KR890001455B1 - Automatic exposure control device - Google Patents

Abstract

Fast and continuous photographing can be done by a controller for automatic exposure even though the brightness of a subject changes during photographing without any variation of shutter speed which is set at first. The 1st light receiving device (1) measures the light which is fransmitted through phtographing lens. 2 is algebraic compression circuit, 3 is analog to digital converting circuit, 5 is operating circuit, 7 is shutter time fixing unit, 9 is iris control circuit, 10 is iris. The 2nd light receiving device (11) measures the reflected light from the shutter membrane surface during exposuring. 12 is the integration circuit and 13 is switching circuit.

Description

Auto Exposure Control

1 is a block diagram showing the configuration of an automatic exposure control apparatus using a conventional TTL direct optical measurement.

2 is a block diagram showing the configuration of an automatic exposure control apparatus according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

DESCRIPTION OF SYMBOLS 1 First light receiving element 5 Operation circuit

9: Aperture control circuit 10: Aperture

11 second light receiving element 13 switching circuit

16: shutter seconds time counting circuit 17: comparison circuit

The present invention relates to an automatic exposure control apparatus for a camera that performs continuous shooting.

BACKGROUND ART [0002] Conventionally, as an automatic exposure control apparatus for controlling the exposure amount, there is a configuration (hereinafter referred to as TTL direct optical measurement) that measures the reflected light from an imaging surface such as a film and controls the shutter speed. An example is shown in FIG. In Fig. 1, reference numeral 1 denotes the first light receiving element, which measures the transmitted light passing through the lens in a state in which the aperture is opened by the release operation, and the optical measuring sheet is subjected to logarithmic compression in the logarithmic compression circuit 2. After that, the analog-to-digital conversion circuit 3 converts the digital values. The optical measurement information 4 is arithmetic processed by the arithmetic circuit 5 and is output as the aperture information 6. When the shutter seconds time is set by the shutter seconds time setting unit 7, the set shutter seconds time information 8 is input to the calculation circuit 5 together with the optical measurement information 4 to be calculated. The aperture information 6 according to the optical measurement information 4 and the set shutter seconds information 8 is output. This aperture information 6 is input to the aperture control circuit 9 to throttle the aperture 10 to a constant value in accordance with the aperture information 6. When the diaphragm 10 is throttled, the shutter starts to open, and the second light receiving element 11 measures the reflected light from the shutter film surface and the imaging surface at the time of exposure, and is integrated in time by the integrating circuit 12. When the output of the integrating circuit 12 reaches a predetermined level, the switching circuit 13 operates to cut off the exciting current of the shutter opening and closing electromagnet 14 to close the shutter.

In such a conventional method, when continuous shooting is performed, the responsiveness of the diaphragm mechanism becomes a problem since the aperture is returned to the open position for each shot and the light passing through the lens is measured to correct the throttle paper of the aperture. The continuous shooting speed could not be increased. In the case of continuous shooting, when the photographing is performed with the throttle paper set to the minimum, the responsiveness of the aperture mechanism is not a problem. However, if the brightness of the subject changes during shooting, Since the time and the shutter second time actually taken are different, the image is blurred, and the sharp shutter time cannot be taken clearly by the shutter time intended by the photographer. In addition, when the brightness of the subject becomes dark during continuous shooting, the shutter speed becomes slow, causing hand shaking.

The present invention eliminates these conventional drawbacks, and even if the brightness of the subject changes during continuous shooting, the shooting shutter speed does not change from the initially set shutter speed, so that the automatic exposure control window capable of high-speed continuous shooting can be obtained. To provide.

The automatic exposure control apparatus of the present invention calculates the throttle value of the aperture and the shutter second time in accordance with the first optical measuring means for measuring the emitted light of the photographing lens, and the output of the first optical measuring means, Throttling means for throttling the aperture according to the throttling value of the aperture, second optical measuring means for measuring the reflected light from the shutter film surface and the photographing surface during exposure after the aperture has been throttled, and the second optical measuring means Control means for controlling the exposure time of the imaging surface on the basis of the output, comparison means for counting this exposure time, and comparing it with the shutter second time calculated by the first optical measuring means, and the output of the comparison means. And a photographing means for correcting the iris and taking the next shot. Even if the brightness of the subject changes during continuous shooting, the shutter shutter time is equal to the shutter initial time set first. Raj will have become without high-speed continuous shooting days.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. 2 is a convex diagram showing the configuration of the automatic exposure control apparatus according to the embodiment of the present invention. The same components as those shown in FIG. 1 are denoted by the same reference numerals and the description thereof will be omitted.

The optical measurement information 4 is calculated by the calculation circuit 5 to output the aperture information 6 and the shutter second time information 15. When the diaphragm 10 is throttled to the aperture value of the diaphragm according to the diaphragm information 6, the shutter is opened and the exposure is started, and the second light receiving element 11 measures the reflected light from the shutter film surface and the imaging surface during exposure, and the The output is time integrated in the integrating circuit 12. At the same time, the shutter second time counting circuit 16 starts counting the exposure time. When the output of the integrating circuit 12 reaches a predetermined level, the switching circuit 13 operates to cut off the exciting current of the shutter opening and closing electromagnet 14 to close the shutter. At the same time, the counting of the shutter second time counting circuit 16 is stopped, and the counting value of the exposure time is sent to the comparing circuit 17 and compared with the shutter second time information 15. From the comparison circuit 17, the axial correction signal 18 of the iris is sent to the iris control circuit 9 in accordance with the difference between the count value of the exposure time and the shutter second time information 15. The throttle paper of the aperture 10 is corrected so that the exposure time is equal to the shutter second time.

In the above example, the aperture is always corrected even if the shutter seconds are slightly changed. However, in actual use, even if the shutter seconds are slightly changed, for example, 1/125 seconds such as 1/120 seconds, none. Therefore, if the difference between the actual exposure time and the initially set shutter second time is within a certain range, for example, within ± 0.5 EV, the aperture may not be corrected, but the aperture may be corrected only when the range is exceeded.

In the above-described embodiment, two light receiving elements are used, but there is no problem even if one light receiving element is used together.

As described above, the present invention controls the exposure time of the imaging surface by TTL direct optical measurement, and in continuous shooting, the aperture time is determined by comparing the shutter seconds time during the previous shooting operation with the shutter seconds time initially set. The next shooting operation is corrected so that the shutter seconds do not change from the initial set value even when the subject brightness changes during continuous shooting, so that continuous shooting can be performed at the shutter seconds intended by the photographer. Moreover, even if the brightness of the subject becomes dark during continuous shooting, the shutter speed does not become slow, and there is no fear of camera shake. In addition, since it is not necessary to return the aperture to the open position and correct the optical measurement for each exposure, high speed continuous shooting can be performed without being affected by the responsiveness of the aperture mechanism or the like.

Claims (3)

A first optical measuring means for measuring the transmitted light of the photographing lens, and an throttle for calculating the throttle value and the shutter second time according to the output of the first optical measuring means and throttling the iris according to the throttle value of the aperture Control of the exposure time to the imaging surface based on the output of the second optical measuring means and the second optical measuring means for measuring the reflected light from the shutter film surface and the photographing surface during exposure, after the means and the aperture are throttled. Means for performing a second exposure, comparison means for counting this exposure time and comparing it with the shutter second time calculated by said first optical measuring means, and means for correcting said aperture by the output of said comparing means to perform the next imaging. Automatic exposure control device characterized in that it has a. The automatic exposure control apparatus according to claim 1, wherein the shutter second time is set in advance. The automatic exposure control apparatus according to claim 1, wherein the aperture is corrected only when the output of the comparing means exceeds a certain range.

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