the A / D conversion circuit 9, and the digital value V of the charging voltage shown in Table 3 is obtained.
_CHD (1-6) is input to the system controller 10.

When the trigger signal of the second stage is input, the MF position, which is the focusing position of the photographing lens, and the focusing position by the AF (automatic focusing) operation of the AF unit.
Check if the AF positions are equal. And
If the two are equal, that is, if the photographer has not performed manual focusing after the AF operation, the subject distance L _AF is substituted for the subject distance L. On the other hand, if the MF position is not equal to the AF position, that is, if manual focusing is performed after the AF operation, the subject distance L _MF corresponding to the manual focusing position is substituted for the subject distance L.

Next, from the data memory corresponding to Table 3 of the system controller 10, a flash emission time T (N) for obtaining an appropriate exposure corresponding to the digital value _{VCHD of the} charging voltage and the subject distance L is obtained. Subsequently, the light emission time T
Flash photography based on (N) is performed, and the photography sequence ends.

In the present embodiment, regarding the _{digitalization} of the charging voltage V _CHG of the main capacitor for strobe light emission, the range width is divided as wide as possible within an allowable range, for example, divided into six as shown in Table 3, System controller 10
Has reduced the amount of memory used.

In this embodiment, the A / D conversion circuit 9 is used to convert the charging voltage of the main capacitor 8a into a digital value (V _CHD ).
As a modified example, the digital value may be obtained from the count value of the charging time. The variable resistor 4 serving as a focusing lens or focusing lens position detecting means for subject distance information includes other position detecting means such as a sliding contact using a sliding conductive pattern, a photo interrupter, or a magnetic sensor. Of course, it is also possible to use a sensor or the like.

In this embodiment, the reference aperture is fixed. However, in order to apply the present invention even when the aperture is changed, a guide number due to the change of the aperture is calculated, and the subject distance corresponding to the guide number change is calculated. If the strobe light emission time T (N) is selected based on L in the same manner as in Table 3, it is possible to perform strobe shooting with proper exposure.

[Effects of the Invention] As described above, the present invention determines the flash emission time in accordance with the distance information to the subject and the charging voltage information of the flash emission main capacitor. Therefore,
According to the present invention, (1) a strobe corresponding to each subject distance based on the aperture is selected in contrast to a method in which an aperture having a stepped resolution is selected from the subject distance as in the case of the conventional flashmatic control method. Since the light emission time is selected, high-precision strobe light emission control becomes possible.

(2) Since the flash time is changed to cope with an increase or decrease in the amount of strobe light emission due to a change in charging voltage,
Further, accuracy for proper exposure is improved.

(3) In addition, since the amount of strobe light emission is controlled in accordance with the subject distance, a phenomenon in which the image of the main subject flies depending on the luminance or the distance of the background unlike the conventional auto strobe control method does not easily occur. .

In other words, when controlling the flash emission of an electronic still camera, accurate exposure control is possible even with an aperture with stepped resolution, and when manual focus is used instead of autofocus. In this case, since the setting of the distance is not impaired, accurate exposure control can be performed.

For example, an electronic still camera having a remarkable effect can be provided.

[Brief description of the drawings]

FIG. 1 is a block diagram of an electronic still camera to which a strobe control method according to an embodiment of the present invention is applied. FIG. 2 is a strobe light main capacitor in the strobe device of the electronic still camera of FIG. FIG. 3 is a characteristic diagram showing the change of the guide number with respect to the flash emission time when the charging voltage is used as a parameter. FIG. 3 is a flowchart of the flash photography processing of the electronic still camera of FIG. L ^{MF ':} Focus lens or focus ring position detection output (distance information) L _MF: Subject distance (distance information) corresponding to L ^MF' L _AF: AF subject distance (distance measurement data) (distance information) V _CHD … digitized value of charging voltage of main capacitor (charging voltage information) T, T (N)… Flash firing time 4… Variable resistor (position detecting means) 6… AF unit (automatic focusing device) 8a …… Main capacitor 9 …… A / D conversion circuit (A / D converter)

Continuation of the front page (72) Inventor Takumi Momose 2-43-2 Hatagaya, Shibuya-ku, Tokyo Olimbus Optical Industry Co., Ltd. (56) References JP-A-56-159622 (JP, A) JP-A-59- 114524 (JP, A) JP-A-52-88332 (JP, A) JP-A-63-182637 (JP, A)

Claims (1)

(57) [Claims] An image pickup device for photoelectrically converting a subject image, a stop having a stepped resolution for adjusting the amount of incident light flux from the subject incident on the image pickup device, and automatically setting a distance to the subject. Automatic distance detecting means for detecting, a manual lens position setting means capable of manually setting a photographing lens position, and an object corresponding to the lens position obtained by the manual distance detecting means when the manual lens position setting means is operated. Means for detecting a distance; means for detecting a charging voltage of a main capacitor for emitting a strobe; means for storing a strobe emission time corresponding to a combination of a subject distance at a predetermined aperture value and the charging voltage; Means for selecting a flash emission time corresponding to a subject distance based on the predetermined aperture value set for the above. Electronic still camera to.